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#REDIRECT [[0CAN042104, Emergency Plan and Alert and Notification System (ANS) Design Report]]
{{Adams
| number = ML21127A166
| issue date = 04/28/2021
| title = Alert and Notification System Design Report
| author name =
| author affiliation = Entergy Operations, Inc, KLD Engineering, PC
| addressee name =
| addressee affiliation = NRC/NMSS, NRC/NRR
| docket = 05000313, 05000368, 07200013
| license number = DPR-051, NPF-006
| contact person =
| case reference number = 0CAN042104
| document report number = KLD TR-1208, Rev. 4
| document type = Emergency Preparedness-Emergency Plan
| page count = 217
}}
 
=Text=
{{#Wiki_filter:Enclosure to 0CAN042104 Arkansas Nuclear One Alert and Notification System Design Report
 
ENGINEERING, P.C.
ARKANSAS NUCLEAR ONE Alert and Notification System (ANS) Design Report Lepftd
  *A ANO WPS2807
* WPS2907 Q    Zone Contour
* 70dBC 0  60dBC I"':: lOMileRlng          ::i'::~~U..>Oll tl.Of,..-.,(-.,,.
::=::c~=~"S:-~.~1'1~ ~~~
Population Density
  *    >2,000Peopte/Sq. MI. :=::.:i=~....      -=M
                                                  ~~~                                    J.S Work performed for Entergy, by:
KLD Engineering, P.C.
1601 Veterans Memorial Highway, Suite 340 Islandia, NY 11749 E-mail: kweinisch@kldcompanies.com September 25, 2020                                          Final Report, Rev. 4        KLD TR-1208
 
SIGNATURE LIST My agency has reviewed the enclosed Alert and Notification (ANS) Design Report In its entirety. We find the report to be accurate and complete, and to be in agreement with our agency's emergency plans. My signature below is my attestation to such.
OSCAR MARTINEZ JR Date:                          Digitally signed by OSCAR MARTINEZ JR 2020.12.14 08:26:07 -06'00' Date 01 'J.8  J.tJ/ti>
Date Date
 
REVISION HISTORY Date  Revision# Notes 3/5/1984      0    FEMA approval of original ANS for the ANO EPZ.
5/2009      1    Design report was updated to account for.
* One-for-one replacement of 34 electromechanical sirens with Whelen and ATI electronic sirens without modifying or changing the control system, antennas and radio systems.
* Results of an acoustical test following installation of the new sirens to demonstrate that the updated siren system meets the design objectives.
* The Fallure Mode and Effects Analysis {FMEA) of the completed siren system
* Replacement of transmitters and radios for the tone alert system .
6/14/2011    2    Design report updated to correct siren GPS locations and siren coverage map 5/2016      3    Design report was revised and supplemented to reflect the following changes:
2/2017
* One-for-one*replacement of the 28 ATI sirens with Whelen 2900-7 series sirens.
* Installation of an additional Whelen 2900-7 siren .
* Results of the near-field tests Indicate that the replacement of the 28 sirens provide a higher siren rated output.
* Provide the Manufacturer's Technical Data, Operations and Troubleshooting Manual for the Whelen 2900-7 siren.
* A replacement triJnsmltter and replacement radios for the NOAA Tone Alert System.
9/2020      4    Design report was requested to update to lnclui:le.
* Update the siren coverage map using detailed Sound PLAN acoustical model and field testing of siren sound levels.
* New guidance on report format and report content in FEMA Rad1ologlcal Emergency Planning Program Manual dated December 2019.
 
Table of Contents EXECUTIVE
 
==SUMMARY==
....................... :......................................................................................... ES-1 MAIN BODY 1    Licensing Obligations .........................................................................................................
                                                                                                                                              ................... 1 2    Requirements ........................................................................................................................
                                                                                                                                                  ................ 2 2.1      System Coverage .........................................................................................................
                                                                                                                                                .................. 2 2.1.1      Population ........................................................................................................................
                                                                                                                                                                ..... 2 2.1.2      Geographic Area .........................................................................................................
                                                                                                                                                          .......... 4 2.1.3      Means........................................................................................................................
                                                                                                                                                      ............ 5 2.1.4      Primary Methods .........................................................................................................
                                                                                                                                                          ......... 6 2.15      Backup Methods .........................................................................................................
                                                                                                                                                          .......... 6 2.2      Population/Demographics ..........................................................................................
                                                                                                                                                .................. 6 2.3      Interoper ability .........................................................................................................
                                                                                                                                            .................... 7 2.4      Operations ................................................. ******************:********** .. ****** ..............................
                                                                                                                                                  ................ 8 2.5      Managem ent/Administration ..........................................................................................
                                                                                                                                                    ............. 8 2.6      Security and Privacy .........................................................................................................
                                                                                                                                                    ............. 9 2.6.1      Physical Security .........................................................................................................
                                                                                                                                                      ........... 9 2.6.2      Logical Security ......................................................................................................................
9 2.7      Maintenance/Repair .........................................................................................................
                                                                                                                                                      ............ 9 2.7.1      Preventative Maintenance ..........................................................................................
                                                                                                                                                        .......... 9 2.7.2      Corrective Maintenance ........................................................................................................
9 2.8      Availability/Rellablllty .........................................................................................................
                                                                                                                                                        ........ 10 2.9      Testing ........................................................................................................................
                                                                                                                                              ................. 10 2.10 Responsibility ..................................................;............................................................
                                                                                                                                                ............... 11 2.11 Training ........................................................................................................................
                                                                                                                                                ............... 11 2.12 Quality Assurance .........................................................................................................
                                                                                                                                                .............. 11 3    Description/Performance ..........................................................................................
                                                                                                                                    ......................... 12 3.1      Physical requirements .........................................................................................................
                                                                                                                                                        ........ 12 3.1.1      System Components .........................................................................................................
                                                                                                                                                              .. 12 3.1.2      User Interfaces ....................................................................................................................
12 3.1.3      Functional Block Diagrams ..........................................................................................
                                                                                                                                                        ........ 12 3.2      Administrative Components ..........................................................................................
                                                                                                                                                  ............. 13 3.2.1      Organizational Responsibilities ..........................................................................................
                                                                                                                                                                . 13 3.2.2      Management .......................................................................................................................
13 3.3      Operational Components .........................................................................................................
                                                                                                                                                              ... 14 3.3.1      Activation ........................................................................................................................
                                                                                                                                                            .... 14 3.3.2      nming .................................................................................................., ..............................
                                                                                                                                                                . 14 3.3.3      Geo-Targeting .....................................................................................................................
14 4    Verification ........................................................................................................................
                                                                                                                                            .................. 14 Arkansas Nuclear One ANS Design Report- Rev. 4
 
4.1    Coverage ..................................................................................................................................... 14 4.2    Population/Demographics .......................................................................................................... 1~
4.3    Metrics ........................................................................................................................................ 17 5    Availability/Reliability ......................................................................................................................... 17 6    Security and Privacy ............................................................................................................................ 17 7    Training and Public Outreach .............................................................................................................. 18 REFERENCES ....................................................................................................................................... R-1 LIST OF APPENDICES A. Compliance with Federal Regulations and Guidance ............... :....................................................... A-1 B. ANO EWS Activation Procedures .......................................................................................................B-1 C. ANO SWS Testing and Maintenance Procedures ............................. :................................................. C-1 D. WPS2800 and WPS2900 Series Operating and Troubleshooting Manuals ....................................... D-1 E. Siren Test Result Report ..................................................................................................................... E-1 LIST OF FIGURES Figure 1. Site Location ................................................................................................................................. 26 Figure 2. Permanent Resident Population by Sector for the ANO EPZ ....................................................... 27 Figure 3. Census Blocks with Population Density Exceeding 2,000 People per Square Mile ..................... 28 Figure 4. Census Blocks with Population Density Exceeding 2,000 People per Square Mile (Filter 1 Applied) ..............................................................................................................................'. ....... :................ 29 Figure 5. Applying Filter 2 to Eliminate Isolated Neighborhoods from High Population Density Consideration ..............................................................................................................................................30 Figure 6. Final Census Blocks with Population Density Exceeding 2,000 People per Square Mile after Applying Filters ..................................;.......................................................................................................... 31 Figure 7. Siren Coverage Map for the ANO EPZ .......................................................................................... 32 Figure 8. Siren System within the ANO EPZ ................................................................................................ 33 Figure 9. Control System Layout for the ANO ANS Siren System ............................................................... 34 Figure 10. Sound Transmission in Temperature Lapse Conditions ............................................................. 35 Figure 11. Sound Transmission in Temperature Inversion Conditions ....................................................... 35 Figure 12. Outdoor Sound Propagation near the Ground .......................................................................... 35 Figure 13. Upwind Sound P~opagation ....................................................................................................... 36 Figure 14. Downwind Sound Propagation with Terrain and Vegetation Effects ........................................ 36 Figure 15. Near-Field and Far-Field Test Locations ..................................................................................... 37 LIST OF TABLES Table 1. EPZ Population by Decennial Census ............................................................................................ 19 Table 2. Population Density Computed using Different Geographic Areas ................................................ 20 Table 3. Siren Details for the ANO EPZ ....................................................................................................... 21 Table 4. SWS Activation Points for ANO Site .............................................................................................. 25 Table 5. Siren System Reliability ................................................................................................................. 25 Table 6. Summary of Near-Field Acoustical Test Results ............................................................................ 25 Table A-1. Regulations Crosswalk ..... i ....................................................................................................... A-2 Arkansas Nuclear One                                                          II                                          ANS Design Report - Rev. 4
 
EXECUTIVE
 
==SUMMARY==
 
The Arkansas Nuclear One (ANO) is located on a peninsula near the Town of Russellville in southwest ern Pope County, Arkansas. The Emergency Planning Zone ('EPZ) for ANO Includes parts of Johnson, Logan, Pope, and Yell Counties. The permanent resident population for the EPZ is 52,871 people as per the 2010 U.S. Census.
The Alert and Notification System (ANS) for the ANO relies on the Siren Warning System (SWS) and the National Oceanic and Atmospheric Administra tion (NOAA) Tone Alert System as the primary means of alerting the public. Route alerting is used as the bc1ckup means to alert the residents around the failed or inoperable siren(s). Public Informatio n materials are distributed to the EPZ populace to Inform people what to do if they hear sirens sounding or a loud tone from the activated NOAA Tone Alert Radios, and what radio stations to tune into for additional informatio n.
The SWS consists of SO omni-direc tional electronic sirens (21 Whelen WPS2807 sirens and 29 Whelen WPS2907 sirens). The location, model type and mounted height of each siren were input to Sound PLAN acoustic modeling software to estimate the audible level of the sirens throughou t the 10-mile EPZ surrounding ANO. The SWS provides 60dBC coverage to 92.6% of the p~pulation within the EPZ and 70dBC coverage to the areas with population density exceeding 2,000 people per square mile.
NOAA Tone Alert Radios are provided to residents of the 10-mlle EPZ who live outside the 60dBC coverage or who have special needs. The radios are also provided to facilities within the 10-mlle EPZ with significant population. The ANO tests the ANS routinely and has an extensive maintenance program in place to ensure continuous, reliable operation of the ANS. The ANS for ANO has had a reliability performan ce Indicator of 100% for 2019. The reliability of the ANS has not dropped below 99% during the la~t decade of operation. Operators of the ANS are offered training as needed to ensure continued reliable operation of the system.
All siren batteries and control boxes are locked and mounted on the siren pole to prevent tampering The siren activation equipmen t is installed at secure locations (the Arkansas Departme nt of Health offices). The ANS system includes a DTMF encoder that requires key-lock a~ivation to make It resistant to cyber-attack.
This ANS design report is an update to the last ANS report (Rev. 3 dated 2/2017) to update the siren coverage map using outputs from the detailed SoundPLAN acoustic model and field testing of siren sound levels, and to address the new guidance on ANS design report formatting and content documented in the December 2019 FEMA REP Program Manual.
Arkansas Nuclear One                                  ES-1                        ANS DeslgT\ Report - Rev. 4
 
1      Licensing Obligations Title 10 of the Code of Federal Regulations {CFR) §S0.47{b), item (5) and Trtle 44 of the CFR §350.S(a),
item (5) state:
uProcedures have been estabflshed for notification, by the licensee, of State and local response organizations and for notification of emergency personnel by all organizations; the content of initial and follow-up messages to response organizations and the public has been established; and means to provide early notification and clear instruction to the populace within the plume exposure pathway Emergency Planning Zone [EPZ] have been established."
The December 2019 FEMA Radiological Emergency Preparedness {REP) Program Manual states, "the alerting and notification of the public Is a function of the state, local, tribal and territorial governments' emergency plans. An NPP [Nuclear Power Plant] applicant/licensee is required to demonstrate that the administratl\/e and physical means are established for alerting the public and providing Instructions, regardless of who implements the ANS [Alert and Notification System] capability. An applicant/licensee may install and maintain the ANS but the responsibility for the alerting and notifying the public, as well as the activation of the ANS, remains with the state, local, tribal and territorial governments."
This ANS design report describes the physical and administrative means established by Entergy to assist the states and counties in alerting and notifying the public in an emergency. Detail of the state and county actions can be found in the state and county radiological emergency plans.
As discussed rn the December 2019 version of the FEMA REP Program Manual, the initial federal guidance on ANS provided in NUREG-0654/FEMA-REP-l, Rev. 11, Appendix 3 {1980) and FEMA-REP-10 ("Guidance for the Evaluation of Alert and Notification Systems for Nuclear Power Plants") (1985) "predated technology many citizens now take for granted (e.g., smartphones, social media, etc.)." As such, the FEMA REP Program Manual is now the recognized federal ANS guidance document as it uallows evaluators to account for new technologies, consider updated NRC/FEMA guidance, and incorporate REP l~ssons learned." This ANS design report adheres to the guidance of th~ latest FEMA REP Program Manual (December 2019), but does rely on data and Information from the following additional guidance documents:
* NUREG-0654/FEMA-REP-l, Rev. 11 (1980) including Supplement 4 (2011)
* FEMA CPG 1-17, HOutdoor Warning Systems Guide" (1980)
* FEMA-REP-10 (1985)
* FEMA Technical Bulletin (Version 2.0) uautdoor Warning Systems" (2006)
* NUREG-1022, Revision 3, "Event Report Guidelines 10 CFR 50.72 and SO 73 (2013)
* NEI 13-01, Revision 0, "Reportable Action Levels for Loss of Emergency Preparedness Capabilities" Part V, Section B of the 2019 FEMA REP Program Manual discuss ANS design objectives. The minimum acceptable design objectives for coverage by an ANS - what the system must be able to do when speed is critical - Include:
1 This document IS outdated, being replaced with Rev 2 rn December 2019. One of the goals of Rev. 2 of this document and of the December 2019 revision of the FEMA REP Program Manual was to not rnen!Jon spectfic technologies (1 e, Sirens) m reference to ANS Nonethel-, Rev 1 of 1h18 document does indude valuable guidance on outdoor warning sirens Arkansas Nuclear One                                          1                                ANS Design Report - Rev. 4
* The capability to provide both an alert signal and an informati onal or instructional message to the population In the EPZ within 15 minutes.
* The initial notificati on system will ensure direct coverage of essentially lQO percent of the population within 5 miles of the NPP site.
* Notification methods will be established to ensure coverage within 45 minutes of essentially 100 percent of the population in the EPZ who may not have received the initial notificatio n including any special requirem ent exceptions (e.g., large water areas with transient boats or remote hiking trails).
* The capability of the ANS to cover essentially 100 percent of the population within the EPZ, regardless of failures. The corrective means/measures will be conducted within a reasonable time, with a recommended goal of 45 minutes. The use of a sequential failure model or "primary and backup" ANS model Is acceptable. Other models, such as simultaneous or concurre nt activation models, could be !,JSed.
All of these criteria are met by the ANS system in the Arkansas Nuclear One (ANO)
EPZ, as discussed in the sections below.
2      Requirements 2.1    System Coverage 2 1.1    Population The ANO site is located near the Town of Russellville in southwes tern Pope County, Arkansas. The EPZ is located entirely within the State of Arkansas and consists of portions of four counties
                                                                                                -Johnson , Logan, Pope, and Yell Counties. Figure 1 shows the location of ANO as well as the approxim ate 10-mile EPZ.
The permanent resident populatio n In the EPZ Is 52,871 people according to the 2010 Census. Table 1 summarizes the permane nt resident population and population density In the EPZ, by Zone, for the last two decennial censuses conducted by the U.S. Census Bureau. As the data indicate, population in the EPZ has increased since 2000, with an increase of +3.8% for the 2-mlle radius of the plant, +12.8% for those Zones within the 5-mile radius, and +13.6% for the EPZ as a whole.
A common method for displaying population around a nuclear power plant is by sector.
The EPZ Is divided up into one-mile increments and the sixteen cardinal and Inter-cardinal wind directions
                                                                                              , for a total of 160 sectors. The 2010 EPZ permane nt resident population, by sector, Is shown In Figure 2.
The federal guidance; FEMA-REP-10, "Guide for the Evaluation of Alert and Notificati on Systems for Nuclear Power Plants/ indicates that sirens are in compliance with federal guidance if they meet either of the following conditions:
    *    "The expected siren sound pressure level generally exceeds 70dBC where the populatio n exceeds 2,000 persons per square mile and 60dBC in other inhabited areas; or
* The expected siren sound pressure level generally exceeds the average measured summer daytime ambient sound pressure levels by lOdB (geographical areas with less than 2,000 persons per square mile).H FEMA CPG 1-17, "Outdoo r Warning Systems Gulde" indicates that people typically mentally block out sounds that are not pertinent to what they are doing. In order to break the mental block, a warning sound Arkansas Nuclear One                                    2                            ANS Design Report - Rev. 4
 
must be about 9dBC greater than ambient noise to capture the attention of the listener. This is.the basis of the conseivative l0dBC above ambient noise guidance. Ambient noise levels were not measured in the ANO ,EPZ; thus, 60dBC and 70dBC will be used as the criteria for siren sound levels in this report, depending on the population density In a given area In order to determine whether 60dBC or 70dBC coverage is needed, population density was computed.
There are many different methods for computing population density:
* Population density by radial distance mile radius, 5-mile radius, or the full approximate 10-mile EPZ
* Population density by county
* Population density by municipality As shown in Table 2, these population densities differ significantly, underscoring the uneven distribution of population in the EPZ. Higher sound pressure levels are required in densely populated areas to overcome the' higher ambient noise levels associated with a larger number of people and increased activity. Computing the population density by a large radial distance, or by county can distort population density by incorporating large land areas that are unpopulated or sp~rsely pop'ulated. This could result In the failure to adequately identify areas that need 70dBC coverage. For example, Table 2 indicates that ~he municipalities in the EPZ have population densities ranging from 211 to 1,303 people per square mile.
However, when considering the population density for each county as a whole, it is considerably lower (ranging from 24 to 76 people per square mile).
The most refined method for computing population density is by census block. The U.S. Census Bureau divides the U.S. into census tracts. These census tracts ara in turn divided into block groups, and block groups are comprised of multiple blocks. The census block is the finest level at which the U.S. Census Bureau aggregates detailed population data.
Census blocks vary in size from as small as a single city block to as large as an entire county. Given the variance in block size, there is the potential to have abno.rmaliy high population density for a block with a very small area. Similarly, a* small neighborhood can have a population density exceeding 2,000 people per square mile but it may be the only community for miles. Assuming this neighborhood has 100 people living in an area of about 0.04 square miles (approximately 26 acres - 50 homes on 1/2-acre plots), the population density would exceed 2,000 people per square mile. However, if there are no surrounding neighborhoods, 100 people are not likely to generate enough background noise to warrant 70dBC coverage.
The last physical census'in the United States was conducted in 2010 (the 2020 Census is ongoing, but data will not be released until March 31, 2021). Thus, the 2010 Census serves as the basis for all population estimates m this document. Each year in May, the U.S. Census Bureau releases projected populations for each state, county and municipality in the U.S. The latest available census population estimates, as of July 1, 2019, which were released in May 2020 (when this analysis documented in this report was started),
from the U.S. Census Bureau were used to compute annual growth rates by county and municipality.
These growth rates were then used to extrapolate the 2010 census population In the EPZ to 2020 at the Arkansas Nuclear One                                  3                          ANS Design Report- Rev. 4
 
block level. For more informati on, please refer to the 2020 Evacuation Time Estimate (ETE) update 2 for ANO.
The following methodology was used to compute populatio n density within the EPZ, by census block.
Population block data was overlaid on the EPZ boundary using Geographic Informati on Systems (GIS) mapping software. The population density was computed by dividing the 2020 extrapola ted population by the area of the bloc~ In square miles. Any block with a density exceeding 2,000 people per square mile was flagged (block color coded red) as high density as shown In Figure 3.
As discussed above, there Is a possibility of isolated neighborhoods or extremely small census blocks being flagged with abnormally high populatio n densities. While mathematically the populatio n densities are correct, these anomalous census blocks do not represent densely populated areas, that would have significant background noise warrantin g 70dB siren sound levels. Two steps were taken to remove these anomalous census blocks from the actual high population density areas:
: 1. A filter was applied which eliminate s all flagged blocks that have a population less than 100 people or an area less than 0.02 square miles. This filter eliminates sparsely populated census blocks which are abnormally small and result In unrealistically high populatio n densities. Figure 4 displays those blocks which are still flagged after applying this filter.
: 2. Each flagged census block with a populatio n density exceeding 2,000 people per square mile was converted into a circle with an area of 1 square mile, centered at the center ofthe block. These 1 square mile circles were then overlaid with the census block data once again and the population density of the 1 square mile circle was recalculated. If the density exceeded 2,000 people per square mile, the block which the circle was centered at remained flagged as having a high population density. If the density of the circle fell below the threshold, the block the circle was centered at was removed from consideration. This filter eliminates isolated high population density neighborhoods that are surrounded by areas of low populatlo n density.
Figure 5 shows an example of this filter applied to three census blocks In the EPZ. Both blocks shown in Step 1 are flagged as high population density blocks after applying Filter 1. However, when drawing the 1 square mile circles (Step 2.1) centered at the blocks, the populatio n density (Step 2.2) is well below the 2,000 people per square mile threshold. As a result, both blocks are eliminate d as high population density blocks (Step 2.3). Figure 6 shows the final blocks flagged as having population density exceeding 2,000 people per square mile in the EP~ after the two filters were applied.
2.1.2    Geographic Area The ANO site Is situated on a peninsula formed by Lake Dardanelle, which Includes the Arkansas River and the former Illinois Bayou. The land within 5 miles of the plant is gently rolling and contains a number of ridge-valley configurations. The Arkansas River and Lake Dardanelle roughly bisect the ANO EPZ.
The meteorological Information for each of the EPZ counties is described below.
Johnson County3 is characterized by hot summers and cold winters, with an average high temperature of 90 degrees Fahrenheit ("F) in July and an average low temperat ure of 27°F in January.
The average rainfall 2
  "Arkanaas Nuclear One 2020 Population Update Analysis", KLD TR - 1167, dated September 19, 2020
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and snowfall in the county is 50 inches and 4 inches, respectively. The number of days with any measurable precipitation is 96. Johnson County is at an averag': elevation of 1,017 feet.
Logan County" Is also characterized by hot summers and cold winters, with an average high temperature of 92°F in July and an average low temperature of 28°F in January. The average rainfall and snowfall in the county is 49 inches and 2 inches, respectively. The number of days with any me_asurable precipitation Is
: 95. Logan County is at an average elevation of 678 feet.
Pope County5 is also characterized by hot summers and cqld winters, with an average high temperature of 91 °F In July and an average low temperature of 28°F in January. The average rainfall and snowfall in the county is 50 Inches and 4 inches, respectively. The number of days with any. measurable precipitation is 101. Pope County is at an average elevation of 835 feet.
Yell County6 is also characterized by hot summers and cold winters, with an average high temperature of 93°F In July and an average low temperature of 29"F in January. The average rainfall and snowfall in the county Is 5.1- inches and 3 inches, respectively. The number of days with any measurable precipitation is
: 95. Yell County is at an average elevation of 626 feet.
j;igure 1 identifies the municipal areas and major roads in the area, as well as the 15 Zones that comprise the approximate 10-mile EPZ. The Zones are color-coded based on the county they are In.
The National Oceanic an_d Atmospheric Administration {NOAA) commissioned a study 7 to summarize historical wind data from 1930 to 1996 in the United States. Wind data was aggregated for Fort Smith Regional Airport, which is the closest airport to ANO. The average wind speed at Fort Smith Regional Airport, based on the data gathered, ranges from a low of 6 miles per hour (mph) in July to a high of 8mph in January.
As shown In "Figure 1 and listed in Table 2, there are 6 municipalities within the EPZ. Most of the municlpallties are located adjacent to the Arkansas River and Lake Dardanelle. Beyond the population centers is sparsely populated rural farmland or undeveloped land.
The population centers in the ANO EPZ are connected by_an extensive highway network. Interstate 40 and US Route 64 travel northwest-southeast through the EPZ. The major state highways servicing the EPZ include Arkansas State Routes -7, 22, 27, 28, 124, 164, 247, 315, 326, 331, 333 and 359. The primary railroads within the EPZ include Dardanelle and Russellville Railroad and Missouri Pacific Railroad .
2.1.3      Means The physical means of alerting and notifying the public within the ANO 10-mile EPZ is the Emergency Warriing System (EWS} that consists of a mixture of the Siren Warning System {SWS) and the NOAA Tone Alert Sy51:em. The ANS is essentially designed to notify the Individuals In the 10-mile EPZ within 15 minutes of the issuance of recommendations by the State of Arkansas for radiological emergencies at ANO. Local fire departments in the EPZ and route alerting are used as the backup method to alert the public to receive instructions, information, and necessary actions to be taken.
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2.1.4    Primary Methods The primary ANS for ANO is the EWS as discussed above. The SWS is used to alert the more densely populated areas shown in Figure 7. Based on the population estimates discussed in Section 2.1.1, the SWS covers 92.6% of the population within the EPZ at 60dBC or higher. Those residents of the 10-mile EPZ who live outside the siren coverage area or who have special needs are alerted by NOAA Tone Alert Radios (TAR). NOAA TARs are also provfded to the facilities within the 10-mile EPZ with significant population.
These Individuals and facilities are further discussed In Section 2.2.
The SWS relies on SO Whelen omni-directio nal electronic sirens (21 WPS2807 sirens and 29 WPS2907 sirens). Of the 50 sirens, there are 2 sirens in Johnson County, 3 sirens in Logan County, 33 sirens In Pope County and 12 sirens in Yell County. All sirens are mounted at pole top, approximate ly SO feet above the ground. The location, height and ID for each siren are presented in Table 3.
All of the sirens are radio-contro lled and a DTMF (Dual Tone Multiple Frequency) encoder is required for activation. Sirens include a National Nuclear Attack signal that insists of an up-and-down scale tone. This three-minute continuous tone signal will be used to alert the populace to tune into NOAA TARs and local radio stations for emergency information (primary notification). Sirens also include a warning signal. This signal is used to alert ,the populace of not only a radiological incident, but also of natural disasters, especially tornado warnings.
The Arkar:isas Department of Health (ADH) maintains a database of addresses that are outside of the 60dBC siren coverage area. Each year a letter Is sent to those addresses to verify if they have a NOAA TAR and If It is functioning. If they do not have a TAR or if the TAR is not functioning, they can request that ADH provide a TAR. The ADH also mails batteries to the TAR holders annually.
The NOAA Tone Alert System is operated in cooperation with the National Weather Service (NWS). When activated, a loud tone is emitted from the radio to alert the user. Following activation of the receivers, live or pre-recorded emergency messages are broadcast to instruct/noti fy the public. Section 3.1 below provides additional details of the EWS.
2.1.5    Backup Methods Supplem_ental notification to the EPZ population is provided by local fire departments In the EPZ. In the event of siren or NOAA Tone Alert System failures, route alerting is implemented in the affected fire distrlct(s) using truck sirens and Public Address (PA) systems for notification of residents around the failed or inoperable siren(s). The truck sirens serve as the backup alert method, while the announceme nts being made over the PA system serve as the backup notification method.
2.2      Population/Demographics In addition to the permanent resident population detailed in Section 2.1.1, there are transients who may be visiting the EPZ for recreational purposes. Those people who live and recreate In the EPZ have already been considered as permanent residents to avoid double counting population.
According to the latest ETE study done for ANO (KLD TR-S17, "Arkansas Nuclear One - Developmen t of Evacuation nme Estimatest Rev. 1, dated December 2012), there could be as many as 11,74S transients in the EPZ at peak times. Th'e transient estimate is based on data provided by county emergency management agencies.
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There are 69 special facilities identified in the EPZ. These facilities lndude schools, universities, parks, campgrounds, golf courses, marinas, recreational areas, lodging facilities, major employers, medical facilities, and correctional facilities. The EWS is capable of alerting and notifying each of these special facilities. Nonetheless, the State has plans in i;:ilace to notify each of these facilities individually.as discussed below.
As per the Arkansas Comprehensive Emergency Management Plan (ARCEMP), Rev. 39, dated September 30, 2019, the State Department of Parks and Tourism will provide notification of the public within the park system; the State Game and Fish Commission and State Forestry Division will provide backup communications and personnel for notification purposes in remote forest areas, and on rivers and lakes; the ADH repeater system will alert the emergency response agencies and schools within the 10-mile EPZ through the Early Notification System (ENS) component of the EWS; and infonnation contained in                        the Emergency Instruction Booklet8 (EIB) is posted and/or placed in public locations within the 10-mile EPZ such as public buildings, state and national parks, recrea_tional areas, tourist infonnation centers and rest areas located on major highways, _which are routinely visited by transient populations. Postings will be checked periodically and updated as needed. In addition, letters of agreement formalizing the emergency notification interfaces between Entergy and Arkansas tech University in Russellville are kept on file in Entergy's offices.
None of the areas discussed above are considered exception areas. They can all be alerted and notified in a timely fashion.                        -                                                                  -
Special provisions have been developed by ADH Nuclear Planning & Response Pr(?gram (NP&RP) and Entergy for the alerting of identified handicapped individuals. A p~stage-prepaid, detachable postcard is provided in the' annual mailing of the EIB for use by persons who may have special needs. This form is to be completed and then mailed to the ADH NP&RP office, and the infonnation Is subsequently provided to the appropriate local government. The individuals wlth special needs, depending upon their handicap, are notified appropriately. The notification may includ~ door-to-door notification by law enforcement officers, neighbors, telephones, or tone activated NOAA TARs. Persons who are hearing impaired, or who require special notification are provided NOAA TARs free of charge. These receivers ~re also made available to the large businesses, hospitals, nursing homes, schools, day reception centers, and other applicable groups within the 10-mile EPZ.
According to American Community Survey 2014 - 2018 data9, the percent of non-English speakers within the EPZ is approximately 0.56%. Given the small size of non-English speaking population, English is the only language used for notification.
2.3      Interoperability The SWS is divided into 5 siren activation zones of relatively higher population density covering parts-of the 10-mile EPZ, specifically: Yell County (lZ as Zone 1), the Russellville/Dover area and the Village of London in Pqpe County (2Z and 3Z), Johnson County (4Z), and Logan County (SZ). Each of these zones can be activated independently or in conjunction with other zones. All zones would be activated in the event of emergency at the ANO site.
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The ADH has the sole ability to activate the SWS. There are three activation points - one primary and two backup points, as discussed in Section 3.1.3 and Section 3.3.1. The locations of the activation points are outlined in Table 4. All the activation points have backup power and two independe nt paths for activation slgnals to reach the sites. The SWS is activated by radio signal in the UHF (Ultra High Frequency
                                                                                                          ) band which Is ~ransmitted by the primary/ba ckup siren radio transmitte r. The architectur e of the SWS activation is discussed in detail In Section 3.1.3. The SWS activation Is also made available to local governme nts for use in severe weather and other emergencies. Authorized officials may request siren activation for various zones in their jurisdiction s.
The sirens are battery operated and are powered by four high capacity batteries. Battery charge is maintained by AC power through "smart" chargers to avoid overchargi ng. Sirens, depending on use, can keep operating up to 10 days without AC power. The ADH has mobile generator units that can be used in the event an AC power outage exceeds that length of time.
The NOAA TARs are activated by the NWS through a 300-watt transmitte r with a 300-watt backup transmitte r. The NWS is contacted by the ADH staff and infomied of the intent to activate the EWS. The NWS is notified in advance of the sirens being activated such that, In conjunctio n with the siren activation, the NWS activates the NOAA tone which automatica lly turns the receivers on.
2.4    Operations ANO maintains the capabilities to assess, classify, and declare an emergency condition within 15 minutes of the availability of Indications to plant operators that an emergency action level has been exceeded.
Emergency personnel are trained to promptly declare the emergency condition as soon as possible following identificati on of the appropriat e emergency classificati on level. There are four emergency classification levels - Notificatio n of Unusual Event, Alert, Site Area Emergency and General Emergency .
The EWS within the 10-mile EPZ might be activated by ADH for a Site Area Emergency and will be activated for a General Emergency.
The final decisions to alert and notify the public by the EWS are the decisions of governmen tal officials.
Initial notification is made to the state and local authorities within 15 minutes after declaring an emerge'ncy. An Emergency Action Authentica tor is used to verify messagl:!s that are received over a non-secure system, such as commercia l telephone system. The NRC is notified Immediate ly following notification of state and local authorities and within 1 hour of the de~ared emergency.
'The EWS cari be fully activated from the ADH Emergency Communic ation Center (ECC), the alternate State Emergency Operations Facility (SEOF) or the ADH NP&RP office. Anytime the SWS is to be activated to notify the public, ADH NP&RP will take over operation of radio station KXRJ, 91.9 FM at Arkansas Tech University. ADH NP&RP has the capability to remotely take over broadcast of this station and provide the public with any emergency communic ations or protective actions that might become necessary.
The detailed activation process Is included In Appendix B.
2.5    Management/Administration It is the responsibi lity of ADH to manage and oversee the EWS network. The NOAA radio pr~ram Is administra ted by ADH NP&RP and operated by NWS. The NWS is responsible for managing the weather radio transmitte rs nationwide .
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2.6    Security and Privacy 2.6.1    Physical Security All siren batteries and control boxes are pad locked and mounted on the siren pole to prevent tampering, and both AC and battery voltage can be monitored remotely. The siren activation equipment is installed at se_cure locations that are manned 24 hours per day. Entry into all activation points is limited to authorized personnel only. Additionally, all activation consoles are equ'ipped with a physical keyed lock to prevent access to the activation keys.
2.6.2    Logical Security To prevent cyber-attack, the actual activation of the EWS is accomplished by use of a DTMF encoder requiring key-lock activation. Details of either activation procedure are limited to a "Need-to-Know" basis for security reasons.
2.7    Maintenance/Repair 2.7 1    Preventative Maintenance It is the responsibility of ADH NP&RP to perform the Preventive Maintenance (PM) on the SWS. On a quarterly basis, the PM is performed following the instructions listed in the ANO SWS Maintenance Plan (see Appendix C). During the scheduled PM, each siren may experience brief periods when it is not able to sound, but it Is not taken out of service for more than a few minutes and could be returned to service immediately, if needed. As noted in the maintenance plan, a wide variety of inspections are performed at each siren site including verification that there is no vegetation growth that can obstruct sound propagation near the siren head; visual inspection of the pole, the antenna, the siren head, the cabinet and associated connections; verifying acceptable condition of the batteries and chargers; and running a silent test. In addition, the ADH performs the maintenance with contractor assisted items, such as crane rental for upper driver maintenance.
The ADH NP&RP also checks the operation of the control points and transceivers associated with the activation system on a routine basis. The operability of key components, for Instance, is verified every weekday. Additionally, a contractor Is used to measu~ the transceiver perimeters.
The ADH NP&RP mails Information annually to every address within the 10-mile EPZ to provide the contact in'formatiO!J for the request of the NOAA TARs. On a monthly basis, the ADH mails letters to t~e new residents within the 10-mile EPZ to notify them of the same information. Recipients of the NOAA TARs are tracked in a master database by the NP&RP staff as discussed in Section 2.1.4. Needed repair and/or replacement of the receivers identified as defective is also carried out by the NP&RP staff. All the holders of the NOAA TARs receive new batteries and instructions from the ADH annually.
2.7.2    Corrective Maintenance Upon notification of a siren malfunction, the ADH determines if the failure(s) is reportable in accordance with 10CFR 50.72, and the noted siren malfunction is immediately serviced by an ADH NP&RP Electronics Technician and every attempt is made to return the unit to operation. If the siren is unavailable, the appropriate county is notified that the backup alert method - route alerting - will be required in the affected area until the unit is returned to service.
I A siren that did not fully respond to the activation command signal during a valid test is considered as an activation failure and would not have provided adequate public alert. It would be reported as a siren Arkansas Nuclear One                                  9                          ANS Design Report - Rev 4
 
failure to FEMA and to ANO Emergency Planning (EP) personnel. A siren is considere d out of service when it cannot receive, process, or sound the appropria te audible warning tone through the driver section.
When determin ation has been made that a SWS compone nt is not responding appropria tely to polling, such as low battery, AC voltage or related issues; or reports or concerns from the public indicating siren abnormal behavior, an on-site Inspection and repair will be performe d by an ADH NP&RP Electronics Technician. The Electronics Technician will follow the guidelines recommended in the manufact urer's operating and troublesh ooting manuals (see Appendix D) to restore compone nt functiona lity. The Electronics Technicians also meet routinely with the ADH Section Chief to Identify any maintenance and/or performance trends. Trends are noted and corrective actions are impleme nted, if needed.
In addition, the ADH tests the siren control transmitt ers and consoles every weekday morning, when the state offices are open. If a problem is identrfied , the corresponding corrective action Is immediat ely undertaken. The use of redundan t transmitt ers and activation points minimizes the risk of a failure of the activation system.
2.8    Availability/Reliability Appendix 4 of FEMA REP-10 specifies that the operabili ty of a siren system is considere d acceptable "when an average of 90% of the sirens (as determin ed by a simple average of all regularly conducted tests) can be demonstrated functiona l over the 12-month period immediat ely preceding the submittal of the design report.N The Nuclear Energy Institute (NEI) Regulatory Assessment Performance Indicator Guideline, NEI 99-02 Revision 7, specifies a minimum performance indicator threshold of 94% for ANS Reliability during the previous four quarters for plants operating in the normal regulator y response band.
The ANO SWS reliability data is reported to FEMA for review on a quarterly basis.
According to the ADH, the ANO siren system has been operational since 1981 A review was complete d over the past 10 years and it was determin ed that the successful siren performa nce has not dropped below 99% during that time. Table 5 shows the results of siren tests at ANO for the last 4 quarters.
As shown, the siren performance in each quarter of 2019 was 100%.
2.9    Testing The EWS is tested by ADH and NWS periodically to ensure Its readiness. The testing includes functiona lity of sirens and of NOAA TARs.
The entire SWS is sounded weekly to reinforce public awareness of the system. This is not a silent or growl test, but either a 15-second or 1-mmute audible test each Wednesday at 12:00 pm. Testing will not be performed if severe weather is present in the area or the state offices are closed. Under a verbal agreement with FEMA, the 1-minute audible test is performe d on the 4 th Wednesd ay of the month. The operation of each siren Is verified once per month and the results are reported to FEMA. Due to the fact that the weekly audible test far exceeds the annual federal operabili ty requirem ent, other types of audible tests are not conducted at the ANO.
In addition to the weekly audible test, sirens are polled for health maintenance at least once per month.
The health of siren batteries is assessed by the ADH NP&RP Electronics Technicia n on a quarterly basis (see Section 2.7.1). Batteries are replaced at a frequency that exceeds the battery manufact urer's recommendations. The siren activation equipme nt is tested frequentl y (see Section 2.7 2). Special Arkansas Nuclear One                                10                            ANS Design Report - Rev. 4
 
observations may be conducted in the event of severe weather or high winds which might result In physical damage, such as identifying loose feed lines or pole damage. If any issues are identified during these observations, repairs will be undertaken using the ANO SWS Maintenance Plan in Appendix C.
The NOAA TAR activation is tested by the NWS and monitored by ADH NP&RP. The testing Is performed each Wednesday between 11:00 am and 12:00 pm. If inclement weather persists, the testing will be performed the next clear day.
The current testing conducted by ADH exceeds the annual maintenance recommended by the NRC. This includes actions specifically designed for the ANO EWS. The testing records are kept in the ADH NP&RP office.
2.10 Responsibility It is the responsibility of ADH NP&RP to perform or supervise maintenance on the entire EWS network (except for the NOAA radio system and local broadcast stations and radios) and to ensure that it Is functioning properly. In general, the electronic component control and radio parts are maintained and rep_aired by ADH. The items requiring the use of a crane or other specialized equipment are maintained and repaired by contractors. The NOAA radio system is tested by the NWS and monitored by ADH NP&RP and by ANO EP personnel (see Section 2.9 and Section 4.3). A local contractor is responsible for maintenance and repair of the NOAA weather radio transmitters.
2.11 Training It is the responsibilities of ADH NP&RP to identify organizations with a need for training and provide training and refresher training on a continuing basis. Refresher training shall be made available to emergency personnel at least annually. At a minimum, these emergency workers will have attended the FEMA REP Planning course. The training required for emergency personnel is discussed in Section 7.
2.12 Quality Assurance The ADH maintains several procedures pertaining to the ANS, including procedures on activation, testing, maintenance, repair and reportability. These procedures are included in Appendices Band C. The records regarding the SWS testing and maintenance are maintained by ADH and routinely reviewed by ANO.
Copies of the quarterly reports detailing siren system perfonnance are also provided to ANO. Additionally, the ANO is provided the results of activation verification on a monthly basis.
In addition to these procedures above, the EWS 1s tested on a weekly basis as discussed In Section 2.9.
Hence, the essential elements of the SWS activation are "practiced" weekly. These extensive exercises help to reduce errors during the operation.
The NOAA weather radio test data is not reported as the weekly test 1s not guaranteed due to the weather conditions The records of the NOAA radio system performance are not maintained as it is outside ADH's area of responsibility. However, the ADH notifies the NWS of service interruptions monitored (see Section 4.3) and provides assistance in resolving problems. As noted In Section 2.10, a local contractor is responsible for the maintenance and repair of the NOAA weather radio transmitters.
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3    Description/Performance 3.1    Physical requirem ents 3.1.1    System Components As discussed In Section 2.1.4, the siren system is comprised of SO omni-directional electronic sirens.
Figure 8 maps the sirens in the EPZ. The sirens are labeled with their Identification number and are symbolized by siren model type. Table 3 lists each of the SO sirens In the ANO EPZ. The table includes the siren Identification number, the latitude and longitude of the siren, the siren model, the mounted height of the siren and location description.
WPS2807 and WPS2907 sirens can produce approxima tely llS.ldBC and llS.SdBC, respective ly, at 100 feet along their centerline with operating frequencies between 500 and 630 Hz, based on the results of the near-field tests discussed In Section 4.1.
A WPS2807 or WPS2907 siren consists of a power supply (batteries), a control board, seven 400-watt audio drivers, seven audio amplifiers, and a radio transceiver for reception of control signals.
The batteries, control board, amplifiers and transceiver are located in a sealed and locked enclosure.
The siren drivers are pole mounted at approximately 50 feet above the ground. All sirens have multiple ground points and surge protection, including antenna feed lines.
Over the past 30 years, the ADH has Issued numerous NOAA TARs of various models and manufactu rers.
Nevertheless, all the radio receivers must respond to the 1050 Hz alert tone and feature an audible warning. The ADH also provides models with a visual signal to alert deaf or hearing-impaired individuals The NOAA TAR have a battery backup feature which allows the user to install batteries, such that the radio will work during a power outage. New batteries are Issued annually to each of the NOAA TAR holders as discussed in Section 2.1.4 and Section 2.7.1.
3.1.2    User Interfaces The WPS2800 and WPS2900 series sirens can be remotely activated by using an encoder and siren radio transmitte r. The logical connection between the siren control components is further discussed In Section 3.1.3. The NOAA TARs are activated by a primary 300-watt transmitter. A secondary 300-watt backup transmitte r would be used following a failure of the primary transmitter. Both primary and secondary backup transmitte r sites are located on Mount Nebo, which is approximately 6 miles SSW of the ANO site.
Entergy has provided backup generator capability for the transmitte r site. Hot standby switching for auto-start of the backup transmitte r and a backup generator with auto-start capability is also available and tested frequently.
3.1.3    Functional Block Diagrams Figure 9 shows the logical connection of the components of the siren control system. As shown in the diagram, there are three different locations that can communicate with the primary and backup siren radio transmitters which in tum communicate with the siren sites via a utility microwave link or a leased line which Is a circuit rented from a public carrier -AT&T in this case. The ADH Mobile Command Post can communicate with the primary and backup radio transmitte rs via radio line. The primary/ba ckup siren radio transmitters activate sirens by UHF-FM radio signal. Section 2.3 further discusses the physical connections of the system and the interopera bility.
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3.2    Administrative Components 3.2.1    Organizational Responsibilities The ADH ECC is the official 24-hours-per-day point of contact between the State and ANO for the Initial notification of a radiological incident. In the event of an emergency, the operator of ANO Is responsible for notifying the ADH ECC, Arkansas Department of Emergency Management (ADEM), and the warning points In Conway, Johnson, Logan, Pope and Yell Counties. The final decisions to alert and notify the public by the EWS are the decisions of governmental officials.
The responsibilities of ADH NP&RP include off-site emergency planning and response to emergencies involving ANO; the development and update of emergency response plans; the maintenance and operation of the EWS and the communication system used to notify state agencies and local governments of emergencies; the maintenance of equipment and supplies necessary to support emergency operations for state and local agencies; the development and training of emergency personnel who would respond to an emergency; and the distribution of emergency instructions to the public.
The primary means of notification and communication between ANO and the state and local governments will be via the ANO Dedicated Emergency Facsimile/Voice System (DEF/VS). In the event that the ANO DEF/VS is not operating properly, the operator of ANO will notify the ADH ECC directly by commercial telefax or by commercial telephone; and ADH, In turn, will notify the county warning points and ADEM using various means, such as the DEF/VS, ENS radio, ADEM radio, and/or commercial telephone. If both communication procedures outlined above fail, the operator of ANO will use commercial telephone to notify the ADEM which will, in turn, notify the ADH ECC. The ~ommunications link between the state and federal emergency response organizations is via the commercial telephone system, with the National Warning System (NAWAS) serving as the backup system.
3.2.2    Management As noted in Section 2.6, the activation consoles are key locked and kept at secure locations to prevent the inadvertent systemwide activation, and the siren control system is configured In such a way that a systemwide inadvertent activation is very unlikely to occur. There are limited failure paths which will result in an inadvertent activation, such as included high voltage that shorts a control cable. In the event of an inadvertent siren activation, the ADH sends the notification to area broadcast stations and to appropriate 911 Centers to assure the public there is no emergency involving ANO. In an emergency Involving ANO, this responsibility falls on which of the State's centers have "Command and Contror'. For other situations, it depends on the time of day. After hours notification falls to the ADH ECC if the radiological emergency response team is not activated.
If siren(s) are inadvertently sounded, the cancellation tones are not automatically sent to the siren(s) due to the time factor. In most cases, reports of spurious siren sounding come In the form of calls from the public to the aJpropriate 911 Center which the~ notifies the ADH. It is noted that the sirens in Arkansas are hard coded to sound for 3 minutes before shutting off. As such, the siren has most likely "timed out" when the incident is reported. When the ADH receives a report of inadvertent siren sounding, the first step is to gather the information of the Inadvertent sounding reported, including the number of calls received, the generation location of the sound reported, the caller names and call back numbers. The ADH then will verify the existence of a siren in the reported activation area. If a siren is Identified in the reported area, a repair technician will visit the site to ascertain the status of the siren, and attempt to determine If Arkansas Nuclear One                                    13                              ANS Design Report - Rev. 4
 
there was an actual activation or if there were other noise sources that Imitate a siren. Most reported siren sounds are in fact from other sources, for Instance, emergency vehicle sirens.
3.3    Operational Compone nts 3.3.1    Activation As discussed previously in Section 2.3, the SWS is activated by ADH through the primary or secondary activation points. As shown In Table 4, the primary activation point for the SWS is located at the ADH ECC office that is manned 24 hours per day to accommod ate day or night activation. One secondary activation point for the SWS Is located In the SEOF which is co-located at the ANO site; another secondary activation point is located in the ADH NP&RP office. All the activation points have the ability to activate the entire SWS, but for events where ANO is not involved, such as severe weather, activation is usually conducted by ADH ECC or by ADH NP&RP.
The NWS is notified by the ADH staff in advance of the sirens being activated. The NWS in turn utilizes the primary/ba ckup weather radio transmitte r to transmit the NOAA tone which automatica lly turns the receivers on. Both primary and secondary backup transmitte r sites are located on Mount Nebo, which is approxima tely 6 miles SSW of the ANO site.
3.3.2    nming According to ADH, when an emergency is declared at ANO, the ANO operator must notify state officials within 15 minutes. State offlclals can then notify the public of an emergency within 15 minutes by use of the EWS. The EWS activation will be conducted with a sense of urgency without undue delay.
The sirens activate within seconds of the signal being sent from the controller. The N(?AA tone is activated in conjunctio n with the siren activation. The backup method - route alerting - Is capable of alerting and notifying the 10-mile EPZ population within 45 minutes (see Section 4.3 and Section 5).
There are no exception areas (rural, low population areas) In the EPZ that would require additional time to be alerted and notified.
3 3.3    Geo-Targeting Individual sirens within the siren system can be activated to pinpoint a geographic location for alerts; however, this is not part of the standard alert procedure. NOAA radios cannot be individually sounded.
4      Verification 4.1      Coverage ANO recently conducted an extensive ac0ustical study of the siren system, Including detailed acoustical modeling and field testing of siren sound levels. The results of this study are summarized below.
Section 2.0 of FEMA Technical Bulletin (Version 2.0) "Outdoor Warning Systems" dated January 12, 2006 provides an extensive discussion of sound propagation. Below are some key points on sound taken from this guidance document:
* Sound travels in waves
* Sound decreases in loudness at greater distances from its source
* Refraction: Sound waves can refract or bend with differences in temperatu re and wind speed.
The specific heat of the ground Is higher than that of the air above It. Thus, during the day, the ground Arkansas Nuclear One                                  14                            ANS Design Report - Rev. 4
 
is warm and temperature decreases as you move higher above the ground. This difference in temperature impacts the speed of sound waves as shown in Figure 10. The resulting shadow zone causes the audible level of the siren to be lower at the ground. The opposite happens in the evening when the ground releases its heat to the atmosphere resulting in higher temperatures the farther you get from the ground, as shown In Figure 11. This explains why sounds from the same source are louder at night than they are In the daytime.
* Ground Absorption: Soft ground such as grass covered soil or dense foliage can cause significant absorption of sound, thereby reducing perceived loudness of sound. Hard surfaces such as cpncrete, ice, or water can cause sound waves to reflect upwards and be perceived as louder as shown in Figure 12.
* Wind: Wind speed either adds or subtracts to the velocity of sound waves depending on whether the sound is moving upwind or downwind, resulting in refraction of sound waves. Wind speed also increases with height above the ground causing further refraction. The additive refraction of these two phenomena can result in a significant acoustical shadow zone In the upwind direction as shown in Figure 13.
* Diffraction: Sound waves can also be diffracted {bent upward or downward) by objects (buildings, trees) in the path between the source and the listener resulting in lower perceived loudness.
Figure 14 shows IJlUltiple potential factors that could impact the sound heard by a receiver from a source.
One way to deal with the complications that can impact the audible level of outdoor sirens is to use a sophisticated acoustic model that accounts for terrain and atmospheric conditions. Such a model, Sound PLAN, was used to predict t~e siren coverage In the ANO EPZ. The SoundPLAN software is a state-of-the-art acoustic model written by SoundPLAN, LLC (a German company) and distributed in the U.S. by Navcon Engineering Network In California. This software has been used to model the sire~ coverage for more than a dozen U.S. nuclear plants, induding the Diablo Canyon Power Plant In California, which has one of the most difficult terrains of any U.S. plant in terms of siren coverage.
Modeling Inputs and Assumptions The following inputs/assumptions were used in the acoustic modeling:
* Digital elevation d,ata was provided by the United States Geological Survey (USGS) National Map Vlewer1°. A standard DEMu, was downloaded with a resolution of 1/3 arc-second, which Is an approximate grid spacing of 10 meters. This is more than adequate to model the terrain in the EPZ.
* Major bodies of water including the Arkansas River, Illinois Bayou and Lake Dardanelle were explicitly modeled in the analysis using GIS mapping software.
* Ground surface absorption wa~ explicitly modeled. The software default value for ground surface absorption is 1 for all soft grounds such as fields or other grassy areas, and forests. The ground surface value was changed to O for major bodies of water to accurately depict the reflective properties of the hard surface.
* The siren locations and model type documented in Table 3 were input to the model.
10 http tMgwer na11onalr)lao aoy/baslc/
11 htlo*(lnationalmap aov/30EP/3deo orodsert html Arkansas Nuclear One                                      15                          ANS Design Report - Rev. 4
* Acoustical tests were conducted on June 23 and June 24, 2020 to measure the sound levels output by sirens. The tests included seven near-field tests in accordance with ANSI 512.14, wherein a sound meter was aimed at the center of the siren horns from a bucket truck parallel with the siren horns at a distance of 100 feet. In addition to the near-field tests, far-field tests were conducted with siren meters on the ground at varying distances form the siren pole. Five WPS2907 sirens and two WPS2807 sirens were tested. Figure 15 presents the locations of the near-field and far-field test locations. The tests were conducted by acoustical expert - Dr. Bruce lkelheime r - using Larson Davis Model 831 sound level meters - and were supervised by the ADH and Entergy personnel. Weather conditions during the tests were good, with low winds and no precipitation.
The test results were analyzed and reported by Dr. Bruce lkelhelmer (s-ee Appendix E). The results of the near-field tests are summarized in Table 6. Based on the overall average results, sound levels of 115.ldBC and 115.SdBC are adopted for WPS2807 and WPS2907 siren models, respectively. The ANSI 512.14 test sheets for the seven near-field tests which provide additional details on the test are included In Appendix E.
* The acoustical standard International Organization for Standardization (ISO) 9613-:2. 12 was used.
150-9613-2 Is a widely used standard for sound modeling and Is accurate at predicting total coverage areas at extended distances from the source.
* The average daytime temperature, pressure and humidity were used to account for atmospheric conditions. These data were estimated as the 3-month average of June, July and August of 2019.
The historical weather data was obtained from the Weather Underground website 13
* The location used was Hot Springs, which is located approximately 55 miles southeast of ANO. The atmospheric conditions used were:
o  Average tempera ture= 79.B"F (26.S-C) o  Average relative humidity = 77.2%
o  Average air pressure= 29.4 inHg (995.2mbar)
As discussed In Section 3.1.2, the NOAA TARs are activated by the primary/secondary weather radio transmitt er located in Mount Nebo. As per the latest county radiological emergenc y response plans, the NOAA weather radio primary/backup transmitt er at Mount Nebo covers the following counties - Conway, Johnson, Perry, Pope and Yell. This has provided adequate coverage to the radio receivers within the 10-mile EPZ.
4.2        Population/Demographics Based on the population density analysis using the 2020 population projections (see Section 2.1.1), the overall population density in the ANO EPZ is low. Only parts of Russellvllle have a population density exceeding 2,000 persons per square mile, as shown in Figure 6. As discussed in Section 2.1.1, federal guidance recommends siren coverage of at least 70dBC In areas where the populatio n density exceeds 2,000 people per square mile, and 60dBC In all other areas. Also, as discussed in Section
                                                                                                -1, the ANS should provide direct coverage of essentially 100 percent of the population within 5 miles of the NPP site.
Figure 7, maps the predicted siren coverage for the ANO EPZ output by the SoundPLA N software based on the inputs and_ assumptions discussed above. The map shows the 60dB and 70dB contours, as well as the high population density areas discussed in Section 2.1.1.
12 13 https //www ISQ,0rg/standard/20649 html httos llwww.wunderground com/
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As shown In the map, the 60dBC coverage covers the majority of the 10-mile EPZ. All the high population density areas flagged red in Figure 7 have adequate 70dB coverage. As discussed In Section 2.1.4, the ADH maintains a database of addresses that are outside the 60dBC siren coverage area. Letters are sent to those addresses an,nually to ensure NOAA TARs are available to ~hose addresses to ensure completed coverage of the EPZ by the EWS.
4.3    Metrics Sound levels during siren activation were measured In many locations as discussed In Section 4.1 and shown In Figure 15. These sound level measurements were used to calibrate the acoustical model and predict GOdBC and 70dBC of the siren system in the EPZ.
As discussed in Section 4.1, the NOAA TAR refeivers within the 10-mile EPZ are fully covered by the NOAA weather radio primary/backup transmitter at Mount Nebo. According to the ADH, the NOAA radio signal strength has not been reported as an issue by any NOAA TAR holders. As discussed In Section 2.5, the NOAA radio program is operated by the NWS and administrated by the ADH NP&RP staff. The ADH retains several radio receivers in the ADH NP&RP office for constant monitoring. The NOAA radio system is also monitored by ANO EP personnel.
As per federal guidance, the primary ANS means should be capable of alerting and notifying the EPZ population within 15 minutes, and the backup means should be capable of alerting and notifying the EPZ population within 45 minutes. According to the ADH, the time for the EWS (primary method) activation and route alerting (backup method) process has been evaluated by FEMA several times during the bi-annual evaluated exercises, al"!d the timeline has been acceptable. The time for actual physical activation of the ENS by pushing the button is a matter of seconds.
5    Availability/Rel~ability As discussed in Section 2.12, the ADH maintains several procedures to provide detailed information of performing testing, maintenance, and record keeping for system maintenance/repair activities. The system testing, maintenance and siren malfunctions have been discussed In detail In Section 2.7 and in Section 2.9. Appendices B and C details the Quality Assurance procedures that are in place which have resulted In a 100% reliability score for the ANS In 2019 and reliability scores in excess of 99% for the past decade (see Section 2.8}. The Inadvertent activation of the SWS and the actions taken thereafter are discussed In Section 3.2.2.
As discussed in Section 43, the ability to meet the minimum activation time of 15 minutes has been successfully demonstrated in the bi-annual evaluated exercises, including the latest one on July 17, 2018.
The evaluation details are reported in the After-Action Report/Improvement Plan published by FEMA.
6 Security and Privacy The applications used to activate the SWS can only be accessed by authorized personnel with unique user IDs and passwords. Section 2.6 provides additional detail on the physical and cyber security of the ANS.
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7      Training and Public Outreach The ADH NP&RP is responsible for arranging the initial and continuing training for all staff members who are assigned to the ANO radiological emergency planning effort. The elements of training required for emergency personnel include the review of emergency classification levels, protective action advisories, methods of notification, notification procedures, procedures for dissemination of public information during a nuclear generating plant emergency, emergency nptiflcation forms, emergency staff positions arid responsibilities, facility set-up, layout and equipment.
The publlc is instructed by the EIB to tune to NOAA TARs and local radio stations for emergency instructions when the sirens are activated. The local radio stations have the capability to broadcast emergency messages on a 24-hour basis to the general public. The EIB Is available in both English and Spanish and can be accessed thr9ugh the ADH webslte14
* The booklet also Includes contact information for emergency planning agencies should additional information on alert and notification or other emergency planning issues be needed.
In addition to the EIB, emergency information regarding notification procedures and those steps that should be taken in an emergency Is included in the official telephone directory distributed within the 10-mile EPZ and is updated annually. Education and informational programs are offered annually to area civic and service organizations, including public and private schools. These pro~rams include information on the EWS, evacuation routes, and designated care centers. An annual media workshop is conducted by ADH NP&RP to provide pre-incident information to the representatives of the Arkansas news media. The workshop provides Information on notification, evacuation and planning efforts. The ADH NP&RP will also provide the news media with periodic releases containing Information on any changes In notification, evacuation or planning efforts.
14 https.JlwNw.heelthy.arJqlnsas gov/prooralJ}S=mces{toolCS{nudea[:pjannmg-and-resoonse Arkansas Nuclear One                                          18                        ANS Dl:slgn Report - Rev. 4
 
SIGNATURE LIST My agency has reviewed the enclosed Alert and Notification (ANS) Design Report in its entirety. We find the report to be accurate and complete, and to be in 'agreement with our agency's emergency plans. My signature below is my attestation to such.
FEMA Regional Representative (Print/Signature)                                            Date Entergy Emergency Planning Representative (Print/Signature)                              Date Arkansas Department of Health (Print/Signature)                                          Date
 
REVISION HISTORY Date  Revision# Notes 3/5/1984      0    FEMA approval of original ANS for the ANO EPZ.
5/2009      1    Design report was updated to account for:
* One-for-one replacement of 34 electromechanical sirens with Whelen and ATI electronic sirens without modifying or changing the control system, antennas and radio systems.
* Results of an acoustical test following Installation of the new sirens to demonstrate that the updated siren system meets the design objectives.
* The Failure Mode and Effects Analysis (FMEA) of the completed siren system.
* Replacement of transmitters and radios for the tone alert system. ,
6/14/2011    2    Design report updated to correct siren GPS locations and siren coverage map.
5/2016      3    Design report was revised and supplemented to reflect the following changes:
2/2017
* One-for-one replacement of the 28 ATI sirens with Whelen 2900-7 senes sirens.
* Installation of an additional Whelen 2900-7 siren .
* Results of the near-field tests indicate that the replacement of the 28 sirens provide a higher siren rated output.
* Provide the Manufacturer's Technical Data, Operations and Troubleshooting Manual for the Whelen 2900-7 siren.
* A replacement transmitter and replacement radios for the NOAA Tone Alert System.
9/2020      4    Design report was requested to update to include:
* Update the siren coverage map using detailed Sound PLAN acoustical model and field testing of siren sound levels.
* New guidance on report format and report content in FEMA Radiological Emergency Planning Program Manual dated December 2019.
 
Table of Contents EXECUTIVE
 
==SUMMARY==
................................................................................................................. ES-1 MAIN BODY 1    Licensing Obligations ............................................................................................................................ 1 2    Requirements ................................................*....................................................................................... 2 2.1      System Coverage ..........................................................-................................................................. 2 2.1.1      Population ............................................................................................................................. 2 2.1.2      Geographic Area ................................................................................................................... 4 2.1.3      Means .................................................................................................................................... 5 2.1.4      Primary Methods .................................................................................................................. 6 2.1.5      Backup Methods ................................................................................................................... 6 2.2      Population/Demographics ............................................................................................................ 6 2.3      Interoperability ............................................................................................................................. 7 2.4      Operations .................................................................................................................................... 8 2.5      Management/Administration .........................................................:............................................. 8 2.6      Security and Privacy ...................................................................................................................... 9 2.6.1      'Physical Security .................................................................................................................... 9 2.6.2      Logical Security: ..................... '. ........................................ :..........................................._........... 9 2.7      Maintenance/Repair ......................................................'...... ._........................................................ 9 2.7.1      Preventative Maintenance ........................ '. ........................................................................... 9 2.7.2      Corrective Maintenance ........................................................................................................ 9 2.8      Availability/Reliability ................................................................................................................. 10 2.9      Testing ......................................................................................................................................... 10 2.10      Responsibility ...._.......................................................................................................................... 11 2.11    Training ....................................................................................................................................... 11 2.12      Quality Assurance ....................................................................................................................... 11 3    Description/Performance ................................................................................................................... 12 3.1      Physical requirements ................................................................................................................. 12
      ,3.1.1      System Components ........................................................................................................... 12 3.1.2      User Interfaces .................................................................................................................... 12 3.1.3      Functional Block Diagrams .................................................................................................. 12 3.2      Administrative Components ........................................................... ,........................................... 13 3.2.1      Organizational Responsibilities ..........................................-................................................. 13 3.2.2      Management ........................................................................................................................ 13 3.3      Oper~tional Components ..................................................*.............. :.......................................... 14 3.3.1      Activation ............................................................................................................................ 14 3.3.2      nming .................................................................................................................................. 14 3.3.3      Geo-Targeting ..................................................................... :............................................... 14 4    Verification .......................................................................................................................................... 14 Arkansas Nuclear One                                                                                                    ANS Design Report - Rev. 4
 
4.1    Coverage ..................................................................................................................................... 14 4.2    Population/Demographics .......................................................................................................... 16 4.3    Metrics ........................................................................................................................................ 17 5    Availability/Reliability ......................................................................................................................... 17 6    Security and Privacy ............................................................................................................................ 17 7    Training and Public Outreach .............................................................................................................. 18 REFERENCES ***************************************************************************************************************************************R-1 LIST OF APPENDICES A. Compliance with F~deral Regulations and Guidance ....................................................................... A-1 B. ANO EWS Activation Procedures ....................................................................................................... B-1 C. ANO SWS Testing and Maintenance Procedures ............................................................................... C-1 D. WPS2800 and WPS2900 Series Operating and Troubleshooting Manuals ....................................... D-1 E. Siren Test Result Report ..................................................................................................................... E-1 LIST OF FIGURES Figure 1. Site Location ................................................................................................................................. 26 Figure 2. Permanent Resident Population by Sector for the ANO EPZ ....................................................... 27 Figure 3. Census Blocks with Population Density Exceeding 2,000 People per Square Mile ..................... 28 Figure 4. Census Blocks with Population Density Exceeding 2,000 People per Square Mile (Filter 1 Applied) ....................................................................................................................................................... 29 Figure 5. Applying Filter ito Eliminate Isolated Neighborhoods from High Population Density Consideration .............................................................................................................................................. 30 Figure 6. Final Census Blocks with Population Density Exceeding 2,000 People per Square Mile after Applying Filters ............................................................................................................................................ 31 Figure 7. Siren Coverage Map for the ANO EPZ .......................................................................................... 32 Figure 8. Siren System Within the ANO EPZ ................................................................................................ 33 Figure 9. Control System Layout for the ANO ANS Siren System ............................................................... 34 Figure 10. Sound Transmission in Temperature Lapse Conditions ............................................................. 35 Figure 11. Sound Transmission in Temperature Inversion Conditions ....................................................... 35 Figure 12. Outdoor Sound Propagation near the Ground .......................................................................... 35 Figure 13. Upwind Sound Propagation ....................................................................................................... 36 Figure 14. Downwind Sound Propagation with Terrain and Vegetation Effects ........................................ 36 Figure 15. Near-Field and Far-Field Test Locations ..................................................................................... 37 LIST OF TABLES Table 1. EPZ Population by Decennial Census ............................................................................................ 19 Table 2. Population Density Computed using Different Geographic Areas ................................................ 20 Table 3. Siren Details for the ANO EPZ ....................................................................................................... 21 Table 4. SWS Activation Points for ANO Site .............................................................................................. 25 Table 5. Siren System Reliabiiity ................................................................................................................. 25 Table 6. Summary of Near-Field Acoustical Test Results ............................................................................ 25 Table A-1. Regulations Crosswalk ............................................................................................................. A-2 Arkansas Nuclear One                                                          ii                                          ANS Design Report- Rev. 4
 
EXECUTIVE
 
==SUMMARY==
 
I The Arkansas Nuclear One (ANO) is located on a peninsula near the Town of Russellville in southwestern Pope County, Arkansas. The Emergency Planning Zone (EPZ) for ANO includes parts of Johnson, Logan, Pope, and Yell Counties. The permanent resident population for the EPZ is 52,871 people as per the 2010 U.S. Census.
The Alert and Notification System (ANS) for the ANO relies on the Siren Warning System (SWS) and the National Oceanic and Atmospheric Administration (NOAA) Tone Alert System as the primary means of alerting the public. Route alerting is used as the backup means to alert the residents around the failed or inoperable siren(s). Public information materials are distributed to the EPZ populace to inform people what to do if they hear sirens sounding or a loud tone from the activated NOAA Tone Alert Radios, and what radio stations to tune into for additional information.
The SWS consists of 50 omni-directional electronic sirens (21 Whelen WPS2807 sirens and 29 Whelen WPS2907 sirens). The location, model type and mounted height of ea_ch siren were input to SoundPLAN acoustic modeling software to estimate the audible level of the sirens throughout the 10-mile EPZ surrounding ANO. The SWS provides 60dBC coverage to 92.6% of the population within the EPZ and 70dBC coverage to the areas with popu1ation density exceeding 2,000 people per square mile. NOAA Tone Alert Radios are provided to residents of the 10-mil~ EPZ who live outside the 60dBC coverage or who have special needs. The radios are also provided to facilities within the 10-mile EPZ with significant population. The ANO tests the ANS routinely and has an extensive maintenance program in place to I
ensure continuous, reliable operation of the ANS. The ANS for ANO has had a reliability performance indicator of 100% for 2019. The reliability of the ANS has not dropped below 99% during the last decade of operatlon. Operators of the ANS are offered training as needed to ensure continued reliable operation ofthe system.
All siren batteries and control boxes are locked and mounted on the siren pole to prevent tampering.
The siren activation equipment is installed at secure locations (the Arkansas Department of Health offices). The ANS system includes a DTMF encoder that requires key-lock activation to make it resistant to cyber-attack.
This ANS design report is an update to the last ANS report (Rev. 3 dated 2/2017) to update the siren coverage map using outputs from the detailed SoundPLAN acoustic model and field testing of siren sound levels, and to address the new guidance on ANS design report formatting and content documented in the December 2019 FEMA REP Program Manual.
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1      Licensing Obligations ntle 10 of the Code of Federal Regulations (CFR) §50.47(b), item (5) and Title 44 of the CFR §350.S(a),
rtem (5) state:
            "Procedures have been established for notification, by the licensee, of State and local Fesponse organizations and for notification of emergency personnel by all organizations; the content of initial and follow-up m*essages to response organiiations and the public has been established; and means to provide early notification and clear instruction to the populace within the plume exposure pathway Emergency Planning Zone [EPZ] have been established."
The December 2019 FEMA Radiological Emergency Preparedness (REP) Program Manual states, "the alerting and notification of the public is a function of the state, local, tribal and territorial governments' emergency plans. An NPP [Nuclear Power Plant] applicant/licensee is required to demonstrate that the administrative and physical means are established for alerting the public and providing instructions, regardless of who implements the ANS [Alert and Notification System] capability. An applicant/licensee may install and maintain the ANS but the responsibility for the alerting and notifying the public, as well as the activation of the ANS, remains with the state, local, tribal and territorial governments."
This ANS design report describes the physical and administrative means established by Entergy to assist the states and counties in alerting and notifying the public in an emergency. Detail of the state and county actions can be found in the state a11d county radiological emergency plans.
As discussed in the December 2019 version of the FEMA REP Program Manual, the initial federal guidance on ANS provided in NUREG-0654/FEMA-REP-1, Rev. 11, Appendix 3 (1980) and FEMA-REP-10 ("Guidance for the Evaluation of Alert and Notification Systems for Nuclear Power Plants") (1985) "predated technology many citizens now take for granted (e.g., smartphones, social media, etc.)." As such, the FEMA REP Program Manual is now the recognized federal ANS guidance document as it "allows evaluators to account for new technologies, consider updated NRC/FEMA guidance, and incorporate REP lessons learned." This ANS design report adheres to the guidance of the latest FEMA REP Program Manual (December 2019), but does rely on data and information from the following additional guidance documents:
* NUREG-0654/FEMA-REP-1, Rev. 11 (1980) including Supplement 4 (2011)
* FEMA CPG 1-17, "Outdoor Warning Systems Guide" (1980)
* FEMA-REP-10 (1985)
      * . FEMA Technical Bulletin (Version 2.0) "Outdoor Warning Systems" (2006)
* NUREG-1022, Revision 3, "Event Report Guidelines 10 CFR 50.72 and 50.73 (2013)
* NEI 13-01, R~vision 0, "Reportable Action Levels for Loss of Emergency Preparedness Capabilities" Part V, Section B of the 2019 FEMA REP Program Manual discuss ANS design objectives. The minimum acceptable design objectives for coverage by an ANS - what the system must be able to do when speed is critical - include:
1 This document IS outdated, being replaced wrth Rev 2 In December 2019 One of the goals of Rev 2 of thls document and of the December 2019 revIs10n of the FEMA REP Program Manual was to not mention specific technologies (1 e, sirens) in reference to ANS Nonetheless, Rev 1 of ttus document does Include valuable guidance on outdoor warning sirens
* Arkansas Nuclear One                                          1                                ANS Design Report- Rev. 4
* The capability to provide both an alert signal and an informational or. instructional message to the population in the EPZ within 15 minutes.
* The initial notification system will ensure direct coverage of essentially 100 percent of the population within 5 miles of the NPP site.
* Notification methods will be established to ensure coverage within 45 minutes of essentially 100 percent of the population in the EPZ who may not have received the initial notification including any special requirement exceptions (e.g., large water areas with transient boats or remote hiking trails).
* The capability of the ANS to cover essentially 100 percent of the population within the EPZ, regardless of failures. The corrective means/measures will be conducted within a reasonable time, with a recommended goal of 45 minutes. The use of a sequential failure model or "primary and backup" ANS model is acceptable. Other models, such as simultaneous or concurrent activation models, could be used.
All of these criteria are met by the ANS system in the Arkansas Nuclear One (ANO) EPZ, as discussed in the sections below.-
2      Requirements 2.1    System Coverage 2.1.1    P-epulation The ANO site is located near the Town of Russellville in southwestern Pope County, Arkansas. The EPZ is located entirely within the State of Arkansas and consists of portions of four counties - Johnson, Logan, Pope, and Yell Counties. Figure 1 shows the location of ANO as well as the approximate 10-mile EPZ.
The permanent resident population in the EPZ is 52,871 people according to the 2010 Census. Table 1 summarizes the permanent resident population and population density in the EPZ, by Zone, for the last two decennial censuses conducted by the U.S. Census Bureau. As the data indicate, population in the EPZ has increased since 2000, with an' increase of +3.8% for the 2-mile radius of the plant, +12.8% for those Zones within the 5-mile radius, and +13.6% for the EPZ as a whole.
A common method for displaying population around a nuclear power plant is by sector. The EPZ is divided up into one-mile increments and the sixteen cardinal and inter-cardinal wind directions, for a total of 160 sectors. The 2010 EPZ permanent resident population, by sector, is shown in Figure 2.
The federal guidance, FEMA-REP-10, "Guide for the Evaluation of Alert and Notification Systems for Nuclear Power.Plants," indicates that sirens are in compliance with federal guidance if they meet either of the following conditions:                                                                "
    *    ''The expected siren sound pressure level generally exceeds 70dBC where the population exceeds 2,000 persons per square mile and 60dBC in other inhabited areas; or
* The expected siren sound pressure level generally exceeds the average measured summer daytime ambient sound pressure levels by 10dB (geographical areas with less than 2,000 persons per square mile)."
FEMA CPG 1-17, "Outdoor Warning Systems Guide" indicates that people typically mentally block out sounds that are not pertinent to what they are doing. In order to break the mental block, a warning sound Arkansas Nuclear One                                  2                            ANS Design Report- Rev. 4
 
must be about 9dBC greater than ambient noise to capture the attention of the listener. This is the basis of the conservative 10dBC above ambient noise guidance. Ambient noise levels were not measured in the ANO EPZ; thus, 60dBC and 70dBC will be used as the criteria for siren sound levels in this report, depending on the population density in a given area.
In order to determine whether 60dBC or 70dBC coverage is needed, population density was computed.
There are many different methods for computing population density:
* Population density by radial distance mile radius, 5-mile radius, or the full approximate 10-mile EPZ
* Population density by county
* Population density by municipality As shown in Table 2, these population densities differ significantly, underscoring the uneven distribution of population in the EPZ. Higher sound pressure levels are required in densely populated areas to overcome the higher ambient noise levels associated with a larger number of people and increased activity. Computing the population density by a large radial distance, or by county can distort population density by incorporating large land areas that are unpopulated or sparsely populated. This could result in the failure to adequately identify areas that need 70dBC coverage. For example, Table 2 indicates that the municipalities in the EPZ have population densities ranging from 211 to 1,303 people per square mile.
However, when considering the population density for each county as a whole, it is considerably lower (ranging from 24 to 76 people per square mile).
The most refined method for computing population density is by census block. The U.S. Census Bureau divides the U.S. into census tracts. These census tracts are in turn divided into block groups, and block groups are comprised of multiple blocks. The census block is the finest level at which the U.S. Census Bureau aggregates detailed population data.
Census blocks vary in size from as small as a single city block to as large as an- entire county. Given the variance in block size, there is the potential to have abnormally high population density for a block with a very small area. Similarly, a small neighborhood can have a population density exceeding 2,000 people per square mile but it _may be the only community for miles. Assuming this neighborhood has 100 people living in an area of about 0.04 square miles (approximately 26 acres - 50 homes on 1/2 acre plots), the population density would exceed 2,000 people per square mile. However, if there are no surrounding neighborhoods, 100 people are not likely to generate enough background noise to warrant 70dBC coverage.
The last physical census in the United States was conducted in 2010 (the 2020 Census is ongoing, but data will not be released until March 31, 2021). Thus, the 2010 Census serves as the basis for all population estimates in this document. Each year in May, the U.S. Census Bureau releases projected populations for each state, county and municipality in the U.S. The latest available census popui'ation estimates, as of July 1, 2019, which were released in May 2020 (when this analysis documented in this report was started),
from the U.S. Census Bureau were used to compute annual growth rates by county and municipality.
These growth rates were then used to extrapolate the 2010 census population in the EPZ to 2020 at the Arkansas Nuclear One                                  3                          ANS Design Report - Rev. 4
 
block level. For more infom,ation, please refer to the 2020 Evacuation lime Estimate {ETE} update2 for ANO.
The following methodology was used to compute population density within the EPZ, by census block.
Population block data was overlaid on the EPZ boundary usirig Geographic Information Systems {GIS}
mapping software. The population density was computed by dividing the 2020 extrapolated population by the area of the block in square miles. Any block with a density exceeding 2,000 peqple per square mile was flagged (block color coded red} as high density as shown in Figure 3.
As discussed above, there is a possibility of isolated neighborhoods or extremely small census blocks being flagged with abnormally high population densities. While mathematically the population densities are correct, these anomalous census blocks do not represent densely populated areas that would have significant background noise warranting_ 70dB siren sound levels. Two steps were taken to remove these anomalous census blocks from the actual high population density areas:
: 1. A filter was applied which eliminates all flagged bloc!<5 that have a population less than 100 people or an area less than 0.02 square miles. This filter eliminates sparsely populated census blocks which are abnorrnally small and result in unrealistically high population densities. Figure 4 displays those blocks which are still flagged after applying this filter.
: 2. Each flagged census block with a population density exceeding 2,000 people per square mile was converted into a circle with an area of 1 square mile, centered at the center of the block. These 1 square mile circles were then overlaid with the census block data once again and the population density of the 1 square mile circle was recalculated. If the density exceeded 2,000 people per square mile, the block which the circle was .centered at remained flagged as having a high population density. If the density of the circle fell below the threshold, the block the circle was centered at was removed from consideration. This filter eliminates isolated high population density neighborhoods that are surrounded by areas of low population density. Figure 5 shows an example of this filter applied to three census blocks in the EPZ. Both blocks shown in Step 1 are flagged as high population density blocks after applying Filter 1. However, when drawing the 1 square mile circles (Step 2.1} centered at the blocks, the population density (Step 2.2) is well below the 2,000 people per square mile threshold. As a result, both blocks are eliminated as high population density blocks (Step 2.3). Figure 6 shows the final blocks flagged as having population density exceeding 2,000 people per square mile in the EPZ after the two filters were applied.
2.1.2    Geographic Area The ANO site is situated on a peninsula fom,ed by Lake Dardanelle, which includes the Arkansas River and the fomier Illinois Bayou. The land within 5 miles of the plant is gently rolling and contains a number of ridge-valley configurations. The Arkansas River and Lake Dardanelle roughly bisect the ANO EPZ.
The meteorological information for each of the EPZ counties is described below.
Johnson County3 is characterized by hot summers and cold winters, with an average high temperature of 90 degrees Fahrenheit (&deg;F) in July and an average low.temperature of 27&deg;F in January. The average rainfall 2
  "Arkansas Nuclear One 2020 Populallon Update Analysis", KLD TR-1167, dated September 19, 2020
'https*//www bestpjaces net/clunate/coUntv/arkansashohnson Arkansas Nuclear One                                        4-                            ANS Design Report - Rev. 4
 
and snowfall in the county is 50 inches and 4 inches, respectively. The number of days with any measurable precipitation is 96. Johnson County is at an average elevation of 1,017 feet.
Logan County4 is also characterized by hot summers and cold winters, with an average high temperature of 92&deg;F in July and an average low temperature of 28&deg;F in January. The average rainfall and snowfall in the county is 49 inches and 2 inches, respectively. The number of days with any measurable precipitation is
                                                                                                              \
: 95. Logan County is at an average elevation of 678 feet.
Pope County5 is also characterized by hot summers and cold winters, with an average high temperature of 91 &deg;Fin July and an average low temperature of 28&deg;F in January. The average rainfall and snowfall in the county is 50 inches and 4 inches, respectively. The number of days with any measurable precipitation is 101. Pope County is at an average elevation of 835 feet.
Yell County6 is also characterized by hot summers and cold winters, with an average high temperature of 93&deg;F in July and an average low temperature of 29&deg;F in January. The average rainfall and snowfall in the county is 51 inches and 3 inches, respectively. The number of days with any measurable precipitation is
: 95. Yell County is at an average elevation of 626 feet.
Figure 1 identifies the municipal areas and major roads in the area, as well as the 15 Zones that comprise the approximate 10-mile EPZ. The Zones are color-coded based on the county they are in.
The National Oceanic and Atmospheric Administration (NOAA) commissioned a study 7 to summarize historical wind data from 1930 to 1996 in the United States. Wind data was aggregated for Fort Smith Regional Airport, which is the closest airport to ANO. The average wind speed at Fort Smith Regional Airport, based on the data gathered, ranges from a low of 6 miles per hour (mph) in July to a high of 8mph in January.
As shown in Figure 1 and listed in Table 2, there are 6 municipalities within the EPZ. Most of the municipalities are located adjacent to the Arkansas River and Lake D_ardanelle. Beyond the population centers is sparsely populated rural farmland or undeveloped land.
The population centers in the ANO EPZ are connected by an extensive highway network. Interstate 40 and US Route 64 travel northwest-southeast through the EPZ. The major state highways servicing the EPZ include Arkansas State Routes 7, 22, 27, 28, 124, 164, 247, 315, 326, 331, 333 and 359. The primary railroads within the EPZ include Dardanelle and Russellville Railroad and Missouri Pacific Railroad .
2.1.3      Means The physical means of alerting and notifying the public within the ANO 10-mile EPZ is the Emergency Warning System (EWS) that consists of a mixture of the Siren Warning System (SWS) and the NOAA Tone Alert System. The ANS is essentially designed to notify the individuals in the 10-mile EPZ within 15 minutes of the issuance of recommendations by the State of Arkansas for radiological emergencies at ANO. Local fire departments in the EPZ and route alerting are used as the backup method to alert the public to receive instructions, information, and necessary actions to be taken.
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2.1.4    Primary Methods The primary ANS for ANO is the EWS as discussed above. The SWS is used to alert the more densely populated areas shown in Figure 7. Based on the population estimates discussed in Section 2.1.1, the SWS covers 92.6% of the population within the EPZ at 60dBC or higher. Those residents of the 10-mile EPZ who live outside the siren coverage area or who have special needs are alerted by NOAA Tone Alert Radios (TAR). NOAA TARs are also provided to the facilities within the 10-mile EPZ with significant population.
These individuals and facilities are further discussed in Section 2.2.
The SWS relies on 50 Whelen omni-directional electronic sirens (21 WPS2807 sirens and 29 WPS2907 sirens). Of the 50 sirens, there are 2 sirens in Johnson County, 3 sirens in Logan County, 33 sirens in Pope County and 12 sirens in Yell County. All sirens ;:ire mounted at pole top, approximately 50 feet above the ground. The location, h~ight and ID for each siren are presented in Table 3.
All of the sirens are radio-controlled and a DTMF (Dual Tone Multiple Frequency) encoder is required for activation. Sirens include a National Nuclear Attack signal that insists of an up-and-down scale tone. This three-minute continuous tone signal will be used to alert the populace to tune into NOAA TARs and local radio stations for emergency information (primary notification). Sirens also include a warning signal. This signal is used to alert the populace of not only a radiological incident, but also of natural disasters, especially tornado warnings.
The Arkansas Department of Health (ADH) maintains a database of addresses that are outside of the 60dBC siren coverage area. Each year a letter is sent to those addresses to verify if they have a NOAA TAR and if it is functioning. If they do not have a TAR or if the TAR is not functioning, they can request that ADH provide a TAR. The ADH also mails batteries to the TAR holders annually.
The NOAA Tone Alert System is operated in cooperation with the National Weather Service (NWS). When activated, a loud tone is emitted from the radio to alert the user. Following activation of the receivers, live or pre-recorded emergency messages are broadcast to instruct/notify the public. Section 3.1 below provides additional details of the EWS.
2.1.5    Backup Methods Supplemental notification to the EPZ population is provided by local fire departments in the EPZ. In the event of siren or NOAA Tone Alert System failures, route alerting is implemented in the affected fire district(s) using truck sirens and Public Address (PA) systems for notification of r~sidents around the failed or inoperable siren(s). The truck sirens serve as the backup alert method, while the announcements being made over the PA system serve as the backup notification method.
2.2    Population/Demographics In addition to the pennanent resident population detailed in Section 2.1.1, there are transients who may be visiting the EPZ for recreational purposes. Those people who live and recreate in the EPZ have already been considered as permanent residents to avoid double counting population.
According to the latest ETE study done for ANO (KLD TR-517, "Arkansas Nuclear One - Development of Evacuation Time Estimates," Rev. 1, dated December 2012), there could be as many as 11,745 transients in the EPZ at peak times. The transient estimate is based on data provided by county emergency management agencies.
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There are 69 special facilities identified In the EPZ. These facilities include schools, universities, parks, campgrounds, golf courses, marinas, recreational areas, lodging facilities, major employers, medical facilities, and correctional facilities. The EWS is capable of alerting and notifying each of these special facilities. Nonetheless, the State has plans in place to notify each of these facilities individually as discussed below.
As per the Arkansas Comprehensive Emergency Management Plan (ARCEMP), Rev. 39, dated September 30, 2019, the State Department of Parks and Tourism will provide notification of the public within the park system; the State Game and Fish Commission and State Forestry Division will provide backup communications and personnel for notification purposes in remote forest areas, and on rivers and lakes; the ADH repeater system will alert the emergency response agencies and schools within the 10-mile EPZ through the Early Notification System (ENS) component of the EWS; and information contained in the Emergency Instruction Booklet8 (EIB) is posted and/or placed in public locations within the 10-mile EPZ such-as public buildings, state and national parks, recreational areas, tourist information centers and rest areas located on major highways, which are routinely visited by transient populations. Postings will be checked periodically and updated as needed. In addition, letters of agreement formalizing the emergency notification interfaces between Entergy and Arkansas Tech University in *Russellville are kept on file in Entergy's offices.
None of the areas discussed above are considered exception areas. They can all be alerted and notified in a timely fashion.
Special provisions have been developed by ADH Nuclear Planning & Response Program (NP&RP) and Entergy for the alerting of identified handicapped individuals. A postage-prepaid, detachable postcard is
. provided in the annual mailing of the EIB for use by persons who may have special needs. This form is to be completed and then mailed to the ADH NP&RP office, and the information is subsequently provided to the appropriate local government. The individuals with special needs, depending upon their handicap, are notified appropriately. The notification may include door-to-door notification by law enforcement officers, neighbors, telephones, or tone activated NOAA TARs. Persons who are hearing impaired, or who require special notification are- provided NOAA TARs free of charge. These receivers are also made available to the large businesses, hospitals, nursing homes, schools, day reception centers, and other applicable groups within the 10-mile EPZ.
According to American Community Survey 2014 - 2018 data 9, the percent of non-English speakers within the EPZ is approximately 0.56%. Given the small size of non-English speaking population, English is the only language used for notification.
2.3      Interoperability The SWS is divided into 5 siren activation zones of relatively higher population density covering parts of the 10-mile EPZ, specifically: Yell County (lZ as Zone 1), the Russellville/Dover area and the Village of London in Pope County (2Z and 3Z), Johnson County (4Z), and Logan County (SZ). Each of these zones can be activated Independently or in conjunction with other zones. All zones would be activated in the event of emergency at the ANO site.
8 httpsJ/www healthy arkansas gov/imaqes/uok>ads/pdf/AR Nuc0ne20 ENGweb.pdf e AddrtJonal details about language spoken at home can be found at the following website https /lfactfinder census.aov/facestafthelphsf/oageslmetadata xhtml'-'1anQ:'en&typectable&d--table en ACS 17 5YR s 16004 Arkansas Nuclear One                                            7                                  ANS Design Report - Rev. 4
 
The ADH has the sole ability to activate the SWS. There are three activation points - one primary and two backup points, as discussed in Section 3.1.3 and Section 3.3.1. The locations of the activation points are outlin~d in Table 4. All the activation points have backup power and two independent paths for activat,ion signals to reach the sites. The SWS is activated by .radio signal. in the UHF (Ultra High Frequency) band which is transmitted by the primary/backup siren radio transmitter. The architecture of the SWS activation is discussed in detail in Section 3.1.3. The SWS activation is also made available to local governments for use in severe weather and other emergencies. Authorized officials may request siren.activation for various zones in their jurisdictions.
The sirens are battery operated and are powered by four high -capacity batteries. Battery charge is maintained by AC power through "smart" chargers to avoid overcharging. Sirens, depending on use, can keep operating up to 10 days without AC power. The ADH has mobile generator units that can be used in the event an AC power outage exceeds that length of time.
The NOAA TARs are activated by the NWS through a 300-watt transmitter with a 300-watt backup transmitter. The NWS is contacted by the ADH staff and informed of the intent to activate the EWS. The NWS is notified in advance of the sirens being activated such that, in conjunction-with the siren activation, the NWS activates the NOAA tone which automatically turns the receivers on.
2.4    Operations                                            ,
ANO maintains the capabilities to assess, classify, and declare an emergency conditi~n within 15 minutes of the availability of indications to plant operators that an emergency action level has been exceeded.
Emergency persqnnel are trained to promptly declare the emergency condition as soon as possible following identification of the appropriate emergency classification level. There are four emergency classification levels - Notification of Unusual Event, Alert, Site Area Emergency and General Emergency.
The EWS within the 10-mile EPZ might be activated by ADH for a Site Area Emergency and will be activated for a General Emergency.
The final decisions to alert and notify the public by the EWS are the decisions of governmental officials.
Initial notifi~ation is made to the state. and local authorities within 15 minutes after declaring an emergency. An Emergency Action Authenticator is used to verify messages that are received over a non-
          ,      '                '                      J secure system, such_ as commercial telephone system. The NRC is notified immediately following notification of s_tate and local authorities and within 1 hour of the declared emergency.
The EWS can be fully activated from the ADH Emergency Communication Center (ECC), the alternate State Emergency Operations Facility (SEOF) or the ADH NP&RP office. Anytime the SWS is to be activated to notify the public, ADH NP&RP will take over operation of radio station-KXRJ, 91.9 FM at Arkansas Tech University.*ADH NP&RP has the capability to remotely take over broadcast of this station and provide the public with any emergency communications or protective actions that might become necessary. The detailed ~ctivation process is included in Appendix B.
2:5    Management/Administration It is the responsibility of ADH to manage and oversee the EWS network. The NOAA radio program is administrated by ADH NP.&RP and operated by NWS. The NWS is responsible for managing the weather radio transmitters nationwide.
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2.6    Security and Privacy 2.6.1    Physical Security All siren batteries and control boxes are pad locked and mounted on the siren pole to prevent tampering, and both AC and battery voltage can be monitored remotely. The siren activation equipment is installed at secure locations that are manned 24 hours per day. Entry into all activation points is limited to authorized personnel only. Additionally, all activation consoles are equipped with a physical keyed lock to prevent access to the activation keys.
2.6.2 Logical Security To prevent cyber-attack, the actual activation of the EWS is accomplished by use of a DTMF encoder requiring key-lock activation. Details of either activation procedure are limited to a "Need-to-Know" basis for security reasons.
2.7    Maintenance/Repair 2.7.1    Preventative Maintenance It is the responsibility of ADH NP&RP to perform the Preventive Maintenance (PM) on the SWS. On a quarterly basis, the PM is performed following the instructions listed in the ANO SWS Maintenance Plan (see Appendix C). During the scheduled PM, each siren may experience brief periods when it is not able to sound, but it is not taken out of service for more than a few minutes and could be returned to service immediately, if needed. As noted in the*maintenance plan, a wide variety of inspections are performed at each siren site including verification that there is no vegetation growth that can obstruct sound propagation near the siren head; visual inspection of the p'ole, the antenna, the siren head, the cabinet and associated connections; verifying acceptable condition of the batteries and chargers; and running a silent test. In addition, the ADH performs the maintenance with contractor assisted items, such as crane rental for upper driver maintenance.
The ADH NP&RP also checks the operation of the control points and transceivers associated with the activation system on a routine basis. The operability of key components, for instance, is verified every weekday. Additionally, a contractor is used to measure the transceiver perimeters.
The ADH NP&RP mails information annually to every address within the lQ-mile EPZ to provide the contact information for the request of the NOAA TARs. On a monthly basis, the ADH mails letters to the new residents within the 10-mile EPZ to notify them of the same information. Recipients of the NOAA TARs are tracked in a master database by the NP&RP staff as discussed in Section 2.1.4. Needed repair and/or replacement of the receivers identified as defective is also carried out by the NP&RP staff. Alrthe holders of the NOAA TARs receive new batteries and instructions from the ADH annually.
2.7.2 Corrective Maintenance Upon notification of a siren malfunction, the ADH determines if the failure(s) is reportable in accordance with 10CFR 50.72, and the noted siren malfunction is immediately serviced by an ADH NP&RP Electronics Technician and every attempt is made to return the unit to operation. If the siren is unavailable, the appropriate county is notified that the backup alert method - route alerting - will be required in the affected area until the unit is returned to service.
A siren that did not fully respond to the activation command signal during a valid test is considered as an activation failure and would not have provided adequate public alert. It would be reported as a siren Arkansas Nuclear One                                  9                            ANS Design Report- Rev. 4
 
failure to FEMA and to ANO Emergency Planning (EP) personnel. A siren is considered out of service when it cannot receive, process, or sound the appropriate audible warning tone through the driver section.
When determination has been made that a SWS component is not responding appropriately to polling, such as low battery, AC voltage or related issues; or reports or concerns from the public indicating siren abnormal behavior, an on-site inspection and repair will be performed by an ADH NP&RP Electronics Technician. The Electronics Technician will follow the guidelines recommended in the manufacturer's operating and troubleshooting manuals (see Appendix D) to restore component functionality. The Electronics Technicians also meet routinely with the ADH Section Chief to identify any maintenance and/or perform.ance trends. Trends are noted and corrective actions are implemented, if needed.
In addition, the ADH tests the siren control transmitters and consoles every weekday morning, when the state offices are open. If a problem is identified, the corresponding corrective action is immediately undertaken. The use of redundant transmitters and activation points minimizes the risk of a failure of the activation system.
* 2.8    Availability/Reliability Appendix 4 of FEMA REP-10 specifies that the operability of a siren system is considered acceptable "when an average of 90% of the sirens (as determined by a simple average of all regularly conducted tests) can be demonstrated functional over the 12-month period immediately preceding the submittal of the design report."
The Nuclear Energy Institute (NEI) Regulatory Assessment Performance Indicator Guideline, NEI 99-02 Revision 7, specifies a minimum performance indicator threshold of 94% for ANS Reliability during the previous four quarters for plants operating in the normal regulatory response band.
The ANO SWS reliability data is reported to FEMA for review on a quarterly basis. According to the ADH, the ANO siren system has been operational since 1981. A review was completed over the past 10 years and it was determined that the successful siren performance has not dropped below 99% during that time. Table 5 shows the results of siren tests at ANO for the last 4 quarters. As shown, the siren performance in each quarter of 2019 was 100%.
2.9    Testing The EWS is tested by ADH and NWS periodically to ensure its readiness. The testing includes functionality of sirens and of NOAA TARs.
The entire SWS is sounded weekly to reinforce public awareness of the system. This is not a silent or growl test, but either a 15-second or 1-minute audible test each Wednesday at 12:00 pm. Testing will not be performed if severe weather is present in the area or the state offices are closed. Under a verbal agreement with FEMA, the 1-minute audible test is perfonned on the 4 th Wednesday ofthe month. The operation of each siren is verified once per month and the results are reported to FEMA. Due to the fact that the weekly audible test far exceeds the annual federal operability requirement, other types of audible tests are not conducted at the ANO.
In addition to the weekly audible test, sirens are polled for health maintenance at least once per month.
The health of siren batteries is assessed by the ADH NP&RP Electronics Technician on a quarterly basis (see Section 2.7.1). Batteries are replaced at a frequency that exceeds the battery manufacturer's recommendations. The siren activation equipment is tested frequently (see Section 2.7.2). Special Arkansas Nuclear One                                10                          ANS Design Report - Rev. 4
 
observations may be conducted in the event of severe weather or high winds which might result in physical damage, such as identifying loose feed lines or pole damage. If any issues are identified during these observations, repairs will be undertaken using the ANO SWS Maintenance Plan in Appendix C.
The NOAA TAR activation is tested by the NWS and monitored by ADH NP&RP. The testing is performed each Wednesday between 11:00 am and 12:00 pm. If inclement weather persists, the testing will be performed the next clear day.
The current testing conducted by ADH exceeds the annual maintenance recpmmended by the NRC. This includes actions specifically designed for the ANO EWS. The testing records are kept in the ADH NP&RP office.
2.10 Responsibility It is the responsibility of ADH NP&RP to perform or supervise maintenance on the entire EWS network (except for the NOAA radio system and local broadcast stations and radios) and to ensure that it is functioning properly. In general, the electronic component control and radio parts are maintained and repaired by ADH. The items requiring the use of a crane or other specialized equipment are maintained and repaired by contractors. The NOAA radio system is tested by the NWS and monitored by ADH NP&RP and by ANO EP personnel (see Section 2.9 and Section 4.3). A local contractor is responsible for maintenance and repair ofthe NOAA weather radio transmitters.
2.11 Training It is the responsibilities of ADH NP&RP to identify organizations with a need for training and provide training and refresher training on a continuing basis. Refresher training shall be made available to emergency personnel at least annually. At a minimum, these emergency workers will have attended the FEMA REP Planning course. The training required for emergency personnel is discussed in Section 7.
2.12 Quality Assurance The ADH maintains several procedures pertaining to the ANS, including procedures on activation, testing, maintenance, repair and reportability. These procedures are included in Appendices Band C. The records regarding the SWS testing and maintenance are ,maintained by ADH and routinely reviewed by ANO.
Copies of the quarterly reports detailing siren system performance are also provided to ANO. Additionally, the ANO is provided the results of activation verification on a monthly basis.
In addition to these procedures above, the EWS is tested on a weekly basis as discussed in Section 2.9.
Hence, the essential elements of the SWS activation are "practiced" weekly. These extensive exercises help to reduce errors during the operation.
The NOAA weather radio test data is not reported as the weekly test is not guaranteed due to the weather conditions. The records of the NOAA radio system performance are not maintained as it is outside ADH's area of responsibility. However, the ADH notifies the NWS of service interruptions monitored (see Section 4.3) and provides assistance in resolving problems. As noted in Section 2.10, a local contractor is responsible for the maintenance and repair of the NOAA weather radio transmitters.
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3    Description/Performance 3.1    Physical requirements 3.1.1    System Components As discussed in Section 2.1.4, the siren system is comprised of 50 omni-directional electronic sirens. Figure 8 maps the sirens in the EPZ. The sirens are labeled with their identification number and are symbolized by siren model type. Table 3 lists each of the 50 sirens in the ANO EPZ. The table includes the siren identification number, the latitude and longitude ofthe siren, the siren model, the mounted height of the siren and location description.
WPS2807 and WPS2907 sirens can produce approximately 115.ldBC and 115.5dBC, r~spectively, at 100 feet along their centerline with operating frequencies between 500 and 630 Hz, based on the results of the near-field tests discussed in Section 4.1.
A WPS2807 or WPS2907 siren consists of a power supply {batteries), a control board, seven 400-watt audio drivers, seven audio amplifiers, and a radio transceiver for reception of control signals. The batteries, control board, amplifiers and transceiver <!re located in a sealed and locked enclosure. The siren drivers are pole mounted at approximately 50 feet above the ground. All sirens have multiple ground points and surge protection, incl~ding antenna feed lines.
Over the past 30 years, the ADH has issued numerous NOAA TARs of various models and manufacturers.
Nevertheless, all the radio receivers must respond to the 1050 Hz alert tone and feature an audible warning. The ADH also provides models with a visual signal to alert deaf or hearing-impaired individuals.
The NOAA TAR have a battery backup feature which allows the user to install batteries, such that the radio will work during a power outage. New batteries are issued annually to each of the NOAA TAR holders as discussed in Section 2.1.4 and Section 2.7.1.
3.1.2    User Interfaces The WPS2800 and WPS2900 series sirens*can be remotely activated by using an encoder and siren radio transmitter. The logical connection between the siren control components is further discussed in Section 3.1.3. The NOAA TARs are activated by a primary 300-watt transmitter. A secondary 300-watt backup transmitter would be used following a failure of the primary transmitter. Both primary and secondary backup transmitter sites are located on Mount Nebo, which is approximately 6 miles SSW of the ANO site.
Entergy has provided backup generator capability for the transmitter site. Hot standby switching for auto-start of the backup transmitter and a backup generator with auto-start capability is also available and tested frequently.
3.1.3    Functional Block Diagrams Figure 9 shows the logical connection of the components of the siren control system. As shown in the diagram, there are three different locations that can communicate with the primary and backup siren radio transmitters which in turn communicate with the siren sites via a utility microwave link or a leased line which is a circuit rented from a public carrier-AT&T in this case. The ADH Mobile Command Post can communicate with the primary and backup radio transmitters via radio line. The primary/backup siren radio transmitters activate sirens by UHF-FM radio signal. Section 2.3 further discusses the physical connections of the system and the interoperability.
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3.2    Administrative Components 3.2.1    Organizational Responsibilities The ADH ECC is the official 24-hours-per-day point of contact between the State and ANO for the initial notification of a radiological incident. In the event of an emergency, the operator of ANO is responsible for notifying the ADH ECC, Arkansas Department of Emergency Management (ADEM), and the warning points in Conway, Johnson, Logan, Pope and Yell Counties. The final decisions to alert and notify the public by the EWS are the decisions of governmental officials.
The responsibilities of ADH NP&RP include off-site emergency planning and response to emergencies involving ANO; the development and update of emergency response plans; the maintenance and operation of the EWS and the communication system used to notify state agencies and local governments of emergencies; the maintenance of eguipment and supplies necessary to support emergency operations for state and local agencies; the development and training of emergency personnel who would respond to an emergency; and the distribution of emergency instructions to the public.
The primary means of notification and communication between ANO and the state and local governments will be via the ANO Dedicated Emergency Facsimile/Voice System (DEF/VS). In the event that the ANO DEF/VS is not operating properly, the operator of ANO will notify the ADH ECC directly by commercial telefax or by commercial telephone; and ADH, in tum, will notify the county warning points and ADEM using various means, such as the DEF/VS, ENS radio, ADEM radio, and/or commercial telephone. If both communication procedures outlined above fail, the operator of ANO will use commercial telephone to notify the ADEM which will, in turn, notify the ADH ECC. The communications link between the state and federal emergency response organizations is via the commercial telephone system, with the National Warning System (NAWAS) serving as the backup system.
3.2.2 Management As noted in Section 2.6, the activation consoles are key locked and kept at secure locations to prevent the inadvertent systemwide activation, and the siren control system is configured in such a way that a systemwide inadvertent activation is very unlikely to occur. There are limited failure paths which will result in an inadvertent activation, such as included high voltage that shorts a control cable. In the event of an inadvertent siren activation, the ADH sends the notification to _area broadcast stations and to appropriate 911 Centers to assure the public there is no emergency involving ANO. In an emergency involving ANO, this responsibility falls on which of the State's centers have "Command and Control". For other situations, it depends on the time of day. After hours notification falls to the ADH ECC if the radiological emergency response team is not activated.
If siren(s) are inadvertently sounded, the cancellation tones are not automatically sent to the siren(s) due to the time factor. In most cases, reports of spurious siren sounding come in the form of calls from the public to the appropriate 911 Center which then notifies the ADH. It is noted that the sirens in Arkansas are hard coded to sound for 3 minutes before shutting off. As such, the siren has most likely "timed out" when the incident is reported. When the ADH receives a report of inadvertent siren sounding, the first step is to gather the information of the inadvertent sounding reported, including the number of calls receive*d, the generation location of the sound reported, the caller names and call back numbers. The ADH then will verify the existence of a siren in the reported activation area. If a siren is identified in the reported area, a repair technician will visit the site to ascertain the status of the siren, and attempt to determine if Arkansas Nuclear One                                    13                              ANS Design Report- Rev. 4
 
there was an actual activation or if there were other noise sources that imitate a siren. Most reported siren sounds are in fact from other sources, for instance, emergency vehicle sirens.
3.3    Operational Components 3.3.1    Activation As discussed previously in Section 2.3, the SWS is activated by ADH through the primary or secondary activation points. As shown in Table 4, the primary activation point for the SWS is located at the ADH ECC office that is manned 24 hours per day to accommodate day or night activation. One secondary activation point for the SWS is located in the SEOF which is co-located at the ANO site; another secondary activation point is located in the ADH NP&RP office. All the activation points have the ability to activate the entire SWS, but for events where ANO is not involved, such as severe weather, activation is usually conducted by ADH ECC or by ADH NP&RP.
The NWS is notified by the ADH staff in advance ofthe sirens being activated. The NWS in turn utilizes the primary/backup weather radio transmitter to transmit the NOAA tone which automatically turns the receivers on. Both primary and secondary backup transmitter sites are located on Mount Nebo, which is approximately 6 miles SSW of the ANO site.
3.3.2    Timing According to ADH, when an emergency is declared at ANO, the ANO operator must notify state officials within 15 minutes. State officials can then notify the public of an emergency within 15 minutes by use of the EWS. The EWS activation will be conducted with a sense of urgency without undue delay. The sirens activate within seconds of the signal being sent from the controller. The NOAA tone is activated in conjunction with the siren activation. The backup method - route alerting - is capable of alerting and notifying the 10-mile, EPZ population within 45 minutes (see Section 4.3 and Section 5).
There are no exception areas (rural, low popul!'ltion areas) in the EPZ that would require additional time to be alerted and notified.
3.3.3    Geo-Targeting Individual sirens within the siren system can be activated to pinpoint a geographic location for alerts; however, this is not part of the standard alert procedure. NOAA radios cannot be individually sounded.
4 Verification 4.1    Coverage ANO recently conducted an extensive acoustical study of the.siren system, including detailed acoustical modeling and field testing of siren sound levels. The results of this study are summarized below.
Section 2.0 of FEMA Technical Bulletin (Version 2.0) "Outdoor Warning Systems" dated January 12, 2006 provides an extensive discussion of sound propagation. Below are some key points on sound taken from this guidance document:
* Sound travels in waves
* Sound decreases in loudness at greater distances from its source
* Refraction: Sound waves can refract or bend with differences in temperature and wind speed. The specific heat of the gro1,1nd is higher than that of the air above it. Thus, during the day, the ground Arkansas Nuclear One                                    14                            ANS Design Report - Rev. 4
 
is warm and temperature decreases as you move higher above the ground. This difference in temperature impacts the speed of sound waves as shown in Figure 10. The resulting shadow zone causes the audible level of the siren to be lower at the ground. The opposite happens in the evening when the ground releases its heat to the atmosphere resulting in higher temperatures the farther you get from the ground, as shown in Figure 11. This explains why sounds from the same source are louder at night than they are in the daytime.
* Ground Absorption: Soft ground such as grass covered soil or dense foliage can cause significant absorption of sound, thereby reducing perceived loudness of sound. Hard surfaces such as concrete, ice, or water can cause sound waves to reflect upwards and be perceived as louder as shown in Figure 12.
* Wind: Wind speed either adds or subtracts to the velocity of sound waves depending on whether the sound is moving upwind or downwind, resulting in refraction of sound waves. Wind speed also increases with height above the ground causing further refraction. The additive refraction of these two phenomena can result in a significant acoustical shadow zone in the upwind direction as shown in Figure 13.
* Diffraction: Sound waves can also be diffracted (bent upward or downward) by objects (buildings, trees) in the path between the source and the listener resulting in lower perceived loudness.
Figure 14 shows multiple potential factors that could Impact the sound heard by a receiver from a source.
One way to deal with the complications that can impact the audible level of outdoor sirens is to use a sophisticated acoustic model that accounts for terrain and atmospheric conditions. Such a model, Sound PLAN, was used to predict the siren coverage in the ANO EPZ. The SoundPLAN software is a state-of-the-art acoustic model written by SoundPLAN, LLC (a German company) and distributed in the U.S. by Navcon Engineering Network in California. This software has been used to model the siren coverage for more than a dozen U.S. nuclear plants, including the Diablo Canyon Power Plant in California, which has one of the most difficult terrains of any U.S. plant in terms of siren coverage.
Modeling Inputs and Assumptions The following inputs/assumptions were used in the acoustic modeling:
* Digital elevation data was provided by the United States Geological Survey (USGS) National Map Viewer10
* A standard DEM 11 was downloaded with a resolution of 1/3 arc-second, which is an approximate grid spacing of 10 meters. This is more than adequate to model the terrain in the EPZ.
* Major bodies of water including the Arkansas River, Illinois Bayou and Lake Dardanelle were explicitly modeled in the analysis using GIS mapping software.
* Ground surface absorption was explicitly modeled. The software default value for ground surface absorption is 1 for all soft grounds such as fields or other grassy areas, and forests. The ground surface value was changed to O for major bodies of water to accurately depict the reflective properties of the hard surface.
* The siren locations and model type documented in Table 3 were Input to the model.
10 http /tV!e'Wer nattooaknap.aov/bastc/
11 http //nat1onalmap goy/3DEP/3deo prodserv.html Arkansas Nuclear One                                      15                          ANS Design Report-, Rev. 4
* Acoustical tests were conducted on June 23 and June 24, 2020 to measure the sound levels output by sirens. The tests included seven near-fieid tests in accordance with ANSI S12.14, wherein a sound meter was aimed at the center of the siren horns from a buckettruck parallel with the siren horns at a distance of 100 feet. In addition to the near-field tests, far-field tests were conducted with siren meters on the ground at varying distances form the siren pole. Five WPS2907 sirens and two WPS2807 sirens were tested. Figure 15 presents the locations of the near-field and far-field test locations. The tests were conducted by acoustical expert - Dr. Bruce lkelheimer - using Larson Davis Model 831 sound level meters - and were supervised by the ADH and Entergy personnel. Weather conditions during the tests were good, with low winds and no precipitation.
The test results were analyzed and reported by Dr. Bruce lkelheimer (see Appendix E). The results of the near-field tests are summarized in Table 6. Based on the overall average results, sound levels of 115.ldBC and 115.SdBC are adopted for WPS2807 and WPS2907 siren models, respectively. The ANSI S12.14 test sheets for the seven near-field tests which provide additional details on the test are included in Appendix E.
* The acoustical standard International Organization for Standardization (ISO) 9613-2 12 was used.
ISO-9613-2 is a widely used standard for sound modeling and is accurate at predicting total coverage areas at extended distances from the source.
* The average daytime temperature, pressure and humidity were u~ed to account for atmospheric conditions. These data were estimated as the 3-month average of June, July'and August of 2019.
The historical weather data was obtained from the Weather Underground website 13
* The location used was Hot Springs, which is located approximately 55 miles southeast of ANO. The atmospheric conditions used were:
o Average temperature= 79.8&deg;F (265&deg;C) o  Average relative humidity= 77.2%
o  Average air pressure= 29.4 inHg (995.2mbar)
As discussed in Section 3.1.2, the NOAA TARs are activated by the primary/secondary weather radio transmitter located in Mount Nebo. As-per the latest county radiological emergency response plans, the NOAA weather radio primary/backup transmitter at Mount Nebo covers the following counties          .
                                                                                                        - Conway, Johnson, Perry, Pope and Yell. This has provided adequate coverage to the radio receivers within the 10-mile EPZ.
4.2        Population/Demographics Based on the population density analysis using the 2020 population projections (see Section 2.1.1), the overall population density in the ANO EPZ is low. Only parts of Russellville have a population density exceeding 2,000 persons per square mile, as shown in -Figure 6. As discussed in Section 2.1.1, federal guidance recommends siren coverage of at" least 70dBC in areas where the population density exceeds 2,000 people per square mile, and 60dBC in all other areas. Also, as discussed in Section 1, the ANS should provide direct coverage of essentially 100 percent ofthe population within 5 miles of the NPP site.
Figure 7 maps the predicted siren coverage for the ANO EPZ output by the Sound PLAN software based on the inputs and assumptions discussed above. The map shows the 60dB and 70dB contours, as well as the high population density areas discussed In Section 2.1.1.
12 https /fw.Nw lSO org/standard/20649,html 13 https*l!y.,ww.wunderground com/
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As shown in the map, the G0dBC coverage covers the majority of the 10-mile EPZ. All the high population density areas flagged red in Figure 7 have adequate 70dB coverage. As discussed in Section 2.1.4, the ADH maintains a database of addresses that are outside the G0dBC siren coverage area. Letters are sent to those addresses annually to ensure NOAA TARs are available to those addresses to ensure completed coverage of the EPZ by the EWS.
4.3    Metrics Sound levels during siren activation were measured in many locations as discussed in Section 4.1 and shown in Figure 15. These sound level measurements were used to calibrate the acoustical model and predict G0dBC and 70dBC of the siren system in the EPZ.
As discussed in Section 4.1, the NOAA TAR receivers within the 10-mile EPZ are fully covered by the NOAA weather radio primary/backup transmitter at Mount Nebo. According to the ADH, the NOAA radio signal strength has not been reported as an issue by any NOAA TAR holders. As discussed in Section 2.5, the NOAA radio program is operated by the NWS and administrated by the ADH NP&RP staff. The ADH retains several radio receivers in the ADH NP&RP office for constant monitoring. The NOAA radio system is also monitored by ANO EP personnel.
As per federal guidance, the primary ANS means should be capable of alerting and notifying the EPZ population within 15 minutes, and the backup means should be capable of alerting and notifying the EPZ population within 45 minutes. According to the ADH, the time for the EWS (primary method) activation and route alerting (backup method) process has been evalua~ed by FEMA several times during the bi-annual evaluated exercises, and the timeline has been acceptable. The time for actual physical activation of the ENS by pushing the button is a matter of seconds.
5    Availability/Reliability As discussed in Section 2.12, the ADH maintains several procedures to provide detailed information of performing testing, maintenance, and record keeping for system maintenance/repair activities. The system testing, maintenance and siren malfunctions have been discussed in detail in Section 2.7 and in Section 2.9. Appendices B and C details the Quality Assurance procedures that are in place which have resulted in a 100% reliability score for the ANS in *2019 and reliability scores in excess of 99% for the past decade (see Section 2.8). The inadvertent activation of the SWS and the actions taken thereafter are discussed in Section 3.2.2.
As discussed in Section 4.3, the ability to meet the minimum activation time of 15 minutes has been successfully*demonstrated in the bi-annual evaluated exercises, including the latest one on July 17, 2018.
The evaluation details are reported in the After-Action Report/Improvement Plan published by FEMA.
6    Security and Privacy The applications used to activate the SWS can only be accessed by authorized personnel with unique user IDs and passwords. Section 2.6 provides additional detail on the physical and cyber security ofthe ANS.
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7 Training and Public Outreach The ADH NP&RP is responsible for arranging the initial and continuing training for all staff members who are assigned to the ANO radiological emergency planning effort. The elements of training required for emergency personnel include the review of emergency classification levels, protective action advisories, methods of notification, ,notification procedures, procedures for dissemination of public information during a nuclear generating plant emergency, emergency notification forms, emergency staff positions and responsibilities, facility set-up, layout and equipment.
The public is instructed by the EIB to tune to NOAA TARs and local radio stations for emergency instructions when the sirens are activated. The local radio stations have the capability to broadcast emergency messages on a 24-hour basis to the general public. The EIB is available in both English and Spanish and can be accessed through the ADH website 14
* The booklet also includes contact information for emergency planning agencies should additional information on alert and notification or other emergency planning issues be needed.
In addition to the EIB, emergency information regarding notification procedures and those steps that should be taken in an emergency is included in the official telephone directory distributed within the 10-mile EPZ and is updated annually. Education and informational programs are offered annually to area civic and service organizations, including public and private schools. These programs include information on the EWS, evacuation routes, and designated care            \
centers. An annual media workshop is conducted by ADH NP&RP to provide pre-incident information to the representatives of the Arkansas news media. The workshop provides information on notification, evacuation and planning efforts. The ADH NP&RP will also provide the news media with periodic releases containing information on any changes in notification, evacuation or planning efforts.
14 httos 11www healthy.arkansas.goy/programs-serv1ces1tomcs/nuclear-olan1na-and--resoonse Arkansas Nuclear One                                          18                          ANS Design Report- Rev. 4
 
Table 1. EPZ Population by Decenntal Census 2000 Population 2010 Population 2000                2010 Zone                                          Density (people Density (people Population        Population per sq. mi)    per sq. mi)
G            1,278              1,327                  58          60 Total for Zones intersecting 2-    1,278                1,327                  58          60 mile Radius:
H          12,861            *'14,653          '*'  899        1,024*
K            1,798              2,185                  80          97 N            4'92                579                  53          62 -
0            146                141                  72          70 R            502                431                  27          24 u            1,277              1,387                  80          87 Total for Zones intersecting *5. 18I 354. -~        20)03          '1
                                                                      , 176        198
        * , mile Radius:
I          10,618              12,262                541        625 J            4,426              5,445,                232          285 L          4,074              4,484                175        192 M            763                936                  '21          25 p            1,931              2,022                  80          84 Q            398                464                , 12          14 s            1,739              2,133                  47          58 T          4,228              4,422                1,*371      1,434 EPZTOTAL:      46,531              52,871                  155        176 Arkansas Nuclear One                                    19                      ANS Design ReJ;>ort - Rev. 4
 
Table 2. Popu/atlan Density Computed USJfl/J Different Geograph,c Areas Population 2010 Geographic Area                        Arca {sq. mi)      Density (people Population per sq. mi)
                              ~
Radial Distance 2-n:iile-      ;  1,003          12.S-7      --            80 5-mlle              11,553          78.54                      147 10-mlle            5;1.,869        314.16                      168 Full EPZ            52,871          300.97                      176
                            ;                        ; County            ;            ,,
Johnso*n              25,540 _      659.80                      39 Logan              22,361        708.13                      32 Pope              61,754        812.55                      76        ' -
Yell              22,185        929.98                      24
                                                                            -~            '*.  -*
                                        ..          Munici'pality*                          - '
Dardanelle              4,747            3.64                    1,303 Dover                1,379          2.83                      488 Knoxville              ,733            3'.19                    230' London
* 1,040          3.18                      327 Pottsvlile            2,783          13.19 -              _
* 21i Russellville            28,113          28.37                      991 Arkansas Nuclear One                                    20                                        ANS Design Report - Rev. 4
 
Table 3. Siren Detalls for the ANO EPZ Mounting Description  Siren Siren ID U                                              Location                                  Latitude            Longitude      Zone    County              Pole from ADH    Model
                                                    -* - - ..  ....      .... ______ . ,_ .... *----*--*--*-..*-*----- ..-. _..____ . _____ **-****-.....___ -~-~ig_~t.Jr~) ..
1Z1      1001 Whelen 29 WPS2907 Corner of Front St. and Market St.                          35.21924 -93.15294                      T    Yell                  15.2 Intersection of Hwy 28 and Arcadia Rd.
1Z2      1002 Whelen 28 WPS2807 Approx. 100 yds down Arcadia Rd.
35.18017            -93.18961          s    Yell                  15.2 1.9 miles south of Hwy 7 and Hwy 27 1Z3      1003 Whelen 28 WPS2807 intersection on south side of Hwy 27.
35.21265            -93.19426          s    Yell                  15.2 3.7 miles south of Hwy 27 intersection on 1Z4      1004 Whelen 28 WPS2807 Hwy 27 north side of Hwy 35.19644            -93.21616          s    Yell                  15.2 Just off Hwy 27 at the intersection of Alpha lZS      1005 Whelen 29 WPS2907 Rd. (CR 40 and Hwy 27) 35.18037            -93.25319          s    Yell                  15.2 South side of Hwy 155, 2.6 miles west of 1Z6      1006 Whelen 29 WPS2907 intersection with Hwy 22.
35.22657            -93.21175          s    Yell                  15.2 Turn North off of Hwy 155 on Bethel Rd.
(CR 64), then turn West on Haney Hollow 1Z7      1007 Whelen 29 WPS2907                                                              35.24049            -93.22641          u-  Yell                  15.2 Rd. (CR 913). Siren is at second driveway on right.
Mt. Nebo State Park at the intersection of 1Z8      1008 Whelen 28 WPS2807 Hwy :1,55 and Kentucky Rd.
35.22163            -93.25236          s    Yell                  15.2 At Bay Ridge Country Club, take Bay Ridge 1Z9      1009 Whelen 28 WPS2807 DR 1.2 miles from Hwy 22.
35.25855            -93.21677          u    Yell                  15.2 Located 2.8 miles from the intersection of 1Z10 -    1010 Whelen 28 WPS2807 Hwy 7 and Hwy 22 on the north side of                        35.24641            -93.19587          u    Yell                  15.2 Hwy 22.
Located at 2nd St. and Hwy 22 in south 1Z11      1011 Whelen 29 WPS2907                                                              35.236              -93.17313          T    Yell                  15.2 Dardanelle right of 2nd St.
South side of Lower Danville Rd., 320 feet 1Z12      1012 Whelen 29 WPS2907                                                              35.20859            -93.15462          T    Yell                  15.2 south of the intersection with S 5th St.
North Side of East 2nd St. 150 feet west of 2Z1      2001 Whelen 28 WPS2807                                                              35.27698            -93.10901          I    Pope                15.2 intersection of East 2nd St. and Verona.
Arkansas Nuclear One                                                21                                                                      ANS Design Report- Rev. 4
 
Mounting Description  Siren Siren ID tt                                            Location                Latitude  Longitude Zone  County      Pole from ADH    Model Height (m)
At intersection of Elmira and Jimmy Lile 2l.l. 2002 Whelen 28 WPS2807 Rd., siren is 0.1 miles south on Jimmy Lile 35.25449  -93.10342  I  Pope          15.2 Rd.
South of Hwy 7T 0.1 miles at corner of 2Z3      2003 Whelen 28 WPS2807                                            35.24936  -93.12127  I  Pope          15.2 Bernice Cemetery.
Corner of Ea~ 16th and South Detroit on 2Z4      2004 Whelen 29 WPS2907                                            35.26415  -93.12967  I  Pope          15.2 Oakland Heights School Grounds.
North side of Hwy 247 near New Hope 1.6 2Z6      2006 Whelen 29 WPS2907 miles east of intersection with Hwy 7      35.22414  -93.11605  I  Pope          15.2 South.
East side of Sheppa Rd. St. 0.3 miles north 2Z7      2007 Whelen 28 WPS2807                                            35.25344  -93.16099  H    Pope        15.2 of intersection with Old Post Rd.
On Sequoyah Elementary School Grounds 2Z8      2008 Whelen 29 WPS2907                                            35.26758  -93.14869  H    Pope        15.2 off 12th St. in Russellville.
In parking lot off Hwy 64 West1/4 block from 2Z9      2009 Whelen 29 WPS2907                                            35.28552  -93.15919  H    Pope        15.2 intersection with South Cumberland.
North Side of Hwy 326 - 0.8 miles west of 2Z10      2010 Whelen 28 WPS2807                                            35.27955  -93.18061  H    Pope        15.2 intersection with Skyline Drive.
At entrance to Lake Dardanelle State park 2Z11      2011 Whelen 29 WPS2907 on west side of Hwy 326, 2.3 miles          35.29323  -93.2017  H    Pope        15.2 southwest of intersection with U.S. Hwy 64.
West side of Hwy 326, 0.9 miles southeast 2Z12      2012 Whelen 28 WPS2807                                            35.30352  -93.18168  H    Pope        15.2 of intersection with U.S. Hwy 64.
On Reasoner Ave. just off Hwy 7 North, 0.8 2Z13      2013 Whelen 29 WPS2907 miles North of intersection of Hwy 124 and  35.30037  -93.13682  I  Pope        15.2 Hwy 7.
Take Shiloh Rd. East off Hwy 7, 0.4 miles, 2Z14      2014 Whelen 29 WPS2907 turn south on paved road and proceed 0.3    35.31757 , -93.12815  J  Pope        15.2
                      '            miles; siren is on east side of road.
Arkansas Nuclear One                                              22                                    ANS Design Report- Rev. 4
 
Mounting Description  Siren Siren ID#                                              Location                  Latitude Longitude Zone  County      Pole from ADH    Model Height (m) 0.1 miles north of Baker's Creek Bridge on 2Z15      2015 Whelen 29 WPS2907                                              35.34038  -93.13262  L  Pope          15.2 west side of Hwy 7 at Country Club.
Just north of intersection of Hwy 7 and Hwy 2Z16      2016 Whelen 29 WPS2907                                              35.40276  -93.11462  L    Pope        15.2 27 in Dover.
North side of Morgan Rd. 0.7 miles east of 2Z17      2017 Whelen 29 WPS2907                                              35.36554  -93.10677  L  Pope          15.2 intersection with Hwy 27.
East side of Roy Taylor Rd. 0.7 miles South 2Z18      2018 Whelen 29 WPS2907                                              35.34533  -93.08753  J  Pope          15.2 of intersection with Morgan Rd.
East side of Hwy 124, 0.9 miles north of 2Z20      2020 Whelen 28 WPS2807                                              35.32504  -93.09692  J  Pope          15.2 Shiloh Creek Bridge.
Proceed 0.6 miles east on Crow Mountain Rd. 1.8 miles south of intersection with 2Z21      2021 Whelen 29 WPS2907                                              35.30396  -93.08957  J  Pope          15.2 Hwy 124, turn on Yukon Rd. for 0.3 miles; siren is on west side of road.
Proceed 2.3 miles east on Crow mountain Rd. from intersection with Hwy 124, turn north on Sherman Acres Rd. and proceed 2Z22      2022 Whelen 29 WPS2907                                              35.30726  -93.06265  J    Pope          15.2 0.2 miles and turn east on Gravel Rd. and go 0.2 miles. Siren is on south side of Gravel Rd.
North side of Hwy 124 in curve 0.4 miles 2Z23      2023 Whelen 29 WPS2907                                              35.30136  -93.11459  J    Pope          15.2 north of 1-40 overpass.
South side of Hwy 64 East at Hagan's 2Z24      2024 Whelen 29 WPS2907 Datsun 0.8 miles east of 1-40 interchange or 35.27466  -93.08059  I  Pope          15.2 intersection of Hwy 64 and Hwy 331.
At Dare's Car Wash corner of North Boston 2Z25      2025 Whelen 29 WPS2907                                              35.2817  -93.13209  I  Pope        15.2 and East "E" St. in Russellville North side of Hwy 64, 0.5 mile east of 3Z1      3001 Whelen 29 WPS2907                                              35.32245  -93.20183  G    Pope        15.2
                        ~          intersection with Hwy 333.
Arkansas Nuclear One                                              23                                      ANS Design Report- Rev. 4
 
Mounting Description  Siren Siren ID tt                                              Location                  Latitude    Longitude Zone  County        Pole from ADH      Model
                                                                                              ..                            Height (m)
North side of Hwy 333 in curve 1 mile from 3U      3002 Whelen 29  WPS2907                                              35.31349    -93.21891  G    Pope          15.2 intersection with Hwy 64.
South of Arkansas Nuclear One, 1 mile from 323      3003 Whelen 29  WPS2907                                              35.30193    -93.23453  G    Pope          15.2 intersection of Bunker Hill Rd.
East side of Flatwood Ln 0.5 mile from 3Z4      3004 Whelen 29  WPS2907                                              35.31901    -93.24541  G    Pope          15.2 intersection of Hwy 333.
On south side of Hwy 64 in London 0.2 mile 3ZS      3005 Whelen 29  WPS2907                                              35.33134    -93.2582  G    Pope          15.2 west of Hwy 333 intersection.
On south side of U.S. Hwy 64, 1.0 mile west 3Z6      3006 Whelen 29  WPS2907 of intersection with Robertson ~n. and Hwy    35.32721    -93.2284  G    Pope          15.2 333.
East side of Mill Creek Rd. 1.3 miles north 3Z7      3007 Whelen 28  WPS2807                                              35.33982    -93.21062  K  Pope          15.2 of intersection with Hwy 64.
North side of Mill Creek Rd. 2.9 miles from 3Z8      3008 Whelen 28  WPS2807                                              35.35714    -93.21851  K    Pope          15.2 intersection of Hwy 64.
North side of Pleasant View Rd. 1.5 miles 329      3_009 Whelen 29 WPS2907                                              35.33402    -93.18326  K    Pope          15.2 east of intersection with Mill Creek Rd.
North side of Pleasant View Rd. 1.0 miles 3Z10      3010 Whelen 28  WPS2807                                              35.32197    -93.15181  K    Pope          15.2 west of intersection with Hwy 7.
In Piney Community 4 miles west of London 4Zl      4001 Whelen 28  WPS2807                                              35.34428    -93.32532  p  Johnson        15.2 on U.S. Hwy 64.
Knoxville City Limits in front of Knoxville 4Z2      4002 Whelen 28  WPS2807                                              35.38404    -93.36616  p    Johnson        15.2 Elementary School.
South side of Hwy 22 at Yell-Logan County SZl      5001 Whelen 28  WPS2807 Line, 0.1 mile east of intersection of Hwy 22 35.28161    -93.29453  R    Logan          15.2 and Hwy 393.
Right off Hwy 22 on Hwy 393, 1.5 miles SU        5002 Whelen 28  WPS2807                                              35.29633    -93.28739  R    Logan          15.2 toward Delaware Park.
Four miles west of Delaware on Hwy 22 on SZ3      5003 Whelen 28  WPS2807                                              35.28272    -93.37439  Q    Logan          15.2 the right side of the road.
Arkansas Nuclear One                                              24                                          ANS Design Report - Rev. 4
 
Table 4. SWS Activation Points for ANO Site ACTIVATION POINT                PHYSICAL ADDRESS Primary Point -ADH              4815 West. Markham, ECC                  Little Rock, AR 72205 Secondary Backup Point              1448 AR-333,
                                                -SEOF                  Russellville, AR 72802 Secondary Backup Point              305 S Knoxville Ave,
                                          -ADH NP&RP                  Russellville, AR 72801 Table 5. S1ren System Reliability Quarter - Year                Total Siren Tests              Successful Siren Tests          % Successful Test Q4- 2019                            147                              147                        100.00%
Q3- 2019                            147                              147                        100.00%
Q2- 2019                            147                              147                        100.00%
Ql- 2019                            147                              147                        100.00%
Table 6 Summary of Near-Fteld Acoustical Test Results WPS2807 l    (,'
115.1
                                  . Overall* Average                .*115.1 2Z14                113.1                      116.6 1Z11                114.3                      118.5 WPS2907
* 3Z4                116.9 t-----t---------t--------1 120.3 3ZS                116.1                      119.2 2Z13                117.2                      120.3
                            * * *
* Overall Average.*.              115.5.          *. * * *
* 119:0
* According to Entergy, the siren head of Siren 1Z9 was damaged before the near-field test was performed It was repaired after the acoustical test Arkansas Nuclear One                                                25                                ANS Design Report - Rev. 4
 
Pope H<<tor Co1mt.v Arkansas RNer Shoal Cteelc lo Co11 Legend ti' ANO Population Center Urban Area GJ    Zone
              ~ Zones In Johnson County G    Zones In Logan County tf}  Zones In Pope County GJ i:;?
Zone in Pope & Yell Counties Zones in Yell County Do1te: 1/17/2020                                /
JV I'"::;  2, 5, 10 Mile Rings          Cc,:,yri11ht* ESRl Oo1U ;md Map~ 2018, -w.~nsus:cO&#xa5; KU>tn1meerm1, Enter&#xa5;Y                    /
Figure 1. Site location Arka nsas Nuclear One                                                                                            26                    ANS Design Report- Rev. 4
 
N NNW                                        NNE
[ill]
                                            ~                                          I1,0411 0
NW                                                                                      NE I1,938 I                                                                              I2,358 I I
WNW                                                                                                                      ENE 11,155  I                                                                                                            I3,312 I
            ,-                                                                                                      - ....I w                                                                                                                              E
  ~* o                                                                                                                  o I
I6,854 I I                                                                                                          i WSW                                                                                                                      ESE O&sect;I]'                                                                                                                122 ,0591 I
SW  '  '                                                                              SE
[ill]                                                                                  !4,474    I
                                                                                                  - _,  10 M iles t o EPZ Boundary SSW        --
I        0 SSE
[ill]                  s                  I4,7561          N I1,206 I Resident Population Mi les  Subtotal by Ring Cumulative Total 0 -1              209                209 1 -2              794              1,003 2- 3            2,199              3,202 3- 4            3,366              6,568                                w                                                    E 4-5              5,013              11,581 5-6            10,494              22,075 6-7            12,955              35,030 7-8              7,307              42,337 8-9              5,274              47,611 9 - 10            5,258              52,869 10 - EPZ                2            52,871 Total :          52,871 Figure 2. Permanent Resident Population by Sector for the ANO EPZ Arkansas Nuclear One                                              27                                ANS Design Report- Rev. 4
 
wA ,
            '(Cl.irksvll/e Zone: K Zone: L  Z1 2    7 Pope County an 5Z3 nty Zone: Q
                                                                                  **z.a---.-----*- --,-i...,
1Z6 ANO Siren                                                  Yell                  1Z4 1Z3 GJ
(;SJ Zone Shadow Rqlon County        Zone: S lZS c]  County Boundary
(' ::: 10 Mile Rin1 1Z2 Cenlus Blocks
          -      >* 2,000 People/ SqMlle Figure 3. Census Blocks with Population Density Exceeding 2,000 People per Square Mile Arkansas Nuclear One                                                                  28                                              ANS Design Report- Rev. 4
 
a11 5Z3 nty Zone:Q 1Z6
                                                                                          . *zs--...---**--l-Z -3.a. ""\..I
* ANO Yell                    1Z4 e        1Z Oa GJ Siren zone
            ~ Shadow Resion County        Zone: 5 1Z5 c:'.J I"::
County Boundary 10 Mlle Ring Census Blocks
          -      >= 2,000 People/ SqMlle Figure 4. Census Blocks with Population Density Exceeding 2,000 People per Square Mile {Filter 1 Applied)
Arka nsas Nuclear One                                                                          29                                                    ANS Design Report - Rev. 4
 
Flagged blocks from Step 1 that have                                                            Creation of 1 square mile buffer a density higher than 2,000 ppl/sqmlle                                                          arou nd each block centroid 2Z14
* Block 2:
z        J    2020 Population - 172
                                                -            Al'@a -0.039 sqm,le
* Density - 4,208 ppl/sqm1le Block 3:
2020 Population - 102 Area
* 0.023 sqmile Density - 4,244 ppl/sqmile 0          0.25        0.5 Miles                                                                            0.25          0.5 Mlle locks by each 1 square mile buffer d census data within 1 square mile Lecend ANO e  S.ren 0  Mock Centroid
                                                                                                                                                                          ,Q _
EPZ lDMllelllflc 1U IZ5
* Cemus Blocb
                                                                                                          ~-----
0 1l2 i);ate:7/9120'20 People/SquaN MMe
                                                                                                                                                                                  <2,000 0            0.25        0.5 Mile  0 2.5 5Miles          Copvr*cht &#xa3;SRI Oau ind M.iip,11011. ~.census.cov wit hin 1 sqm ile                                                                                                                    l(LOEP1f"lt4m,c.fnterrv      -    >=2,000 Figure 5. Applying Filter 2 to Eliminate Isolated Neighborhoods from High Population Density Consideration Arkansas Nuclear One                                                                        30                                                                    ANS Design Report - Rev. 4
 
wA ,
            -yc,11rksville I
Zone: L    Z1 2    7 Pope County SZ3 Zone: Q
* ANO Yell                  1Z4 (iJ Siren Zone
            ~ Shadow Rqion County        Zone: 5 lZS cJ r:::
County Boundary 10 Mile Rin1 Censu1a*1rs
          -      >* 2,000 People/ SqMlle Figure 6. Final Census Blocks with Population Density Exceeding 2,000 People per Square Mile after Applying Filters Arkansas Nuclear One                                                                          31                                                        ANS Design Report - Rev. 4
 
Legend
            *A ANO WPS2807
* WPS2907
            <:} Zone Contour Q  70dBC Q  60dBC r::  10 Mile Ring
                                        ~'" 7!,(20"XJ (0Pr'ICl'lt fSIII 0.tt.1 &#xa5;'d "1tPI KlD [l\&l,IW'f'fl"I, [nlfl'f'I' ioa Population Density          wrv<<- l""" Crfd,u, ,CUro~          hn. l-lfM. ,.,    ~ \.
l o / . ~ ~CRfMLNT P NA.Un..h* I UQ.an Mtl l., tM'Chin;a
                                        /Kant iont)    h t! ~to, lin (Th;abr,d) NC.CC. It)                                                      0 2.5
            -  > 2,000 People/Sq, Ml. ()cll'n'il:<etO,bp C'OnU!buto", ar,d ltw  ~ UW'f (Gmffl<,fflll'j' Figure 7. Siren Coverage Mop for the ANO EPZ Arka nsas Nuclear One                                                                                                      32                          ANS Design Report - Rev. 4
 
                                                                        -~*~***.
                                                                          *,~a:    *,,~,~ ,
ff-0 ,,
                                                                                        ~:,;
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                                                                                                      , . .~
Legend A
ANO WPS2807
::              ,~
* WPS2907 GJ  Zone                                                      1/~;}> - ;/,
W/4/'                //
            ~    Shadow Region                                                * , I  * ~  I  ,
          '- _, 10 Mile Ring Figure 8. Siren System within the ANO EPZ Arkansas Nuclear One                                33                            ANS Design Report - Rev. 4
 
    .--;1    !!!!!!II!
Backup Power Primary Siren '.
Radio Transmitter'.
D I      Mi Primary Activation Poin
                                                                                                    *-*~..~
                                                                                                \c:;
                                                                                                          ~
                                                                                                          '.t
                                                                                                          *<3:'
24 Hour ADH ECC Little Rock
                                                                                                            *o
                                                                                                              *~*~..
                                                                                                                *-:)
                                                                                                                    ~
D I      Mi Secondary Backup
(<<i>>)
Activation Point ADH NP&RP                                                                                                  Siren_ Sites Russe llville I
D I
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                                                                                                              ~.*
                                                                                                            &sect;i,'
                                                                                                      ~.:/,'*
Secondary Backup Activation Point SEOF (ANO Site)                                                                            ,f,'
                                                                                                ~*
                                                                                              ~.*, I I
                                                                                            ,I I
ADHMobile Command Post Backup Siren Radio Transmitter Figure 9. Control System Layout for the ANO ANS Siren System Arkansas Nuclear One                                      34                                  ANS Design Report - Rev. 4
 
Lt.I a::
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a::
Lt.I a.
I:                                                                                                    SHADOW Lt.I
~                                                                                                        ZONE WARM Figure 10. Sound Transmission in Temperature Lopse Conditions a:
:::)
!<<a:
....a.
.......::E COOL Figure 11 . Sound Transmission in Temperature Inversion Conditions 3
RECEIVER Figure 12. Outdoor Sound Propagation near the Ground Arkansas Nuclear One                                  35                                ANS Design Report - Rev. 4
 
WIND DIRECTION SHADOW SOUND PATHS                                                                      ZONE Figure 13. Upwind Sound Propagation WIND DIRECTION 3
O Figure 14. Downwind Sound Propagation with Terrain and Vegetation Effects Arkansas Nuclear One                                    36                              ANS Design Report - Rev. 4
 
3Z7 A
Zone: K  3z9 2Z20
                                              ,*s-z                                                                                                                                          I~
2Z14 3Z4 3Z2                                                                                          Zone: J
* 6-2                                                                                                                                            2Z21
                                                      . 3Z3                                                                                                          2Z23 2Z9 2Z10 A    Zone:]
2Zl A
H8                                      ~                            o.: 11*nozo Zone: R                                                                                              .  .. St                  ~ fSlll~U;;indM,l9s2017.KlOfnc1~nnc, fnt~liY Sen,ice L;iyerC    *1.      : fw,, HfRE. G:mmn. USGS, lllterm.ip, INCREMENT P.
NAC.ln hn JI    n,      hri Ch.,JHonc tore) hr, Kor*:.i. hrl fT~<l1ndl. NGC(..
jc! O~Strffl~(Clftlr,t,vt~. *r>d !ht' GIS VWr Commul'lfty Legend
          *A ANO WPS2807 Zone: U 1Z1
* WPS2907 Siren Test Location
* Far-Field Test Location Near-Field Test Location                                  1Z6 GJ  Zone c=J  County Boundary Zone:  s I":: 10 Mile Ring              0 ---  1 2 M Iies Figure 15. Near-Field and Far-Field Test Locations Arkansas Nuclear One                                                              37                                                                                ANS Design Report - Rev. 4
 
REFERENCES
: 1. American National Standards Institute, Inc. (ANSI) Sl.4-1983, "Specification for Sound Level Meters"
: 2. ANSI S12.14-1992, "Methods for the Field Measurements of the Sound Output of Audible Publlc Warning Devices Installed at Fixed Locatlo~s Outdoors"
: 3. ANSI S12.18-1994, "Procedures for Outdoor Measurements of Sound Pressure Level"
: 4. ANSI Sl.43-1997, "Specifications for Integrating - Averaging Sound Level Meters"
: 5. ANSI Sl.26-2014, "Method for Calculation of the Absorption of Sound by the Atmosphere"
: 6.  "Arkansas Nuclear One - Upgraded Public Alert and Notification System Design Report Update", May 2016
: 7. Entergy Operations, Inc., "Supplement to Arkansas Nuclear One - Upgraded Public Alert and Notification System Design Report Update", February 2017
: 8. Arkansas Department of Health (ADH), "Arkansas Nu dear One Siren Warning System Maintenance Plan",
September 15, 2020
: 9. Arkansas State Emergency Operations Faclllty (SEOF), "Rapid Warning System Activation Checklist", March 2020
: 10. Entergy Operations, Inc., "Arkansas Nuclear One Emergency Plan" ~ev. 39, November 2014
: 11. Arkansas Division of Emergency Management (ADEM), "Arkansas Comprehensive Emergency Management Plan", Revised, September 30, 2019
: 12. Federal Emergency Management Agency (FEMA) CPG 1-17, "Outdoor Warning Systems Gulde", March 1, 1980
: 13. FEMA-REP-10, "Guide for the Evaluation of Alert and Not1f1cation Systems for Nuclear Power Plants",
November 1985.
: 14. FEMA Technical Bulletin (Version 2.0), "Outdoor Warning Systems", January 12, 2006
: 15. FEMA, "Radiologic:al Emergency Preparedness Program Manual" (FEMA P-1028), December 2019
: 16. Johnson County Department of Emergency Management, "Johnson c;ounty Radiological Emergency Response Plan", Rev. 5.2, July 2019
: 17. Logan County Office of Emergency Management, "Logan County Radiological Emergency Response Plan",
Rev. 5.2, July 2019
: 18. Pope County Office of Emergency Management, "Pope County Radiological Emergency Response Plan",
Rev. 5.2, July 2019
: 19. Yell County Office of Emergency Management, "Yell County Radiological Emergency Response Plan", Rev.
5.2, July 2019
: 20. lnterr]at1onal Organization for Standardization (ISO) 9613, "Acoustics - Attenuation of Sound during Propagation Outdoors" 1993
: 21. KLD Engineering, P.C. (KLD), Technical Report 517, "Arkansas Nuclear One Development of Evacuation TI me Estimates", Rev. 1, December 2012 Arkansas Nuclear One                                    R-1                            ANS Design Report - Rev. 4
: 22. KLD, Technical Report 1167, "Arkansas Nuclear One 2020 Population Update Analysis", September 19, 2020
: 23. Nuclear Energy Institute (NEI) 99-02 Rev. 7, "Regulatory Assessment Performance Indicator Guideline'',
August 31, 2013
: 24. Nuclear Regulatory Comm1ss1on (NRC), 10 CFR 50.47, "Emergency Plans"
: 25. NRC, 10 CFR Appendix E to Part 50, "Emergency Planning and Preparedness for Production and Utlllzat1on Facilities" Arkansas Nuclear One                                    R-2                          AN~ 1Des1gn Report - Rev. 4
 
APPENDIX A Compliance with Federal Regulations and Guidance
 
A. Compliance with Federal Regulations and Guidance Table A-1 is a crosswalk to show compiiance of this design report with federal guidance and regulations.
The criteria in the left column of Table A-1 are taken verbatim from Part V: REP Program Alert and Notification System Guidance, Section C. "ANS Evaluation Report Guidance" of the December 2019 revision of the FEMA REP Program Manual. The references in the right column of Table A-1 are the sections, figures and tables from the design report wherein the criteria from the FEMA REP Program Manual are addressed.
Arkansas Nuclear One                              A-1                          ANS Design Report- Rev. 4
 
Table A-1. Regulations Crosswalk Section(s) where Criteria                                                                                                      Requirement is Met
: a. Introduction of the ANS Evaluation Report                                                                  '.
                                                                                                                      *.,    +
                                                                                                                      ,_                _\~**
Title Page      .                                                                                                                              '
The Title Page must contain basic infonnatlon about the report such as the name ofthe report and date of the report, name of the nuclear power plant, and applicable revision number.                                                  Cover Page Signature Page                                                                                                    ,,.
                                                                                                                        *,*            *V The Signature Page has signatures of responsible officials attesting to the accuracy, completeness, and concurrence of information included within the ANS evaluation report. Since alert and notification is a key component of offsite planning and is part of the state, local, territorial, or tribal government(s) radiological emergency plan approval under 44 CFR 350, the responsible official from the state, at a minimum, must sign. No ANS design, plan, or revision may be considered by FEMA without the state's concurrence.
Other signatories could include responsible officials or representatives from the utility emergency preparedness, the local or C!JUnty emergency management agency, the state, local, territorial, or tribal
  -government(s) emergency management, and the FEMA Region.                                                                      Signature List Revision History              '                                                                                  '.
The Revision History is a summary of the current version, as well as a history of past revisions. This is typically shown as a table with each past revision number and an associated summary outlining the change in each version.                                                                                                      Revision History Table of Contents
                                                                                                                                          -. C The Table of Contents outlines all sections of the report; any ad9itional information should be included as annexes or appendices.                                                                                                      Table of Contents
                                                                                                                          ..                          ,---    .-(-
Executive Summary                                                                                                                  ''                      ..
The Executive Sumrriary provides a short overview that describes the overall physical and administrative features and functions of the ANS. lfthe ANS evaluation report is an update to a previous version, it should also include a summary ofthe changes from the previous version.                                                  Executive Summary Arkansas Nuclear One                                                      A-2                                                    ANS Design Report - Rev. 4
: b. Body of the ANS Evaluation Report Below are points of review that should be addressed in the body of the ANS evaluation report for each      The ANS Plan portion of the type of system used. The ANS evaluation report is divided into two main sections: the ANS plan, where      FEMA Evaluation Report will the administrative means and emergency planning aspects of the system is addressed; and the design        be completed by FEMA based report, where the physical means and technical components ofthe system are detailed. Depending on        on their review of the county the type of system, some headings may be more relevant or need more information than others.              and state plans. This report is the Design Report. This appendix will help FEMA review the Design Report ensuring that all necessary criteria have been addressed.
                                                                                                                  -~~ J    .,_*.                        .. -
Ucenslng obligations (if any)                                                                                : ,.....; :    'f
                                                                                                                                                    * *  ! *-~ **
NRC licensing agreements address having a functional ANS and can include specific requirements unique to a particular licensee and/or state, local, territory, and/or tribal government organization. Any obligations or concessions contained within the licensing agreement should be included.                                            Section 1 Requirements                                                                                                                      Section 2
* System Coverage                                                                                                                Section 2.1 0
Population'- Description or characterization of the population required to be alerted across a    Section 2.1.1, Figure 1 through geographical area.                                                                                    Figure 6, Table 1, and Table 2 Section 2.1.2, Figure 1 and 0
Geographical Area - Description of the geographical area intended for each systems' coverage.                                Table 2 0
Means - Description of the type of system to be used.                                                                    Section 2.1.3 0
Primary Methods - Description of the methods to be used to alert and notify the population in the geographic area, both described above.                                                              Sections 2.1.4 and 3.1, Table 3 0
Backup Methods - Description of the methods to correct or compensate for failures (including total failure) for any segment of the population that did not receive the alert and/or notification.            Sections 2.1.5 and 3.3.3
* Population/Demographics- Description of population groups (e.g., transient populations, those with access/functional needs, non-English speakers, etc.), including any special requirements.                                        Section 2.2
* Interoperability- Description of how the system interfaces with other systems and how that interface is accomplished, if applicable.                                                                            Section 2.3, Figure 9, Table 4
* Operation - Description of all operational requirements.                                                  Section 2.4 and Appendix B
* Management/Administration - Identify and describe the organizations and/or individuals responsible for management and oversight of the system, or the administration of third party agreements with                                  Section 2.5 Arkansas Nuclear One                                                        A-3                                                    ANS Design Report- Rev. 4
 
vendors.
* Security/Privacy                                                                                                          Section 2.6 0
Physical Security- Description of physicaJ security requirements, such as prevention of unauthorized access to systems and the components necessary to operate it .- .                                    Section 2.6.1 0
Logical Security - Description of logical security (cyber-security) requirements, such as prevention of unauthorized or malicious access to the system, or accidental or malicious actions resulting in denial of service and other cyber-security.                                                                        Section 2.6.2
* Maintenance/Repair                                                                                                        Section 2.7 0
Preventative maintenance - Identify and describe routine and periodic maintenance
                                                ,'-),' '
requirements.                                                                                            Section 2.7.1 and Appendix C
          &deg; Corrective maintenanc*e ~ 1.de_ntify and describe procedures and resources for correcting areas requiring improvement.                  -                                                                Section 2.7.2 and Appendix    b
* Availability/Reliability- Identify and describe reliability and availability requirements. The NRC requires greater than 94 percent availability, or the elimination of all critical*single-poinf failure modes.
These requirements may include system operation in all weather conditions typical for local climate.                Section 2.8 and Table 5
* Testing - Identify and describe how system performance, availability and reliability is tested and verified on a periodic basis, including how often and the frequency and method of testing, and what-aspects of the system are actually tested. Not all systems ler:,d themselves to full operational testing. In those instances, -passive testing, actual event verification, and inspection may be* considered. Identify how the results of periodic and a_s-needed testing are recorded, preserved, and made available for inspection.            Section 2.9 and Appendix C
* Responsibility O Identify the individual(s) responsible for system maintenance, testing, and repair.            Sections 2.9, 2.10 and 3.2.1
* Training - Identify and describe initial aod ongoing training requirements for all associated personnel.            Sections 2.11 and 7 Sections 2.7, 2.8, 2.9, 2.12, 4.3
* Quality Assurance - Identify and describe a comprehensive, ongoing quality assurance program that              and 5, Table 5, Appendices B may include testing; record-keeping, internal and external inspections, and exercises.                                        and C Desaipt/on/Performance                                                                                                      Section 3
* Physical components                                                                                                      Section 3.1 0
System com~onents*- Description of the major part~ of each system being employed.                      Section 3.1.1, Figure 8, Table 3 0
User interfaces - Tbe device, system, or physical ~quipment used to activate or control the ANS        Sections 2.3, 3.1.2 and 3.3.1, and its locations.                                                                                                Figure 9, Table 4
        &deg; Functional block diagrams-A diagram used to describe each logical and physical connection of                Sections 2.3 and 3'.1.3,
        -components and systems.                                                                                              Figure 9
  ** Administrative components                                                                                                Section 3.2 0
Organizational res~onsibilities - Description of established roles and responsibilities for operation,  Sections 2.9, 2.10, a_nd 3.2.1 Arkansas Nuclear One                                                          A-4                                            ANS Design Report - Rev. 4
 
planning, maintenance, and testing of the ANS under discussion.
0 Management - Description of the controls used to ensure the proper use of ANS and implementation of any corrective actions.                                                                          Section 3.2.2
* Operational components                                                                                                      Section 3.3 Sections 2.3, 3.1.2 and 3.3.1, 0
Activation.:.. Description of location(s), access, and processes for activating ANS.                          Figure 9, Table 4 0
nming - D_escription of how long it takes to activate the system-after determining the need to activate ANS-and length of time between initiation*ofthe system and when the alert and notification is received by the public.                                                                    Sections 3.3.2 and 4.3 0
Geo-Targeting - Description of the system limits in its ability to a select a geographic location.                Section 3.3.3 Verification '                                                                                            ~1&#xa3;:~&;4;<~-~?:!_'-t,/1~, *~,:*.~~~; l&deg;i' ::::~~.~* ,::
Documents that the system .or approach meets the design report requirements identified above. The need to verify applies to implementation of both new and modified systems and approaches. Information provided here should objectively_demonstrate that the system or approach meets the stated requirements, which can be verified by tests, inspections, demonstrations, analyses, studies, or any other applicable method. Each of the requirem~nts identified should have a description of the corresponding verification process.                                                                                                          Section 4
* Coverage - The coverage (extent or reach) of the ANS can be verified through modeling of the ANS medium (e.g., radio, tone alerts, visual alerts, etc.) using e~istfng accepted* sources and databases,      Section 4.1, Figure 10 through empirical data through testing, or other recognized means of verification.                  ~                Figure 15, Table 6, Appendix E Sections 2.1.1 and 4;.2 - 2010 Census data ext~polated to
                                      ~
2020 for permanent residents
                .-                                                                                            and employees, transient data
* Population/Demographics- Population and demographics inform_ation may be verified by identifying          provided by .county and state credible sources used for the population data. Credible sources may include census data, city or county        emergency management records,* local/tribal organization. records, etc.                                                                    agencies, Figure 7
* Metrics - Identification ofthe method(s), standard(s), or precedent(s) used to determine success or failure to meet the design objectives.                                                                                        Section 4.3 Availability/Rellablllty                                                                                  ~*~i\ r' *;~; :,':"-~ .--t,~_.:. ~*.~:::~- ::.-.ft~\.\:~)~*:~
Description of how failures are detected and traGked/trended, how the system is tested ~ind maintained,      Sections 2.7, 2.8, 2.9, 4.3 and and how v~lner:abilities are identified, mitigated, and reported.                                                                        5 Arkansas Nuclear One                                                        A-5                                            ANS Design Report- Rev. 4
 
Security and Privacy
                                                                                                        ~:~t:~/>~~: ):~:~*:. ;; .<.~;.:r~~i?\/ . ,_* t< ; .. ;
ir*.;.;_,-,::.,,->{*1..>1;;_:, ~-,,--.,?,~':c,:~, :-Y.;:i;._,,;
Description of the supporting information and data.                                                                      Sections 2.6 and 6
                                                                                                        *\...\ * .-_: , . !, ......... "t;:''..,- * '-.~ ,-~ *.;.. i.:. .,., ).<'\'.Jo.' *~i' ~
Training and Public Outreach                                                                        \~__i--,~ ~._.;*'!*<  *.., :.,.;:..~            -.,~;?~  '--.~if,:_, ...i:'";1,~:,t~<.
Description of the training required for applicable stakeholders oft:he ANS, including training for personnel who operate and maintain the ANS; also a description of the public education and outreach activities. An informed population is far more likely to understand and respond appropriately to notifications and take action in emergency situations.                                                                                    Section 7
: c. Attachments
                                                                                                        '<.,.1_.'t- ~,.t+.; ..--1--~:*'- * . {"'.~~~C'i: ,.,.., .._,
                                                                                                                                                      ~      ~
                                                                                                        ~::..'"',~- ,:: ~i-.~-~ *; '~/ ~\, ..:..f(#~tTJ,.~7':t:, "-~.._
                                                                                                                                                                                          ~
Additional infonnation, such as maps, d*iagrams, and/or references, which support the efficient evaluation of an ANS, should be included.                                                                                      Not applicable Arkansas Nuclear One                                                    A-6                                                          ANS Design Report - Rev. 4
 
APPENDIX B ANO EWS Activation Procedures
 
RAPID WARNING SYSTEM ACT/VAT/ON (Pre-Activation ofSEOF)
CHECKLIST THIS CHECKLIST IS FOR USE FOR IMMEDIATE ACTIVATION OF THE EMERGENCY WARNING SYSTEM FOR GENERAL EMERGENCY CLASSIFICATIONS PRIOR TO ACTIVATION OF THE RADIOLOGICAL EMERGENCY RESPONSE TEAM.
TIME:                      DATE:                  EC#:
OPERATOR/SDO:
: l.    [    ] (ANP ONLY) IF A STAFF DUTY OFFICER IS PRESENTl.CONTACT ADH COMCENTER VIA HOT LINE OR DEV /VS AND INFORM THE COMCENTER OPERATOR THAT ANP IS ASSUMING OPERATION CONTROL OF ACTIVATION OF THE WARNING SYSTEM.
NOTE: THE ADH COMCENTER OPERATOR WILL BE RESPONSIBLE FOR THE ACTIONS IN THIS CHECKLIST UNLESS NOTIFIED TO THE CONTRARY BY ANP SDO)
ACTIVATION OF SIRENS AND TONE ALERT RADIOS MUST OCCUR WITHIN 1 5 MINUTES OF NOTIFICATION - DO NOT DELAY
: 2.    [    ] USING THE "RECOMMENDED PROTECTIVE ACTIONS - EVACUATION" INFORMATION FROM THE "EC" FORM, TRANSFER THE ZONES TO BE EVACUATED TO THE "GOLD" EVACUATION MESSAGE FORM (S)
J
: 3.    [    ] USING THE "RECOMMENDED PROTECTIVE ACTIONS - SHELTER" INFORMATION FROM THE "EC" FORMR TRANSFER THE ZONES TO BE SHELTERED TO THE "GREEN" SHELTE ING MESSAGE FORM (S)
: 4.          ~USING THE DEF/VS FAXA TRANSMIT ALL APPROPRIATE MESSAGE ORMS TO THE NATION L WEATHER SERVICE.
: 5.    [    \\,VERIFY RECEPTION OF THE MESSAGE FORMS BY THE NATIONAL EATHER SERVICE VIA NAWAS.
TIME THIS SECTION COMPLETE,._,.,*_ _ _ _ _ _ _ _ _ __
: 6.          ] USING THE ZETRON CONSOLE:
A. ARM CONSOLE USING KEY B. SELECT "SIREN" NET C. SELECT "KXRJ ON" D. PRESS "PAGr-SAFETY''
Fonn 11001 03/2020 PAGE I
 
RAPID WARNING SYSTEM ACT/VA TION (Pre-Activation ofSEOF)
CHECKLIST THIS CHECKLIST IS FOR USE FOR IMMEDIATE ACTIVATION OF THE EMERGENCY WARNING SYSTEM FOR GENERAL EMERGENCY CLASSIFICATIONS PRIOR TO ACTIVATION OF THE RADIOLOGICAL EMERGENCY RESPONSE TEAM.
: 7.      [    ] USING ENS, TRANSMIT (IN A FILL-IN-THE-BLANK METHOD) ALL APPROPRIATE MESSAGE'.S TO RUSSELLVILLE AREA BROADCAST STATIONS.
AFTER HOURS SEE ATTACHMENT #1.
: 8.          ] USING THE ZETRON CONSOLE:
A. ARM CONSOLE USING KEY B. SELECT "SIREN NET Fl" C. SELECT "ENS RADIO" D. PRESS "PAGE SAFETY''
E. WAIT 10 SECONDS F. PRESS THE "TRANSMlr BUTTON AND READ THE FOLLOWING MESSAGE
                    'THIS IS THE ARKANSAS DEPARTMENT OF HEALTH .... ATTENTION ALL BROADCAST STATIONS .... PLEASE LOCATE YOUR GOLD AND GREEN MESSAGE FORMS AND STAND BY FOR AN EMERGENCY MESSAG~ .. REPEATING ... ALL BROADCAST STATIONS, PLEASE LuCATE YOUR GOLD AND GREEN MESSAGE FORMS AND STANDBY FOR AN EMERGENCY MESSAGE"
: 9.          ] WAIT 1 MINUTE FOR STATIONS TO LOCATE FORMS
: 10.          ] USING THE ZETRON CONSOLE:
A. SELECT "SIREN NET Fl" B. SELECT "ENS RADIO" C. PRESS "PAGE SAFETY" D. WAIT 10 SECONDS E. PRESS THE "TRANSMIT' BUTTON AND READ THE FOLLOWING MESSAGE "THIS IS THE ARKANSAS DEPARTMENT OF HEALTH ....
ATTENTION ALL BROADCAST STATIONS PLEASE FILL OUT AND CHECK THE NOTED INFORMAtlON ON YOUR "GOLD" EVACUATION MESSAGE." (READ SLOWLY AND CLEARLY EACH APPROPRIATE BLANK THEN REPEAT FOR THE GREEN MESSAGE) "PLEASE ALL OUT AND CHECK THE NOTED INFORMATION ON YOUR "GREEN" SHELTERING FORM. EAS TONE ACTIVATION IS REQUESTED, THE SIREN WARNING SYSTEM WILL SOUND MOMENTARILY" Form 11001 03/2020 PAG E2
 
RAPID WARNING SYSTEM ACT/VA noN (Pre-Activation ofSEOF)
CHECKLIST THIS CHECKLIST IS FOR USE FOR IMMEDIATE ACTIVATION OF THE EMERGENCY WARNING SYSTEM FOR GENERAL EMERGENCY CLASSIFICATIONS PRIOR TO ACTIVATION OF THE RADIOLOGICAL EMERGENCY RESPONSE TEAM.
TIME THIS SECTION COMPLETED - - - - - - - = - - - - - - - - - -
: 11.    [    ] ACTIVATE THE SIREN WARNING SYSTEM IN ALL ZONES 1 2.        ] USING THE ZETRON CONSOLE:
A.      SELECT "SIREN" NET B.      SELECT "ALERT ALL ZONES" C.      PRESS    "PAGE SAFETY" D.      DO NOT CANCEL, SIRENS WILL SOUND FOR 3 MINUTES!
TIME THIS SECTION COMPLETED: - - - - - - - - - - - -
1 3.    [    ] CONFIRM RECEPTION OF MESSAGES BY THE FOLLOWING RADIO STATIONS:                                  *
            !      j KOC KMTC RUSSELLVILLE RUSSELLVILLE KXRJ (ATU) RUSSELLVILLE (479) 968-6816 (478) 968-7400 (4 79) 968-0222 Or (479) 317-7127 or (479) 968-0583 NOTE: IF ANY STATION(S) FAILED TO RECEIVE MESSAGE(S) VIA ENS, READ THEM IN A FILL-IN-THE-BLANK METHOD.
: 14.    [      LITTLE ROCK ECC ONLY) NOTIFY ANY COUNTY WARNING POINTS W  HICH FAILED TO RESPOND TO THE ROLL CALL CONDUCTED BY ANO (ANO WILL NOTIFY ADH OF ANY STATIONS WHICH          FAIL TO RESPOND TO THE NOTIFICATION ROLL CALL)
POPE COUNTY                      1479! 890-6914 JOHNSON COUNTY                      479 754-2200 lOGAN COUNTY                        479 963-6800 YELL COUNTY                          479 495-4881 CONWAY COUNTY                    ( 01) 215-4911 ADEM (STATE EOC)                    (501) 683-6705 1 5.    [    ] (LITTLE ROCK ECC ONLY) COMMENCE CHECKLIST FOR NOTIFICATION AND ACTIVATION OF RADIOLOGICAL EMERGENCY RESPONSE TEAM
: 16.    [    ] (ANP ONLY) COMMENCE CHECKLIST FOR SDO / LGL SEOF PRE-ACTIVATION.
Form 11001 03/2020 PAO E3
 
RAPID WARNING SYSTEM ACT/VA TION (Pre-Activation ofSEOF)
CHECKLIST THIS CHECKLIST IS FOR USE FOR IMMEDIATE ACTIVATION OF THE EMERGENCY WARNING SYSTEM FOR GENERAL EMERGENCY CLASSIFICATiqNS PRIOR TO ACTIVATION OF THE RADIOLOGICAL EMERGENCY RESPONSE TEAM.
TIME THIS SECTION COMPLETED
                                    *END*
Foll!l 11001 03/2020 PAG E4
 
LOCAL BROADCAST STATIONS AFTER HOURS RECALL Radio stations in the Russellville area may not be manned after normal business hours or on weekends. These stations have agreed to recall their staff upon notification. This notification will be done by calling until ONE person from each station has been reached.
* EAB Radi 0 Group Name & Numbers                Attempt      Attempt      Attempt    Result 1          2            3 Aaron Elmore Home(479)890-0508 Studio Numbers (479) 968-6816                  .
(479) 968-6821 Johnny Story Studio Numbers (479) 968-6816 (479) 968-6821 KMTC Radio Mellssa Krueger Studio Number (479) 968-7400 KXKJ A I u Radio (May Not Re~ond Jf No One is here)
(479)-968-0222 Or (47~)-317-7127 Or (479)-968-0583 Form 11001 03/2020 PAG E5
 
1 APPENDIXC ANO SWS Testing and Maintenance Procedures
 
Arkansas Nuclear One Siren Warning System Maintenance Plan Siren Site Maintenance Plan Pqe1~f1 Siren#:                  Tech:                                                  Date:
Perfonn the following Inspections/tests and record condition/results:
NOTE: Ensure the use of    er PPE NOTE: Take photo (s) of siren damage as needed.
Check the Followlng:              Compl~      COMMENTS/REPAIRS PERFORMED Record slren--number. Technician's name 1  & date In spa~~ provided above.
Check Trees and Vegetation around Ca bl net. Antenna and Homs. So as not to damage or affect sirens function, e.g. trees 2  near horns, cannot access controls.
Check Pole for damage, e.g. leaning, sinking, severe oxidation, ground rods 3  missing, loose or cut Check Radio Antenna for damage, e.g.
4  missing, elements missing.
s  Check for upper horn damage.
Check Cabinet for damage, e.g. door seals, severe dents or ~lstortlon, lock broken, 6  water or l_nsect Intrusion.
Check Electronics for damage, e.g. loose connections, corrosion, chafing of wlf'es, 7  heat dlscoloratlon & surge suppressor.
Check Ba_tterles for damage, e.g. termlnal                                          r corrosion, casing distortion, heat 8  dlscoloratlon .PERFORM LOAD TEST-Oleck the Power Drop for damage, e.g.
weather head not sealed, splices ex~.
cables frayed, cable Insulation damaged, 9  disconnect malfunction.
10  ~      and record battery voltage.                          Voltage=        voe Monitor Battery volta8:e while running a silent test. Ensure batterv voltage goes no 11  lower than 21 VDC.
Plug In charger - watch for chafBel' to 12  COfTl8 on & current meter to r1se.
Run SIient Test. Check that all amplifier
          ':&#xa3;D's are on and all components are med on.
NOTE: ADDmONAL COM_MENTS ON BACK
 
i'
* Arkansas Nuclear One Siren Warning System Maintenance Plan NOTE NATURE OF REPAIR: (Parts replaced, Possible c;ause of the problem)
                                                                            .i NOTE IF ADDmONAL ACTION(S) IS REQUIRED: (Driver replacement, Battery change)
 
.MELE:M ENGINEERING COMPANY INC.
51 Winthrop Road Chaster, Connecticut 06412-0684 Phone. (800) 63SIREN Phone: (860) 526-9504 Fax: (860) 526-4784 Internet: www.whelen.com Sales e-mail: iowsales@whelen.com Customer Service e-mail: iowserv@whelen.com WPS-2800 SERIES HIGH POWER VOICE
                & SIREN SYSTEM Operating and Troubleshooting Manual For warranty information regarding this product, visit www.whelen.com/warranty 02001 Whelen Eng1neenng Company Inc Form No 13580C (100710)
 
Table Of Contents Section I:      Overview of System Components
                    'a) Station Component Locations ..................... - .................................................. page 4 b) Station Components Defined ............................................................................ page 5 Section II:      System Operations a) Remote Operations ..........................................*-****....................................... page 8 b) Local Operations ............................................................................................... page 8 Section ill:    Understanding Station Addressing Central Point Source ........................................... - ............................................... page 10 Governmental ......................................................................................................... page 16 Section IV:      Troubleshooting Audio Loss .............................................................................................................. page 17 Solar Regnlator ...................................................................................................... page 18 AC Battery Charger............................................................................................... page 18 Digital Voice .................................................. - ...................................................... page 20 Partial or Full Diagnostic Failure ............... - ................... ~***** ............................. page 20
* , Section V:      System Maintenance Frequency of Testing and Activation .................................................................... page 21 Quarterly Maintenance ......................................................................................... page 22 Visual Siren Station Inspection ...................._ ..................................................... page 23 Siren Cabinet and Components ............................................................................ page 23 Speaker Assembly and Pole Top Equipment ....................................................... page 23 Station Performance Testing ................................................................................. page 24 Maintenance Check List ........................................................................................ page 26 Illustrations Fig. 1: Station Wiring Diagram ....................................................................................................... page 3 Fig. 2: Siren Cabinet Door Components ........................................................................................ page 4 Fig. 3: Station Control Panel ........................................................................................:.................. page 9 Fig. 17: System LED Diagnostic Indicators ................................................................................... page 28 Page~
 
WAT
                                        -                                                      ~*                      -P'OR-VMJ
                                                                                                                                                                                                            ,___,.                NOT AVAILABLE FOR                    NOT AVAILABLE FOR D"'""'
[n'l'C',I.)
a,.o,-..,                    &#xb5;ff)                                                                                              ('IWW)I IPl:IIIO~        &#xb5;ti)  --~
* WPS-2800 SERIES I
oOJll'UTON
                                                                                      ' ,._..,                                                                                          -          IOOTPUTON
                                                                                                                                                                                                      ....,.,,.. am
                                                                                                                  ~~
AIDl)"1 OUTl
                                                                                        ""'              our, ~                '                                                                  """
                                                                                                                                                                                                  ~
                                                                                    "  IITUTAOJ                                                                                                      TUTAOJ            OUT BV,Q(      *
                                                                                      ' ~'-"                            ,...__.,,.                                                                ' .,._,.,
POW'iRl<'
1  'L'\111 .....,.                                                                                              ttU*
                                                                                      '" OROlK)                                                                                                      ORCIJ!,D u
NOT AVAILABLE FOR I""'    ----*  -*-                  IOUTI'UTON                                                                            ""'  -----
                                                                                                                                                                                          ~
IOUTI'UTC><
NJDOOl<1 WPS--4000 SERIES ROlORF&A'l'IKlNI:>
                                                                                                                                                                                                                                                                          -""&deg;'
ALDOIN2
                                                                                        "'""""'                  '--                                                                                                      o.m OUTl                                                                                    J our,                                                                                      """                  our,                                                      *HV rl
                                                                                                                  ~
                                                                                        ..,..-r,w                                                                                                    llffiITTAOJ
                                                                                                                                                                                                      ,--c,,
                                                                                        "&deg;""'"'
                                                    &#xb5;ii 1'U VMr
                                                                                        <ml'\ITON
                                                                                                                                                                                &#xb5;ii    -
VIW IOOTPUTON ALD01<1 ALD0"2
                                                                                                                                                                                                                                                                        ~
YW.C1fl
                                                                                                                                                                                                                                                                                      "&deg;"' "UP COIi""'-"'
cw...,,..
cc<<..,.:,
                                                                                        "'""""'          am '--
OUTl f--
                                                                                        ....,..,,                                                                                                                                                                        -"""'      &deg;"'""""
                                                                ~ ..."&deg;"""""                                                                                                                ~
OUT    ~
l<TUTNJJ            OUT1 f--
ll1ROOI!
                                                                                        \Ml
_,..                                                                                            ttUU
                                                                                                                                                                                                *u POWiRl<'
WK[                                                                --- .        D C
nu
                                                                                                                                                                                                                                                                        ~
OROlH)                                                                                                      OROlH)
                                                    ,.., ----*                                __,..,,                                                                          &#xb5;.,
___,.,                                                        -  -*    A IOOTPUTON
                                                                                                                                                                                                  '  /OlfTP\JTON M.DJ)N2 OUT2 f--
                                                                                                                                                                                                    ' N..00"'1 ALD0"2 OUT2
                                                                ~=
                                                                                        ,.,..,.ADJ VMT
                                                                                                                  ~
                                                                                                                                                                                                      "115CAOJ
                                                                                                                                                                                                      ,_,._LP OUT\ f--
w::ur IWUOW..
                                                                                                                                                                                                                                                                                      *UV
                                                                                                                                                                                                                                                                                        ~
nu                                                                                      AC CJROU!<)
                                                                                                                                                                                                      """""'                                                                *oE DC
                                                    /JT).                            I AloA.Flia 1
                                                                                                                                                                                /JT)
MO'LFliRI YUUM Rll
                                                                                                                                                                                        ~-
                                                                                        <JUTJVrON                                                                                                    OJTP\STON
                                                            ...                                                                                                                                                                                                            ~
ALOIOIN1 AW<Ol<2 OUTl    -                                                                                  ALDOOQ am -                                                        ""'&deg;"
                              '                                                    ~
OUT1  ~
lWTAOJ              our, -
                                                                                        .-mlTNJJ ea,,e,..,
I
                                                                            't1.1-4illl I
1 ,..,,
                                                                                                                                                                                                      ""m,,y WAT CIAO.ND                                                                          """""-""""
                  ,..,                                                                  """'""                                                                                                                                                                                          (OPTQW.)
                                                    "'"',. ---    """                                                                                                                                                                                                              *UY uuI ; i. i!        i
                        ~j                        1'1> 1 . . , ,
                                                          ~-                                                                                  Ht ;I .Ii~ t iI    j
                                                                                                                                                                    ~
CiRCU<<)
                                                                                                                                                                                                                                                                                    <MO.IT
                                                                                                                                                                                                                                                                                    -=
    -  N "
* C i: ; ~ ~ II HH C  *            ~  ;:
HC
                                                                                                                                              - N " .
H ~ i i iii    n                                                                                                                      --
                                                                                                                                                                                                                                                                                    -=
                                                                                                                                                                                                                                                                                        ~
ii i .l I II!. ill ! : I l l In.ii .i i ! ...n.h. I I ii. .I~ i Iu~ ~                                                                                                ----        ((FTDWJ
                                                                                                                      . - ~"                    . -.                                -.                    --        .
                                                                                                                                                                                                                                    ~
                                                                                                                                                                                                                                    ~
I I u
                                                                                                                                                                                                                                          .. I- .~
                                                                                                        ! I~; ~iI ;
                                                                                                                                                                                                                                  ""'lu~nu~ =-~                        ~
                                                                                                    - N
                                                                                                                              ~
                                                                                                                                          - N                  ~          -  N            ~    ~                        C.
N  -
                                                                                                                                                                                                                                                                                    *UY
                                                                                                                                        ~!~, 1~1 1 ~ ; /Jfr;; ~ ! &#xb5;NJ~1gr~
                                                                                                                                                        -  0
                                                                                                                                                                                                                                                                                    """-N) m<
                                                                                                                                                                                                                                                                        ~ """""'
1.a,
                                                                                                                                                              ! if i;h~~~&l 1
                                                                                                                                              ~n Rm)
                                                                                                                                                                                                                                                                                    """""&deg;"
l:-1 i                                                                      -                                                ~
                                                                                                                                                                                                                                                              ~
llRO!OI(    ~
                                                                                                  /J1)
                                                                                                                                                                                                                                                                                  """"lmlW,CI;
                                            ..,_                          ~
                                                                                                *VIIAT
                                                                                                                                                                                                                                                                                          """"&deg;
~
IJTJ  1 BATTERY CHARGER                                                                                                                                                                                                        ;;; '      ---
                                                                                                                                                                                                                                                                    ~-          :;;.      P"TOW-)
    -IVO(
01--0285772--00
:l~1 CONTROL BOARD 02-01158702--00 CH<lJW<T ll<ULCH DlMl'OUT VBN J
                                                                                                                                                                                                                                                                    ~
CHCIW<T
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J.-.~~                                                                                                                                                                                            7 II                                                                                                                                                                                                                          -*-
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Section I: Overview of System Components a) Station Component ~ocations The WPS-2800 High-Power Voice and Siren System is comprised of 10 basic models:
Model            Driver Info                                                Cabinet
, WPS-2800-1      One (1 ), 400 Watt Driver                                  Type II WPS-2800-2      Two (2), 400 Watt Drivers                                  Type II WPS-2800-3      Three (3), 400 Watt Drivers                                TypeII WPS-2800-4      Four (4), 400 W~tt Drivers                                Type II WPS-2800-5      Five (5), 400 Watt Drivers                                Type II WPS-2800-6      Six (6), 400 Watt Drivers                                  Type II WPS-2800-6A      Six (6), 400 Watt Drivers                                  Typeill WPS-2800-7      Seven (7), 400 Watt Drivers                                Typem WPS-2800-8      Eight (8), 400 Watt Drivers                                Type ill WPS-2800-9      Nine (9), 400 Watt Drivers                                Typeill WPS-2800-10      Ten (10), 400 Watt Drivers                                Type ill Each system ess~ntially functions in the same manner as do the others. This manual will provide the necessary information to properly operate, program and diagnose this system regardless of specific model. If information relevant to a specific model is required, it shall be presented and noted as such.
T~e 2800 series systems are comprised of several major components common to all models, although quantities of some components will vary from model to model.
Fig. 2: Siren Cabinet Door Components WPS-2800-4                                                      WPS-2800-10 Typo I  Cobo,oi -  ta Ra6nnoo                                      Typoa1~si-.c-,1DrRa1oronce
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I~                  -
CD  Con!rol Board            &#xa9;-
              @  Radio or l.ancline Boord @*N:,~Cha'got
* SnnAmp1                  @b    8olor Blllloly Cho,gar CD*  Sno A1tl'.> 1    (DJ  S..., Amp    10 G)b SnnAmp2                  @-
(Db  S.ron Ml? 2      0--1 (De  Smln Amp    3    @bMotlort>oonl2
              @c  Biron AA1!I 3
              @d  8cranAA1p4(2800-4)      (j) -                              (j)d  &""1 Amp 4            Control Boord (De  Su-onAmp~        @,    Rodl:l,orl..andh-(Dt a.., Amp e        &#xa9;*    PC, ll8tloty C!wgor (Dg  8ffl'I Amp 7    @b    Sow Boilofy ci.,,gr (j)h s..n11mpe        @    Ammolor (j),  Shnllmp9        0-Page4
 
b) Station Components Defined Control Board - This component (located on the inside of the upper cabinet door) controls the key functions of the WPS4000 system including:
Tone Generation                                    Remote Activation Event Timing                                      Rotor Control Remote Station Status Reporting* (encoding)        Local Control System Diagnostics (incl. SI TEST)*
* optional equipment The control board contains a microphone jack for public address and a serial port to allow connection of a palm computer (hereafter referred to as a PalmPC) to the remote station.
The control board is also the location of the diagnostic LED's.
Siren Amps - These components (located on the inside of the upper cabinet door) receive the desired tone or message generated by the control board, amplify it and deliver it to the siren driver.
Siren Driver - This component (located in the speaker a~mbly) produces the desired audible tone or voice message.
Radio or Landline Board (Optional) - This component (located on the inside of the upper cabinet door) receives signals from either the antenna or landline and delivers them to the control_ board for processing. Through the use of the included radio, the station is also capable of transmitting status information back to the control center.
Motherboard - This component (located on the inside of the upper cabinet door) distributes Battery Voltage and signals to all system components that require this voltage. The motherboard is fused @10 Amps to protect all connected components EXCEPT for the siren amplifiers and the rotor (they contain their own fuse). The 2nd motherboard (WPS4000-8 only) is also fused @10 Amps. The Motherboard also distributes signals between the amplifiers and the control board.
AC Battery Charger-This component {located on the inside of the lower cabinet door) uses 110 VAC (or 220 VAC) single-phase service to maintain the stations batteries at their proper voltages.
Page5
 
Solar Regulator (optional) - This component (located on the inside of the lower cabinet door) uses electrical energy collected by a pole-mounted solar panel to maintain the station batteries at their proper voltages.
Ammeter - This component (located on the inside of the lower cabinet door) provides a visual indication for the charge current flowing into the batteries from the charger or regulator.
Voltmeter - This component (located on the inside of the lower cabinet door) provides a visual indication of the DC voltage across the ~atteries.
Auxiliary Control Status Board (optional) - This component (located on the right inside wall of the upper cabinet) is wired to remote switches to facilitate remote operation of a specific siren station.
Batteries - These components (located on the inside of the lower cabinet) provide the 28VDC necessary for the system to operate.
Battery Disconnect Switch - This component (located on the rear inside wall of the upper cabinet) allows all system batteries to be completely disconnected from the system. NOTE:
This switch does not disconnect the batteries from the battery charger or regulator.
Antenna Poly Phaser (optional) - This component suppresses high-voltage (static) charges that could be present on the antenna.
Antenna (optional) - This component (located on the utility poie) is capable of either receiving signals broadcast from the control center (one-way) or can both transmit and receive signals to and from the control center (two-way), depending how the system was ordered.
Solar Panel (optional) - This component (located *on the utility po*e) collects solar energy, converts it to electrical energy and delivers it to the Solar Regul!ltor to maintain the station batteries at their proper voltage.
Page6
 
Strobe Control Board (optional) - This component (located on the rear inside wall of the upper cabinet) is a user-defined device that controls a pole-mounted strobe light. This light can be configured to activate during specific conditions (example: when any tone or message is generated).
Intrusion Alarm (optional) - This sensor (located on the door jam of the upper cabinet door) detects the opening of the cabinet door. If the station is equipped with this option, the alarm is configured to transmit a signal back to the control center.
Page7
 
Section II: System Operations a) ~emote Operations Remote operation of a WPS-l800 series siren involves transmitting signals from the_ control center to the desired station. This is accomplished by using either an encoder and transmitter or, if the station is so equipped, using an auxiliary control status board- that has been wired to switches/controls at the control ~nter. Remote operation is beyond_ the ~pe of this document and will therefore not be addressed. IT your system is equipped with an encoder, please ~fer to the encoder* operating manual for information regarding remote operation. If your station has been wired to use the auxiliary control status board, refer to the reference materials provided by the electrical e~gineer Qr installer.
b) Local Operations Local operation is accomplished thry>ugh the control panel on the front of the station cabinet. The functions of these controls are as .follows:
Cancel                Abruptly stops siren tones without the normal "ramp down" found in several tones. Helpful in the event of an accidental tone activation.
Wail                    Pl'.()duces a slow rise and fall tone.
Attack                  Produces a faster rise and fall tone (used for designated Civil Defense National Attack tone).
Alert                  A steady tone (Civil Defense alert).
Whoop                  A repetitive rise-only to~e:
Hi-Low                An alternating two-tone sound.
Air Horn*              A pulsing air horn sound.
I SI TEST              Initiates SI TEST@ tone and th*e* optional diagnostic SI TEST. r:outine.
Xmit Carrier          Actuates ~mot~ station radio transmitter PTT circuit.
When tone squelch is used with ithe transmitter, the transmit function is used when adjusting tone squelch modulation.
Page8
 
Xmit Audio      For use with remote station radio transceiver, causes transmission of DTMF tone via RF link for tone modulation adjustment. The transmit tone level is adjusted with the transmit audio potentiometer located on the controller board (see "Fig. 4: System LED Diagnostic Indicators" page 28).
Xmit Status    Transmits stati9n status information and battery voltage to the control center.
DVMTest        Activates the Digital Voice Message (DVM) assigned to the test procedure in the configuration software.
Rotor CW        No function with 2800-series equipment.
RotorCCW        No function with 2800-series equipment.
Keypad Arm      Enables local station operation* via keypad. Once pressed, the keypad remains active until either a) another keypad button is pressed, or b) 60 seconds have elapsed, whichever comes first. The Keypad Arm button must be pressed each time a keypad button is to be pressed. Note that the Cancel button is always enabled and does not require Keypad Arm to be pressed.
Fig. 3: Station Control Panel Page9
 
Section III: Understanding Station Addressing Every Siren Station in a given area code has its own, unique "Station Address". This address allows the user to select an individual or a group of stations. As stated elsewhere in this manual, a valid station address can be any number from 00()0 to 9999. This allow~ for 10,000 unique addresses; a staggering number of stations to keep track of. Although it is logistically impossible to have that ma~y stations in a single area code, it does illustrate the importance of a sensible, intuitive numbering convention for station addresses. This section will outline two types of conventions Central Point Source: Quadrant, Sector, Radial & Station Frequently, warning systems are used to notify the public of emergency situations that may occur from a single, centralized location. Typically, siren stations. , would be located throughout a 360&deg; area surrounding this location for a specified distance from the source. In this scenario, the Central Point Source convention would be well suited.
For illustration purposes, assume the siren stations are installed within a 5 mile radius of the Central Point. As such, a Quadrant, Sector, Radial & Station numbering convention would allow the selection of any of the followin~:
* any siren station
* all siren stations
* any one of four sectors
* any one of 5 radii within the sectors The area of coverage 'in this system, a circle, is divided.into 4 quadrants. Each quadrant is then divided into 4 sectors. Each sector is further divided into 5 segments or radii emanating from the center of this siren system.
4                1      4 3                2      3 QUADRANTS 1-4        QUADRANT SECTORS 4                1 3
                                &#xa9; RADII          INDIVIDUAL STATIONS Page 10
 
In this system, a stations address is structured as follows:
l!.w1        Allocation 1          Quadrant (1 to 4) 2          Sector (1 to 4) 3          Radii (1 to 5) 4          Individual station within a radian Here are some sample activations to further illustrate this concept.
Sample 1:
A station with address 1354 would be located in:
Quadrant:      1 Sector:        3 of Quadrant 1 Radial:        5 Station:      4 If an operator selects station 1-3-5-4, only that station will be selected, as shown.
SINGLE STATION SELECTION STATION 1354 Page 11
 
Sample 2:
lf the activation of a group of remote stations within a whole segment of a radius within a quadrant and sector is desired, the fourth digit address is substituted with a "Wild Card",
the "#" pound sign.
An address selection of 1 4 - # would activate the system as follows:
Quadrant:      1 Sector:        3 of Quadrant 1 Radial:        4 Station:      # All stations defined by above This selection is shown below.
                                                                        \
GROUP SELECTION-RADIAL SECTOR GROUP 134#
Page 12
 
Sample 3:
Selection of an entire sector can be accomplished by using the following address:
Quadrant:      1 Sector:        3 of Quadrant 1 Radial:        # All radial 1 - 3 Station:        # All stations defined by above In selecting a sector, the first two digits of the address are set for the sector address, for example 1 - 3 (Quadrant 1 - Sector 3). The third and fourth digits are substituted with a #
(Wild Card). Therefore, the address to select all stations in sector 1-3 is 1 # - #. This selection is represented below.
* GROUP SELECTION-SUB-SECTOR GROUP13##
Page 13
 
Sample 4:
The selection of a complete quadrant can be achieved by using the following address:
Quadrant:      1 Sector:        # All sectors of Quadrant 1 Radial:        # All radials in all sectors of Quadrant 1 Station:      # All stations defined by above When selecting a quadrant, the first digit designates the Quadrant (1). the second, third and fourth digits are replaced with Wild Cards (#,#,#). Therefore, the address for selecting all stations in quadrant 1 is 1 - # - # - # as illustrated below.
                            /      /
I GROUP SELECTION-QUADRANT GROUP###
Page 14
 
Sample 5:
All stations in a system may be accessed by using the Wild Card(#) for all address numbers.
The address would be# - # - # - #.
Quadrant:      # All Quadrants Sector:        # All sectors of all Quadrant Radial:        # All radials of all sectors of all Quadrants Station:        # All stations defined by above This "All Call" is illustrated as shown.
GROUP SELECTION-"ALL-CALL" GROUP####
Page 15
 
Governmental: County, City & Station For this next type of address structure, assume that the siren system in question is used primarily for tornado warnings throughout a major population center. This center encompas~es three counties with each county having no more than ten cities. Two cities contain more than 50 high-power voice and siren stations.
The following represents a Governmental System 4-digit address configuration, allowing activation by." All Call", county group activations, city group activations an<J indi".idual station activations:
X              X              X                X
: . _. ......... : ........... Individual Siren Station (0 .: 9)
: ........ ; .................. ~ ....... City (0 - 9)*
: ..................................*.....*..... . County (0 - 9)
*One digit could also be reserved for unincorporated areas.
An address of 2 4 - 5 would indicate the following individual station:
Siren Station 45, in City 5, in County 2.
The Wild Card (#) permits the use of several different types of group activations. Three samples follow:
Sample 1: County Activation (1 - # - # - #)
All Siren Stations in all Cities in County 1 will be activated by this transmission.
Sample 2: City Activation (1 # - #)
All Siren Stations in City 5 of County 1 will be activated by this transmission.
Sample 3: System All Call(# - #- #- #)*
All Siren Stations in all Cities in all Counties will be activated by this transmission.
Page 16
 
Section IV: Troubleshootin,:
Audio Loss If after activating the siren there is no audio output, perform the following procedure step by step. This procedure will require a digitai multimeter.
: 1.      Locate the Audio Presence LED on the controller board (see "Fig. 4: System LED Diagnostic Indicators" on page 28). When audio is present on the board, this* LED will be on.
: 2.      Activate the WAIL siren tone from the control panel on the siren cabinet. Confirm that the Audio Presence LED is on. H this LED is not on or if it turns off quickly, measure the battery voltage. The siren will not activate if battery voltage drops below 19 VDC. Be sure to measure the battery voltage at the same time you activate the siren. The batteries may show a good float voltage while they are not under load, but upon activation, the battery voltage may drop below 19 VDC if their capacity is low.
Note that when the siren shuts down and the load is removed from the batteries, the voltage may rapidly return to 25 VDC or more. If this condition is occurring, the batteries will need to be replaced. If the voltages are in the normal range, proceed to step 3.
: 3.      Locate connector J2 on the control board. With your multimeter set to AC volts, measure across pins 6 and 7 {White with Orange stripe and White with Brown stripe). With the siren tone running, 5 VAC should be present. If no voltage is present, the controller board is probably at fault                                        _
NOTE: Confirm that the audio presence LED is on while performing these measurements. It indicates that the siren controller is still activated. If the specified voltages are present, proceed to step 4.
: 4.      With the siren tone still active, ~easure across pin 1 (Blue wire) and pin 2 (Black w/
White trace) on each of the siren amplifiers. 5 VAC' should be present at each amplifier. If so, proceed to step 5. If no voltage is measured, this is indicitive of a wiring problem between the controller board and the siren amplifiers. Check the wiring between these components
: 5.      Remove the Red siren driver lead from each siren amplifier. Press "Cancel" on the control panel and then press "Wail". Measure across the output of each amplifier (White Weco connector) with the siren driver disconnected. 70 YAC should be measured. If this voltage Ieve is measured, proceed to step 6. If this voltage level is not found and 5 VAC was measured at the input, proceed to step 7.
: 6.      Set your meter to measure resistance at its lowest scale. Measure across each of the speaker drivers, making sure that at least one wire of each driver is removed from the power amplifier (or else the transformer in the amp is being measured as well).
EachI driver should have a DC resistance of approximately 3 Ohms +/- .3 Ohms. If a resistance value outside of this range is found, contact factory.
Page 17
: 7.      Set your meter to measure DC Volts. Connect the negative lead of your meter to ground (one of the solid black wires in the multi-position connector on the amplifier is a good ground source). With a siren tone activated, measure the following wires for the following voltages (approximately):
Grey                  6 VDC Brown                SVDC Solid White (all)    24VDC AC Battery Charger The AC-powered battery charger has two charging modes: Equalization Mode and FloJlt ChaFge Mode. The charger is in equalization mode when AC power is first applied; the charger will stay in equalization mode until the battery voltage reaches approximately 31.5 VDC. Once the battery voltage reaches that point, the charger will switch to float voltage mode. In that mode it will charge the batteries to the appropriate voltage relative to the temperature or the batteries (25 to 29 VDC).
The AC battery charger contains two circuit boards positioned on either side of the large transformer. One of these boards contains a single, green LED, while the other board con-tains a pair of LED's, one green and one yellow. This pair *or LED's provides diagnostic information for the battery charger. The following chart defines their various diagnostic states.
Solar Regulator The following procedure can be perfonned to confirm proper operation of the solar regulator:      *
: 1.      Disconnec.t the solar panel from the charger. With a DC voltmeter, measure the voltage across the wires coming from the solar panel The voltage should be greater than 32 VDC (NOTE: The solar panel must be in direct sunlight).
: 2.      Reconnect the solar panel to th~* charger. Monitor the battery voltage with the cabinet voltmeter. The float v~ltage will vary between 25 to 30 VDC, depending on battery temperature. When the solar regulator is charging, the DC LED on the circuit board will be on. During normal operation the charger will cycle on and off.
The float voltage will vary with battery temperature. The following is a brief description of the normal charging cycle:
Page 18
 
If the float voltage for the current temperature of the batteries is 26 VDC, the regulator will turn on at 26 VDC (LED will come on) and it will charge the batteries to 28 VDC. Once the battery voltage reaches 28 VDC, the regulator will turn off (LED will go oft), and the battery voltage will be ~llowed to drop to 26 VDC.-The cycle would then repeat itself. If the float voltage was 27 VDC, it would cycle from 27 VDC to 29 VDC.
Green LED                                Yellow LED OFF                          Not Working                              Normal Condition FLASHING                      Serial Communications Failed            No Thermistor or Thermistor is bad ON                            Charger Operating Properly              Equalization voltage mode When AC power is applied to the battery charger, the following voltag~ should be measured on the wires coming off the charger:
Note: Refer to "Fig. 1: Station Wiring Diagram" page 3.
Pin 2 (Black)
                      ~I      g::==                      (BC-1 )Two-Position Connector -
Pin 1                                      Charger output wires (25 to 32 VDC)
(White)
Pin 2 (Grey)  Q[J I b=                            (BC-2)Three-Position Connector -
19 VDC from Grey to Ground Pin 1                                      (Black wire in BC-1)
(Orange)
Socket 1 (Red)
          =i.==:i-p~1 [JeJ                                (BC-3)Two-PosrtJon Connector -
Battery Voltage to ground (Black wire in BC-1) Note:On/y when the siren is powered up.;
this is sourced from the siren motherboard.
Pin 2 (Black/White)
(BC-4)Two-Position Connector -
Pin1 (Blue) go                                  No Connection I Not Used Page 19
 
Digital Voice
: 1.      Remove all amplifier fuses.
: 2.      Install an 8 ohm speaker at amplifier audio input connector pins 1 and 2 (Blue ap.d Black w/White wires) in the 16 position connector.
: 3.      Select a siren tone by pressing one of the controls on the front panel.
: 4.      If the tone can be heard through the s~ker, press the DVM-Test control to play the predesignated message.
Partial or Full Diagnostic Failure This procedure is to be used if the Partial or Full diagnostic LED (located on the controller board) indicates that a problem_ has been detected. A Partial indication means that at least one speaker and/or*amplifier is operational. A Full indication means that all speakers and amplifiers are operational; NOTE: In order for a good Full indicator to be valid, a good Partial indicator must also be present).
: 1.      Connect the PalmPC to the siren station via the com port on the front of the siren cabinet control panel.
: 2.      Display the "Status" screen on the PalmPC.
: 3.      Press the SI TEST *control on the front control panel.
: 4.      Each amplifier contains a red LED that is visible on the front of the control panel.
Note if all the LED's are on. '.fap the "Update Status" button on the PalinPC and note wh;ch amp is displaying an error.
: 5.      Open the front panel and swap the speaker driver wires from the amplifier that indicated a failure, with an amplifier with a lit LED. For example: if the L_ED for amplifier 1 is the only LE~ not on, install amplifier 1 speaker'wires onto amplifier 2 and install amplifier 2 speaker wires onto amplifier 1. This will diagnose if it is the speaker or the amplifier that has failed. You may also measure the DC resistance of the speaker driver with your ohm meter. Be sure that the*speaker driver wires are disconnected from the amp prior to measuring. A good driver will read 3 ohms +/- .3 ohms.
* Page 20
 
Section V: Maintenance Although The WPS-2800 is of a dependab.le, solid-state design, periodic activation, field inspection and preventive maintenance is recommended to insure the maximum performan~e of each station.
Frequency of Testing and Activation A system of twice-monthly activation and *confirmation, combined with a quarte~ly service and preventive maintenance is recommended to help insure the successful performance of a station. Increasing the frequency of testing will support and improve a station's test record.
Stations located in environmentally adverse locations will require inspection and preventive maintenance at more frequent intervals than just discussed. Stations should always be inspected following severe storms.
If a station is activated by remote control (landline or radio), the twice-monthly activation should be performed using the remote control link.
The twice-monthly activation of a station can be confirmed by several different methods, depending upon the options selected with each Whelen System.
Local Site Confirmation For a basic station activated at the cabinet, or by landline' or radio, -have an' observer confirm that the station activated audibly. The observer should report successful as well as failed station tests. Station Performance Logs should be maintained. It is important to understand that audible_*confirmation alone is not assurance that the station is operating at 100% power. This requires inspecting the station in greater detail.
Stations '1}ay be optionally equipped with counters that advance upon radio or tone generator activation. These counters do not confirm total operation or the fmal expected output of an outdoor warning device.
If a station is equipped with SI TEST diagnostics (optional), the station's activation may be confirmed using SI TEST or full power siren mode. Following an activation, SI TEST displays its informatjon OQ control board mounted LED's or through a LED display board visible on the right side of the cabinet. Fig. 17 shows the location and function of the LED's on the control board. The cabinet mounted display board LED's will confirm the following (from Left to Right):
Red            AC Power 1
Yellow        DC Power at minimum proper operating level Red            Partial Amplifier and Speaker Driver Operation Green          Full 'Amplifier and Speaker Driver Operation
?Red          Rotor Operation Page 21
 
Following activation and observation the results should be noted in the performance log.
Any indication of incomplete operation presented by the LED indicators should prompt Il\rnEDIATE service attention.
The SI TEST system retains information until cleared by a specific command.
The SI TEST information stored at the station, if not cleared, will update itself automatically with subsequent SI TEST activations.
Remote Monitoring and Confirmation Stations equipped with the optional Whelen COMM/STAT' Command and Status Monitoring control, allow remote monitoring 'of status as well as confirmation of system activation. COMM/STATJ'M returns the results of a remote station activation (both SI TEST and siren warning mode) in a DTMF en~oded format via radio link.
Remote monitoring by RF link eliminates the necessity of physically visiting a station to confirm an activation.
Following the activation of a station, a "Status Request" may be sent to that station by DTMF encoded radio command. Diagnostic SI TEST information is then presented to the status encoder at the station, cop.verted into DTMF code and transmitted back to the control center, where one of several COMM/STA'fTM base station products will convert the DTMF code into meaningful information.
Quarterly Maintenance Developing a quarterly inspection and preventive maintenance program for an outdoor warning station requires a thorough &#xb5;nderstanding of all the elements and expectations of the system. The following section provides an overview and basic guideline for quarterly station inspection and prevenfr~1e maintenance program for the sample station.
Page 22
 
Visual Siren Station Physical Inspection
* Observe the spea~er cluster, siren cabinet and AC Service for any signs of damage or loose mounting hardware (Some shrinkage of a newly treated utility pole may occur in the first several years foJlowing installation, requiring the tightening of mounting hardware.
* Check all conduit for watertight connection and entrance into the siren cabinet.
* Inspect the AC Service for damage, blown fuses, degraded (corroded) power connections and integrity of the lightning arrestor.
* Inspect the grounding system for AC Service, Siren Cabinet and pole top equipment.
Verify connections and acceptability of earth ground.
* Observe the pole for any shifting and/or leaning. Poles that are not plumb will not properly direct alerting sounds.
* Examine entire station for any signs of vandalism or forced entry.
Siren Cabinet and ~omponents
* Inspect AC Outlet, fuse and surge suppression equipment. Examine system for infiltration of foreign material(s), rodents or other pests.
* Inspect and, if necessary, clean all drain holes and vent screens.
* Inspect battery terminal connections and clean if necessary. Re-apply silicone coating to battery terminals if necessary. Observe battery voltage with siren in inactive state (AC power must be on to station, otherwise station must be powered up to observe meter).
* Examin,e all wiring harnesses for chafing. Verify wiring terminations for tightness and wiring connections for proper electrical connections. Replace and correct any corroded or marginal connections. Inspect antenna for proper connection.
Speaker Assembly and Pole Top Equipment NOTE: Any examination of Pole Top equipment should be performed with the station audibly disabled.
* *Inspect speaker for blockage by rodents, pests or other foreign material. Clean if necessary. Inspect any wiring cables or harnesses for chafing. Inspect the siren driver compartment for infiltration of foreign materials, rodents or pests. Clean if necessary.
Confirm that the driver compartment will allow for water or moisture drainage. Inspect speaker wiring connections for any sign of corrosion.
Page 23
* Verify tightness of all mounting hardware.
* Check all wiring term"inations and connections.
* Verify lubrication of the rotor gear train. The recommended inspection interval is initially 6 months. Following the initial two ins-pections, the owner may determine if a longer inspection- interval is acceptable. Varying weath_er conditions will affect this interval. Many stations are located in areas of the country where an annual inspection/
lubrication interval is acceptable.
Station Performance Testing NOTE: Depending on loc:al conditions and station options selected, the station may be tested on or off line. Off line testing of the station involves disconnecting the ~peaker drivers from the siren amplifiers, so as not to disturb the public when verifying tone,gen*erator operation. A co~lete test must, however, indude the testing of the siren amplifier operation. Th'/s can be accomplished inaudibly on units equipped with SI TEST.
Other units must be audibly tested.
* A basic routine, verifying the performance and operation of the sample statjon previously described, would be as follows:
: 1. Local and Remote Activation -
Activation of each remote station function by local control and remote control. W~th amplifiers on and off line as needed. An examination of each activation function will also facilitate a verification of re~ted and subsequent system module activations and
      .electrical connections that would be caused by an activation_ command. Also confirm function time outs (ex.: does the Alert signal time out at three minutes as per user specification?)._                *
: 2. Resp<<;>nse to Station Address and All Call address programming -
Control *Center reception and activation on SI TEST or non-tone activation, for individual station address and All Call address selection.
: 3. Public Address -
With the station on line, activation of PA for both local and remote control, verifying PA Audio path and proper set up level of volume. Verify AC drop out on PA.
: 4. Siren Amplifiers -:
Inspect for complete operation with speaker drivers (observe LED's).
Page 24
: 5. SI TEST Station Analysis -
Observe and confirm diagnostic status of:
AC DC Partial Amplifier & Speaker Driver Operation (disable one amplifier to confirm this test).
Full Amplifier & Speaker Driver Operation NOTE: Verify AC drop out during SI TEST mode.
: 6. Battery Charger Operation -
Observe for proper charging operation.
Verify AC drop out in PA or SI TEST mode.
: 7. Batteries -
Verify voltage stability under load.
Perform. a load test.
: 8. Status Encoder -
Perform a diagnostic SI TEST of the station.
Compare status information with observations made locally at the station.
Disable one speaker and verify that the "Full" LED indicator is off.
Disable AC and verify that the "AC" LED indicator is' off.
Compare battery voltage return status with observed and measured battery voltage.
: 9. Transmitter -
Check status encoder DTMF tone level modulation with transmitter.
Check transmitter set up.
Verify power output and SWR.
NOTE:On concluding any examination of a station where connectors have be~n opened and closed , a final rad.io test by either SI TEST or full power should be performed and the results observed for a complete successful tesl The PA audio path should also be audibly verified by sending PA and broadcast a voice message.
The following is a sample form that may be used for quarterly inspection and maintenance.
Page 25
 
MAINTENANCE CHECK LIST Station#: _ _ _ __                  Siren Address: _ _ _ _ _ _ _ _ _ _ _ __
Installation Date: _ _.,___....___  Inspection Date: _ _ _ _ _ _ _ _ _ _ __
Inspector: _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ __
PHYSICAL INSPECTION:
QK  NOT OK              COMMENT Mounting Hardware Speaker Assembly AC Service Proper Grounding Solar Panels*
Antenna*
Conduit Connections Siren Case Assembly Batteries Components Secure Harnesses LOCAL OPERATIONAL TESTING Battery Voltage Manual Test:
Clear Wail Attack AJert Airhorn Hi-Lo Whoop Clockwise Counter Clockwise (SI TEST):*
ACLED DC LED Partial LED Full LED Rotor LED          _
Timer Set LED Audio Present LED Microphone Mic Volume Page 26
 
MAINTENANCE CHECK LIST (continued)
Radio*:
                    .QK    NOTOK        COMMENT Squelch Control Sensitivity Antenna Toned*
Transmit LED Remote Activation:
Clear Wail Attack Alert Public Address Airhorn Hi-Lo Whoop Wail/ 5 Sec.
All Call Speaker LEDs:
1 2
3 4
5 6
7 8
9 10 SI TEST:
AC DC Partial Full Status Request Intrusion*
*Optional Page 27
 
Fig. 4: System LED Diagnostic Indicators 0
0 P1 9 POS "D" 0                      0 J9 0
MIC. JACK
                                                                        ,~
0 DO NOT ADJUST
                                                                                                                    @)            0 Transmit Audio D  Remote Audio Adjust (FOR USE ONLY WITH MOSCAD)
Adjust                "'~
m
                                                                                                                                    ;o iii U)
D Local PA                                                      D OI.II NOT      -
Adjust ADJUST        j GJ      Audio Presence (RED) - Normally off. This LED will light when an audio signal is present on the board .
                                                                <ID  Partial - Normally on . If all siren amplifiers do not operate properly during a lone activation or SI TEST, this LED will (D
be off. If at least one amplifier operates
: 12)      PTT - Normally off. This LED will light when            properly, ii will remain on .
the station transmitter is active.
I[}  Full - Normally on . If a siren amplifier does not operate properly during a tone activation
    @        Squelch - Normally off. This LED will light or SI T EST, this LED will be off.
when the station is receiving a radio broadcast . If equipped with the optional        1'[  Rotator - This LED will light during siren receive tone/squelch tone , the LED will activation if the rotor oscillates properly.
only light when the receive frequency and sub-audible tone squelch frequency tone is detected.                                ~-    Active - This LED normally flashes at a rate of once every half seconds. When a problem has been detected , this LED (1)      AC - Normally on . If no DC voltage was                will stop flashing or be off. Also indicates detected during a siren tone or SI TEST,              receipt of DTMF data by flashing at a this LED will be off.                                  faster rate for about 1 second .
(i )    DC - Normally on . If no DC voltage was          j_g)  Fault (R ED) - Normally off. When a detected during a siren tone or SI TEST,              problem has been detected , this LED this LED will be off.                                  will be on.
NOTE: In some instances, optional circuit boards may be located directly above these LED's.
0
~ - - --  15,r'-'-
1 _ _ _ _ _ _ _ __.,,
AUXCS                      SPARE                                STROBE 0
Page 28
 
YlltELEM ENGINEERING COMPANY INC.
51 Winthrop Road Chester, Connecticut 06412-0684 Phone: (860) 526-9504 Internet: www.whelen.com Sales e-mail: lowsales@whelen.com Customer Service e-mail: iowserv@whelen.com Lt. WARNING : This product can expose you to chemicals including Methylene Chloride which is known to the State of California to cause cancer, and Bisphenol A, which is known to the State of California to cause birth defects or other reproductive harm. For more information go to www.P65Warnings.ca.gov.
WPS-2900 SERIES HIGH POWER VOICE
                  & SIREN SYSTEM OPERATING & TROUBLESHOOTING MANUAL
&#xa9;2005 Whelen Eng ineering Compa ny Inc.
For warranty information regarding this product, visit www.whelen.com/warranty Form No.13948F (050911)
 
Table Of Contents Section I:      Overview of System Components a) Station Component Locations .......................................................................... page 5 b) Station Components Defined ............................................................................ page 6 Section II:    System Operations a) Remote Operations ............................................................................................ page 9 b) Local Operations ............................................................................................... page 9 Section III:    Understanding Station Addressing Central Point Source .............................................................................................. page 11 Governmental ......................................................................................................... page 17 Section IV:    Troubleshooting Audio Loss .............................................................................................................. page 18 Solar Regulator ....................................................................................................... page 19 AC Battery Charger ...............................................................................................        page 19 Digital Voice ............................................................................................................ page 21 Partial or Full Diagnostic Failure .........................................................................              page 21 Section V:      System Maintenance Frequency of Testing and Activation ....................................................................                  page 22 Quarterly Maintenance .........................................................................................            page 23 Visual Siren Station Inspection .............................................................................              page 24 Siren Cabinet and Components ............................................................................                  page 24 Speaker Assembly and Pole Top Equipment .......................................................                            page 24 Station Performance Testing .................................................................................              page 25 Maintenance Check List ........................................................................................            page 27 Illustrations Fig. la: Station Wiring Diagram (designations) ............................................................................                page 3 Fig. lb: Station Wiring Diagram (voltages) ...................................................................................            page 4 Fig. 2: Siren Cabinet Door Components ........................................................................................            page 5 Fig. 3: Station Control Panel ........................................................................................................... page 10 Fig. 4: Central Point Source Divisions ...........................................................................................        page 11 Fig. 5: Single Station Selection ........................................................................................................ page 12 Fig. 6: Group Selection - Radial Sector ..........................................................................................        page 13 Fig. 7: Group Selection - Sub Sector...............................................................................................        page 14 Fig. 8: Group Selection - Quadrant ................................................................................................        page 15 Fig. 9: Group Selection - All-Call .................................................................................................... page 16 Fig. 10: Solar Regulator Connector Pin-Outs ................................................................................              page 20 Fig. 11: System LED Diagnostic Indicators ...................................................................................              page 29 Fig. 12: Control Board Wire Colors ...............................................................................................        page 30 IMPORTANT! THIS MANUAL ASSUMES THE READER/TECHNICIAN HAS AN INTERMEDIATE TO ADVANCED LEVEL OF PROFESSIONAL TRAINING IN THE FIELD OF ELECTRONICS.
Page2
* No t availa bl e far                              ** No1 avall1bl a for WPS -4000Serl es                                    WP S *2900Sarlaa
                                                                                                                                                                                                                                                                                                                =
MOTHERBOARD                                                                                                                                                                                                                                                    RolOfRilldy8o.wd                                      SIIObe Boan!
AMPLIFIER 5            SHOWN FOR REF                                                                                                                                                          (WPS-4000SeriesJ"'                                        (op!X)n;)I)
(WPS28;::;;:riSER1ES)              (JII)            * *-- - -        9    /Outpu10n I
                                                                                                                                                                                                                                                                                                                                                                                    ~
(JII}                      9  /OU TPUT ON                      \TYPICAL) 2  BLU            2  AUOIO IN 1                                                                                                  2  BLU                  2      AudlOln 1 BLJ</INHl      1  AUDIO lN2                                                                                                    1 BLKIWHT                      Audloln2 OUT2 r,
                                                                                                                                                                                                                                                                                                                                                                              ~
BRN            J  BIAS                                                                                                        l BRN                            Bias ORG                1n        SlTESTAdj          oun                                        (J3)
ORG            10  SITEST ADJ GRY YEL 4
5 POWER UP IPA RELAY SPEAKER DRIVER GRY YEL 4
5 Power Up
                                                                                                                                                                                                                                          /PARelay                          RED            '&sect;SVR*a                                                                                ),,,a WHT      1\ 13.lS  VBAf                                                                                                            WHT        1113 15          VBAl                              BRN            2  Powe1 Up BU<      12 14 16  GROUN D                                                                                                        BLK        12. 14.16        G,olA'l,(I                        ORG            3  CCW Relay
                                                                                                                                                                                                                                                                                                                                                                                    ~
                                                                                                                                                                                                                                                                                                                                                                                --o*
YEL            4  CW Relay (J2)
GRN                CCWM,cr-o
                                                                                            ~
5 (JIO} I 6  WHTIGRN        9  /OUTPU T ON                                                                                        (J IO/ 6    WHTIGR N                    IOU'tpul On                        BLU            6  CW Micro                                                                          rJ).
GRY            7  Strobe          (J1) 2  8LU            2  AUDIO IN\                                                                                                  2 BLU                    2      Audlo ln1
                                                                        =                1                                                                        j _j    ]  J J                        1 BUv'WHT                1    Audl01n2                          WHT            8  BITD                                                    OigllalVoice              ~
Bu<MHT            AUDIO IN2        OUT2                                                                                                                                          OUT2 3 BRN                    l      Bla1                              WHIIBLK        9  BITC                                      ~ I) 7                1~  ::~:ST AOJ        OUT1                                                    I                                7 ORG                  1u        SITES r Adj        oun            WHT~ED        10  811 8                                                *12V 4  GRY            4  POWER Uf'                                                                                                  4  GRY                          PCMlerUp
                                                                                                                                                                                                                                                                                                                                          .IDJL..1...Jo.ouna
                                                                                                                                                                                                                                                                                                                                                                                =
5  YEL            S  IPA RELAY                                                                                                      YEL                          IPA Relay                          WHT/ORG      11  BIT A WHT      11 13 15  VBAl                                                                                                            WHT        111315          VBAT                                                                                            GRN 3      DVMOut BLK          t2  Ground BU<    ~ GROUND                                                                                                                    BLI(      12.14,16          G,Ol.lf\d                                          ,_______.                    -----B,,-LK-:-:;i    4    MSG Start
                                                                                                                                                                                                                                                                                                                                                                                  ~
BRN 5      MSGActlvel
                                                                                                                                                                                                                                                                                                                            ----,,-R::;:E;;-0-;6      Se,ialCt.4}
                                                                                            ~                                                                                                                                                  AMPLIF IER 8 16
                                                                /J9J      WHTIGRN        9  ,ou rPU1 ON                                                                                        (J9)    8  WHTIGRN              II    /OU'tpu! On
                                                                        = ,~ :~:sr 2 BLU              2  AUDIO IN 1                                                                                                2 BLU                    2      Audloln 1                              RED "
* 1 i---                                                      Radiolnlerlace 1 BLKIWHT                      Audio In 2
                                                                                                                                                                                                                                                                                                                                                                                  =
BLK/'M-H        I  AUDIO IN2        OUTI                                                                                                                                                              BLK***    2 l BRN                            BIiis              OUT2                                                                                        (Optional)
ADJ      OUT 1                                                            T                            ORG                1n        SITESTAdj          oun                BRN        3  Strobe
                                                                                                                                                                                                                                                                                                                              ~
                                                                                                                                                                                                                                                                                                                                                                              ~
4                                                                                                              4 GRY                    4      PCM1111Up GRY                POWER UP 5 YEL                    5      !PARelay BLU        4  BITD                                    ~
YEL            5  IPA RELAY 31 S~~
WHT      11.1315    VBAT                                                                                                          WHT        11 .13 15        VBAl                                  GRN            BITC t            VIO        Ch Gram
                                                                                                                                                                                                                                                                                                                                                                                    ~
                                                                                                                                                                                                                                                                                                                                                                                  ~-
BU<    12 1'. l6  GROU ND                                                                                                        ~K        _1l_J_4 ,16        Gror.w:I                              YEL            BITB          j(J2)                        YEL
* ORG        7  BITA                                      GRN 5      TXA.ur:tlo
                                                                                            ~                                                                                                                                                                                            _e_
t AMPLlflER7                      GRY            CCWMICfo                              WHT~ED 6 1 *24VOC (JBJ I6 2
WHTIGRN BLU 9
2 1
ourPur ON AUDIO !N1
                                                                                                                                                                                                /JBJ  16    WHTIGR N 2 BLU 9
2
                                                                                                                                                                                                                                        /Output On Audio In 1 VIO RED 3-10 CW MICro SwUCh&d *24VDC I
BLK
:~~
7
:1~:Cc Gmlllld
                                                                                                                                                                                                                                                                                                                                                                              ~
1 BLKIWHT Bu<JWHT 1
AUDIO !N2        OUT2
                                                                                                                                                                                                                                    ' ,., Audioln2                              BU<      1\  GrOU'ld
                                                                                                                                                                                                                                                                                                                                                                                  ~
                                                                                              ~~:sr                                                                                                      3 BRN                    J                          OUT2
                                                                                                                                                                                                                                                                                ... 14AWG ORG                                              oun s
:~              t~          ADJ      OUT1                                                                                                                      SITESTAdj 4  GRY            4  POWER UP                                                                                                  4 GRY Powe1Up S  YEL                IPARELAY                                                                                                  5 YEL                    5      !PA Relay Au~ 111,pllt WHT BU<
11 13 15 12 1,t 16 VBAl GROUND WHT BLK 1113.li._
121416 VBAT r                                                              ""'"
(Opllollill)
                                                                                                              ~r
"'ti                                                                                                                                                                                                                                                                                                                                                                  (J1)      Q.
                                                                                                                                                                                                                                                                                                                                                                                  ~
s:,:i                                                                                            AMPLIFIER 1                                                                                                                                  AMPLlflER6 r,o                                                            (J7) 1~
IOU TPUTON (Jl)    6  WHTIGRN              9    /Output On                                                                                                                                r,i (ti                                                                  2!!h!:!...._
BWWHT AUOIOIN1 I                                  _l_
2 BLU 1 BLKIWHT 2
1 AtKlioln 1 Audio In 2                                                                                                                          ~
!.,,I
                                                                                                                                                                                                                                                                                                                                                                                =
                                                                                                                                                                                                                                                                                                                                                                              -=-*
AUOIOI N2
                                                                        ~                                                                                                                              3 BRN                    J      Sias                OU12                                    Status LEDs ORG GRY
                                                                                        ]Q 4
SITESTAOJ        OUT1                                                                                          ORG 4 GRY
                                                                                                                                                                                                                            ....l.ll.
4 SITESlAdj Power Up oun RED (op!IOl"lal)                                                  (J20)
                                                                                                                                                                                                                                                                                                                                                                                  ~
r~
POWER UP
                                                                        ~                                                                                                                              5 YEL                    5      /PARelay IPA RELAY                                                                                                                                                                          voo WHT BU<
111315 121'16 VBAT 1
                                                                                                                                                                                                            ~L~T      ~~ :; :: ~~~                                            BLU l        RED    11*12VOC GROUND y L
                                                                                                                                                                                                                                                                                                                                          '-"'---7 "'&deg;""" I                  I  0 t
(J4)  1 RED                                                                                                                                                                                                    BRN
                                            ,;IN ll!IIIIIU~l~I~! !
1 Pag.iglmerlac;e          r,i Board(OpllOllill )
NC r                                                                                                ,    , , , , , , , , , , ,                              [~~-~
                                                                                                                    !~~~~                            m~~~r~H~IU                                                                      ~1 ~ ~ ~~~~~=
                                                                                                    ~l~!~I~
                                                                                                    ~~~~=
:!n.;'6'&sect;'';.,              ~~~'.:::~                ,; t&sect;' ;.
                                                                                                                                                                                                ~~~~~~~d!~J~
z e>.., z:::i
                                                                                                                                                                                                      ~jjjjiOOCll<(l IIIi::.::                  ozz....1:::io
                                                                                                                                                                                                                                                            ~  B =s -~ u o
                                                                                                                                                                                                                                                                              ~1;1515
                                                                                                                                                                                                                                                                              ?;  i~t Aw1Cont1olS1atus Board(oplional) iltft                  Cl)~J&                    i%!%%                    mt;,Jj                                                                        +  & it:~ e :'!
* 5 ~ ~
QQQQQ                      ~!~                  QQQQQ                        ~g-o:              !
a.
3: 3: 3: 3: (/)
u u u u er
(!)      - "'                    ~
in<( -                  u      u 1---- (J 2 J - - --                              L _ _ _ (J3) - - - -                      ' - - - - (J4) - - - - - ' ' - - (J21) -                                      l_(J6)-
1 r RED 7
      ~
METER*                                                                                                                          Control Board 1 Ground        (J 1)                                                                                                                                                                                                                                            (J1)
Battery Charger                                                                      ~ - -- - --                    (J11) - - - - - - ~                                                                                                                    (J7) Sque~      14 YEL  ~
5
                                                                                                    *VBAT                                                                                                                                                                                                DTMF Out I    GRN  1                      BIT2
                                                                              ~ - ~ -...        l G1ound          (JS)          ~      -o                                                                                                                                                                    VBAT I I            nn, BLK
                                  ~ 1* VBAT l  GROUND Charger ON/OFF ACSense ~
c2.1 BCl.
2 4
1 Charger ON/OFF ACSensa a.&sect; J_
0
{!i
                                                                                                                                                        .2 =
                                                                                                                                                      &.~
                                                                                                                                                                        ,n ~ _M ~ ..- o g~jiici5ci5ci5jiijii Ground Ra<lol11 Panlal BITJ
                                                                                                                                                                  ~  ::  ~  :' :!. ~  ~ ~                                                                                                                    *12V this board is presen~ connect                                                              N this board is presen~ connect
                                                                                                                                                                                                                                                                                                                                    ~=**
J,
                                                .  ~
If wires to J11 as shown (ex. connect                                                          wires to J11 as shown (ex. connect
                                                                                                                                                                                                                                                                                                                                    ~
r                                    f  IS                                                                                          RED /+12VDC) to J11 position 3.                                                            WHTIRED (Bff 2) to J11 position 15.
(J2) 1
* BATTERY -1,
* BAHERY TTI                                                                                  lll lllllllllllllll l l l l l l l l
 
WAT                                                                                                                  VBAT GROUND                                                                                                                        GROUND
                                                                                                                                                                                                                        " N olavalla bl e f or                                    ** N ota11all1b1 e for WP S-4 000S  r1H                                          WP S *2900 St r1H MOTHERBOARD                                                  AMPUF IER 5                                                        Mottlerboard                                            AMPllFIER 10*                                                                                                S1roneBo.wd ROIOrRNyBo.vd (J IIJ                                                                                    j WPS2806-WPS28 10 SERIES )          (J 1f)                                                                                (WPS-4000 Se nes r *                                (opllo!'li'IIJ l
OU T2 OUT1 1- 6
                                                                                                                  ~~
                                                                                                                            ;tK]
N    *2 OUT2 our, ~
                                                                                                                                                                                                                                                  '-6 1
u
                                                                                                                                                                                                                                                      !I    RED l;
i I G;;:
(J3)
Gromd
                                                                                                                                                                                                                                                                                                            -HT W,ff Bu<
2 ~(J3)
                                                                                                                    ,._ ArNdlngo129 0 tvn1                                                                                                          R BRN              '  ov        sv reslslanceshoold l>tl measu,ed3'Cl'oss sl,en                                                                                                            ORO 2
ov      1.2V 3
dliYers m
ov      1.2v*
The driYermustbe
                                                                                                                                                                                                                                                                            's  ov      1.2v*
diseotlneciedll'omlhe                                                                                                              ORN av*                                    n ( J 2)
AMPUf lER4                                                                                                                  AAPLIFIER9"                                          ov
                                                                                                                                                                                                                                                                            *1 (JIOJ                                                    ~ ~ =* laking                                                        (JI O}                                                        BLU ov OUT2  1- 8                                                                                                                    OUT2    '- 8 ORY WHT ov ov
:~: (Jf) av*                                          DighlVoice jopllOnal)
WHT/8LK ov        av*                                    >----
OUT1
                                                                                                                  ~~                                                                                                                      our, l- ~        WHTIREO R    WHT/ORG      "      ov ov av*
av*
Bu<          "
12      Ground
                                                                ,.,.,                        AMPLIFIER 3
                                                                                                                                                                                              ,.,.,                                                                            i
                                                                                                                                                                                                                                                                              ![hl AMPLlflER8 OUT2  1- 8 5
0Ul2    ~8 5        RED"'"
BLK ***      '    0    24    0                                            ..,.,,
Radlotntetlace 0    0 OUT 1 u                                                                                                                    our,
                                                                                                                                                                                                                                                  ~~
BRN      1,              ,,.24                                  ~                  )
                                                                                                                    ~                                                                                                                                        BLU 0
0      ,,.
ORN 0      12*
YEL 0      12*  (J2)
ORO 12*
(J6) 0 ORY                                                    WHTIRED 6 AMPLIFIER 2                                                                                                                  AMPLIFIER 7                                                  23*
0                                                *24VDC (JB)                                                                                                                          (JB/                                                            VK>
0      23*
OUT2 OUT1 6
u OUT2 oun 0
u RED BU<
                                                                                                                                                                                                                                                              -*uAWG
                                                                                                                                                                                                                                                                          ..      0 0
23*
                                                                                                                                                                                                                                                                                          ~
RED 9    .,,voc
                                                                                                                    !I                                                                                                                              !I R                                                                                                                                R Au~ tnpUC I                                                        (optional)
ROTOR "ti                                                                                                                                                                                                                                                                          I                                      '-----      t==J                (J1)
                                                                                                                                                                                                                                                    .8
~                                                                                            AMPLtf lCR 1 (JO AMPLlflER6                                                                                            >----
{J7)                                                        ~
(J7)
                                                                                                                                                                                                                                                            *=Pulsating Voltage ti>
"'"                                                                                                      OUT2      !I                i                                                                                                  OV T2 u
Status LEO*
                                                                                                                    ~                                                                                                                    ou n OUT1                                                                                                                                                                          (opuonal )                                                (J20)
LEO STATUS                                                                                                                  ~
BOARD
(.U/                                                                                                          !,
N    I~      N                  ' RED
                                                                                                                            .__                                          l
* N
                                  '                                  2 BU<
                                                                                                                                                                  ~      ~  l
                          * &sect; H!" Q. ..  !i I' ..ci ~:;;    &#xa3;
                                                  ~          (J13}  1 RED
                                                                                                                                                ! l _'[ H ~ ; ~ l i
( < < m
                                                                                                                                                                                  ?                                                                                                                                                  f>~ln!erlace Boa1d(opllonal)
I
                                                                                                                                                                                                                                                                                                                                  ~
                  -  N                                              2 BU<
0                                                                                            -  N  "                    a,  S? :::
NC
[                                                                                                                                                                                                                                                          (J2)
                                                                                                                          '1, z C                                  z lq                                                    l          f 3 H~
All Voltages shown are DC unless otherwise
                                                                                              ~
                                                                                                    ~1 !" .~ .~ I. '~ ..
N t~[ i
                                                                                                                          ~If h o  C
                                                                                                                                                  ~I~
                                                                                                                                                  - Io
                                                                                                                                                        ! a Id !
f Ii i0  0 l1 i "~
                                                                                                                                                                                            -    N 0
cr:
                                                                                                                                                                                                          ~ ,
el,
                                                                                                                                                                                                                ~ ~
                                                                                                                                                                                                      . .. . i i 11:
0
* 0  0  N                                                                                                    AuxConuolStacl.lS noted                                                                          ;!;!;!;!;! uua; ~a;6                              ;! ;! ;! ;! ;! u u a; a; a; 6              ~~~~~~~~~~~
                                                                                                                                                                                                                                                                                                        ~                            Boan:1(01)1:lo,\al)
Active
                                                                                                                  ~~                                              ~~                                --                        i'                                                I (J10)
                                                                                                                                                                                                                                                                                                        ~
I---        -
                                                                                                                                                                                                                                                                                                                                  ~
WHT Stand-By
                                                                                                ~a;a;?;~66666~                                    ~~~?;~66666~                                66666666666j                                                                                            I---
                                                        ,I RED (J2) -                                        (J3)                                        (J4)                  L.....-    (J 21) -    L-  (J6)-            I                    ~
                                                                                  ~
* 24V                        I                                                                                                                                                                                                  '  -
    ,,                                              METER*
Battery Charger
                                                                              ~
R""
o,""""
                                                                                              *24V
                                                                                                                '1')                                                                Control Board i
(J 7)
(J1)
BLK      3 Grour.d                                                    (J11) 6 WHT~EO WHT        2
* VBAT                            ~ C 2 - 1____,QBQ___,)_
(JS) 1(J20) l                                                  l (J 1S) l                        *24V                ,_
Charger ON/Off
* SV Bu<        3 GROUND                  AC Sense  ~
BC2-2
                                                                                ~              *19V I                                                                                                                                                                              *12V 9 R60
      ,,                    ~                  ~
                                                  .I ~
j                                                                                                                                                                                                          TI
                                                                                                                                                                                                                                                                                                                    ,____ 7 (J2) lllllllll I  I  I    I  I    II    I 1
* BAnERY.
I    BATTERY
* 1 111                                                                              111          111111
 
Section I: Overview of System Components a) Station Component Locations The WPS-2900 High-Power Voice and Siren System is comprised of 10 basic models:
Model                Driver Info                                              Cabinet WPS-2900-1          One (1), 400 Watt Driver                                  Type II WPS-2900-2          Two (2), 400 Watt Drivers                                Type II WPS-2900-3          Three (3), 400 Watt Drivers                              Type II WPS-2900-4          Four (4), 400 Watt Drivers                                Type II WPS-2900-5          Five (5), 400 Watt Drivers                                Type II WPS-2900-6          Six (6), 400 Watt Drivers                                Type II WPS-2900-6A          Six (6), 400 Watt Drivers                                Type III WPS-2900-7          Seven (7), 400 Watt Drivers                              Type III WPS-2900-8          Eight (8), 400 Watt Drivers                              Type III WPS-2900-9          Nine (9), 400 Watt Drivers                                Type III WPS-2900-10          Ten (10), 400 Watt Drivers                                Type III Each system essentially functions in the same manner as do the others. This manual will provide the necessary information to properly operate, program and diagnose this system regardless of specific model. If information relevant to a specific model is required, it shall be presented and noted as such.
The 2900 series systems are comprised of several major components common to all models, although quantities of some components will vary from model to model.
Fig. 2: Siren Cabinet Door Components l-,                                                    .,.
r TT*~ "'                                                                                                      . ~
                                                                                              ~
0~   
                                                                              ~ .        .                                      '"
                                                                                  -          -          -            m      1B
                                                                          . ~
                                                                                ~I    @a
                                                                                                        ~I    @t G) Digital Voice Soard        @ r SirenAmp6                      *
                                                                                ~I    @b
                                                                                      '""'""'"      ~
                                                                                                        ~I    @g
                                      @ 9 Siren Amp 7                                                0
        &#xa9; siren Control Board R adio or Landline Board"  @h Siren Amp 8
                                      @ 1 Siren Amp 9                  .      ~I    @c
                                                                                                    >  ~I    @h C ontrol Board Serial Port
                                      @i Siren Amp 10                                                0                        11 Amplifier LEO Status Board
        @,s irenAmp 1
        @,s irenAmp 2 (J) Strobe Control
                                      @ Paging Interface
                                                                        ~
                                                                          .    ~I    @d
                                                                                      """ """'    0
                                                                                                    ~
                                                                                                        ~I    @i
                                                                                                              """"""'    0
        @, s irenAmp 3                @ Battery Charger
        @,s irenAmp 4                @ Solar Charger Card (Optional )  .    ~I.
* I:>
                                                                                                        ~I    i 0
        @,s irenAmp 5                @ Battery Disconnect Switch
                                                                                ~
        '[ ~ BOO 1111[]~                                                                                                        .~
1
                                                                                              ~
                                                                        .  .                                              .        ~
Page5
 
b) Station Components Defined Control Board - This component (located on the inside of the upper cabinet door) controls the key functions of the WPS2900 system including:
Tone Generation                                  Remote Activation Event Timing                                      Rotor Control Remote Station Status Reporting* (encoding)      Local Control System Diagnostics (incl. SI TEST)
The control board contains a microphone jack for public address and a serial port to allow connection of our Siren Diagnostic Programming Tool Software (hereafter referred to as SDPTS) to the remote station. The control board is also the location of the diagnostic LED's.
Siren Amps - These components (located on the inside of the upper cabinet door) receive the desired tone or message generated by the control board, amplify it and deliver it to the siren driver.
Siren Driver - This component (located in the speaker assembly) produces the desired audible tone or voice message.
Radio or Landline Board (Optional) - This component (located on the inside of the upper cabinet door) receives signals from either the antenna or landline and delivers them to the control board for processing. Through the use of the included radio, the station is also capable of transmitting status information back to the control center.
Motherboard - This component (located on the inside of the upper cabinet door) distributes Battery Voltage and signals to all system components that require this voltage. The motherboard is fused @10 Amps to protect all connected components EXCEPT for the siren amplifiers and the rotor (they contain their own fuse). The 2nd motherboard (WPS2900-6 thru WPS2900-10) is also fused @10 Amps. The Motherboard also distributes signals between the amplifiers and the control board.
AC Battery Charger - This component (located on the inside of the lower cabinet door) uses 110 VAC (or 220 VAC) single-phase service to maintain the stations batteries at their proper voltages.
Page 6
 
Solar Regulator (optional) - This component (located on the inside of the lower cabinet door) uses electrical energy collected by a pole-mounted solar panel to maintain the station batteries at their proper voltages.
Ammeter - This component (located on the inside of the lower cabinet door) provides a visual indication for the charge current flowing into the batteries from the charger or regulator.
Voltmeter - This component (located on the inside of the lower cabinet door) provides a visual indication of the DC voltage across the batteries.
Auxiliary Control Status Board (optional) - This component (located on the right inside wall of the upper cabinet) is wired to remote switches to facilitate remote operation of a specific siren station.
Auxiliary Input Control (optional) - This component (located below the " Radio/Landline Board" on the rear inside wall of the upper cabinet) is wired to remote switches to facilitate limited remote operation of a siren station. In contrast to the Auxiliary Control Status Board, the Auxiliary Input Control Board does not offer feedback capabilities and is limited to the following remote activation commands:
* All Siren Tones
* Cancel
* SI TEST
* Digital Voice Messages 1 thru 4 Batteries - These components (located on the inside of the lower cabinet) provide the 28VDC necessary for the system to operate.
Battery Disconnect Switch - This component (located on the rear inside wall of the upper cabinet) allows all system batteries to be completely disconnected from the system. NOTE:
This switch does not disconnect the batteries from the battery charger or regulator.
Antenna Poly Phaser (optional) - This component suppresses high-voltage (static) charges that could be present on the antenna.
Page7
 
Antenna (optional) - This component (located on the utility pole) is capable of either receiving signals broadcast from the control center (one-way) or can both transmit and receive signals to and from the control center (two-way), depending how the system was ordered.
Solar Panel (optional) - This component (located on the utility pole) collects solar energy, converts it to electrical energy and delivers it to the Solar Regulator to maintain the station batteries at their proper voltage.
Strobe Control Board (optional) - This component (located on the rear inside wall of the upper cabinet) is a user-defined device that controls a pole-mounted strobe light. This light can be configured to activate during specific conditions (example: when any tone or message is generated).
Intrusion Alarm (optional) - This sensor (located on the door jam of the upper cabinet door) detects the opening of the cabinet door. If the station is equipped with this option , the alarm is configured to transmit a signal back to the control center.
Paging Interface (optional) - This component (located below the " Strobe Control Board" on the rear inside wall of the upper cabinet) is a user-defined device that serves as an interface between the siren cabinet and an existing, in-house public address system. This board has an output relay with a 1 Amp rated closure that can be used for a " Push To Talk" function.
Page 8
 
Section II: System Operations a) Remote Operations Remote operation of a WPS-2900 series siren involves transmitting signals from the control center to the desired station. This is accomplished by using either an encoder and transmitter or, if the station is so equipped, using an auxiliary control status board that has been wired to switches/con trols at the control center. Remote operation is beyon d the scope of this document and will therefore not be addressed. If your system is equipped with an encoder, please refer to the encoder operating manual for information regarding remote operation. If your station has been wired to use the auxiliary control status board , refer to the reference materials provided by the electrical engineer or installer.
b) Local Operations Local operation is accomplished through the control panel on the front of the station cabinet. The functions of these controls are as follows:
Cancel                  Abruptly stops siren tones without the normal "ramp down" found in several tones. Helpful in the event of an accidental tone activation.
Wail                    Produces a slow rise and fall tone.
Attack                  Produces a faster rise and fall tone (used for designated Civil Defense National Attack tone).
Alert                  A steady tone (Civil Defense alert).
Whoop                  A repetitive rise-only tone.
Hi-Low                  An alternating two-tone sound.
Air Horn                A pulsing air horn sound.
SI TEST                Initiates SI TEST tone and the optional diagnostic SI TEST routine.
Xmit Carrier            Actuates remote station radio transmitter PTT circuit.
When tone squelch is used with the transmitter, the transmit function is used when adjusting tone squelch modulation.
Page 9
 
XmitAudio      For use with remote station radio transceiver, causes transmission of DTMF tone via RF link for tone modulation adjustment.
Xmit Status    Transmits station status information and battery voltage to the control center.
DVMTest        Activates the Digital Voice Message (DVM) assigned to the test procedure in the configuration software.
Rotor CW        No function with 2900-series equipment.
RotorCCW        No function with 2900-series equipment.
Keypad Arm      Enables local station operation via keypad. Once pressed, the keypad remains active until either a) another keypad button is pressed, orb) 60 seconds have elapsed, whichever comes first. The Keypad Arm button must be pressed each time a keypad button is to be pressed. Note that the Cancel button is always enabled and does not require Keypad Arm to be pressed.
Fig. 3: Station Control Panel Page 10
 
Section III: Understanding Station Addressing Every Siren Station in a given area code has its own, unique "Station Address". This address allows the user to select an individual or a group of stations. As stated elsewhere in this manual, a valid station address can be any number from 0000 to 9999. This allows for 10,000 unique addresses; a staggering number of stations to keep track of. Although it is logistically impossible to have that many stations in a single area code, it does illustrate the importance of a sensible, intuitive numbering convention for station addresses. This section will outline two types of conventions Central Point Source: Quadrant, Sector, Radial & Station Frequently, warning systems are used to notify the public of emergency situations that may occur from a single, centralized location. Typically, siren stations would be located throughout a 360&deg; area surrounding this location for a specified distance from the source. In this scenario, the Central Point Source convention would be well suited.
For illustration purposes, assume the siren stations are installed within a 5 mile radius of the Central Point. As such, a Quadrant, Sector, Radial & Station numbering convention would allow the selection of any of the following:
* any siren station
* all siren stations
* any one of four sectors
* any one of 5 radii within the sectors The area of coverage in this system , a circle, is divided into 4 quadrants. Each quadrant is then divided into 4 sectors. Each sector is further divided into 5 segments or radii emanating from the center of this siren system.
Fig. 4:
                                                                  ~
4                1    4 Central Point Source Divisions
                                                  ) \                    )
3                2    3                2 QUADRANTS 1-4        QUADRANT SECTORS 4 ~              1
(@)~,
3~                2 RADI I          rND IVIDUAL STATIONS Page 11
 
In this system, a stations address is structured as follows:
Di2it          Allocation 1            Quadrant (1 to 4) 2            Sector (1 to 4) 3            Radii (1 to 5) 4            Individual station within a radian Here are some sample activations to further illustrate this concept.
Sample 1:
A station with address 1354 would be located in:
Quadrant:      1 Sector:        3 of Quadrant 1 Radial:        5 Station:      4 If an operator selects station 1-3-5-4, only that station will be selected, as shown.
Fig. 5:
Single Station Selection SINGLE STATION SELECTION STATION 1354 Page 12
 
Sample 2:
If the activation of a group of remote stations within a whole segment of a radius within a quadrant and sector is desired, the fourth digit address is substituted with a " Wild Card",
the "#" pound sign.
An address selection of 1 4 - # would activate the system as follows:
Quadrant:      1 Sector:        3 of Quadrant 1 Radial:        4 Station:      # All stations defined by above This selection is shown below.
Fig. 6:
Group Selection -
Radial Sector GROUP SELECTION-RADIAL SECTOR GROUP 134#
Page 13
 
Sample 3:
Selection of an entire sector can be accomplished by using the following address:
Quadrant:      1 Sector:        3 of Quadrant 1 Radial:        # All radial 1 - 3 Station:        # All stations defined by above In selecting a sector, the first two digits of the address are set for the sector address, for example 1 - 3 (Quadrant 1 - Sector 3). The third and fourth digits are substituted with a #
(Wild Card). Therefore, the address to select all stations in sector 1-3 is 1 # - #. This selection is represented below.
Fig. 7:
Group Selection -
Sub Sector I
GROUP SELECTION-SUB-SECTOR GROUP13##
Page 14
 
Sample 4:
The selection of a complete quadrant can be achieved by using the following address:
Quadrant:      1 Sector:        # All sectors of Quadrant 1 Radial:        # All radials in all sectors of Quadrant 1 Station:      # All stations defined by above When selecting a quadrant, the first digit designates the Quadrant (1). the second, third and fourth digits are replaced with Wild Cards (#,#,#). Therefore, the address for selecting all stations in quadrant 1 is 1 - # - # - # as illustrated below.
Fig. 8:
Group Selection -
Quadrant GROUP SELECTION-QUADRANT GROUP###
Page 15
 
Sample 5:
All stations in a system may be accessed by using the Wild Card (#) for all address numbers.
The address would be# - # - # - #.
Quadrant:      # All Quadrants Sector:        # All sectors of all Quadrant Radial:        # All radials of all sectors of all Quadrants Station:        # All stations defined by above This "All Call" is illustrated as shown.
Fig. 9:
Group Selection -
All-Call GROUP SELECTION-"ALL-CALL" GROUP mt-##
Page 16
 
Governmental: County, City & Station For this next type of address structure, assume that the siren system in question is used primarily for tornado warnings throughout a major population center. This center encompasses three counties with each county having no more than ten cities. Two cities contain more than 50 high-power voice and siren stations.
The following represents a Governmental System 4-digit address configuration, allowing activation by " All Call", county group activations, city group activations and individual station activations:
X              X              X              X
: ........... : ........... Individual Siren Station (00 - 99)
: ................................... City (0 - 9)*
: ............................................... County (0 - 9)
*One digit could also be reserved for unincorporated areas.
An address of 2 4 - 5 would indicate the following individual station:
Siren Station 45, in City 5, in County 2.
The Wild Card (#) permits the use of several different types of group activations. Three samples follow:
Sample 1: County Activation (1 - # - # - #)
All Siren Stations in all Cities in County 1 will be activated by this transmission.
Sample 2: City Activation (1 # - #)
All Siren Stations in City 5 of County 1 will be activated by this transmission.
Sample 3: System All Call (# - # - # - #)
All Siren Stations in all Cities in all Counties will be activated by this transmission.
Page 17
 
Section IV: Troubleshooting Audio Loss If after activating the siren there is no audi~ output, perform the following procedure step by step. This procedure will require a digital multimeter.
I
: 1.      Locate the Audio Presence LED on the controller board (see "Fig. 11: System LED Diagnostic Indicators" on page 29). When audio is present on the board, this LED will be on.
: 2.      Activate the WAIL siren tone from the control panel on the siren cabinet. Confirm that the Audio Presence LED is on. If this LED is not on or if it turns off quickly, measure the battery voltage. The siren will not activate if battery voltage drops below 19 VDC. Be sure to measure the battery voltage at the same time you activate the siren. The batteries may show a good float roltage while they are not under load, but upon activation, the battery voltage may drop below 19 VDC if their capacity is low.
Note that when the siren shuts down and the load is removed from the batteries, the voltage may rapidly return to 25 VDC or more. If this condition is occurring, the batteries will need to be replaced. If the voltages are in the normal range, proceed to step 3.
: 3.      Locate connector J2 on the control board. With your multimeter set to AC volts, measure across pins 6 and 7 (White with Oran*ge stripe and White with Brown stripe). With the siren tone running, 5 VAC should be present. I/no voltage is present, the controller hoard is probably at fault NOTE: Confirm that the au.dio presence LEI) is on whi.I_e performing these measurements. It indicates that the siren controller is still a~tivated. If the specified voltages are present, proceed to step 4.
: 4.      With the siren tone still active, measure across pin 1 (Blue wire) and pin 2 (Black w/
White trace) on each of the siren amplifiers. 5 VAC should be present at each amplifier. If so, proceed to step 5. If no voltage is measured, this is indicitive of a wiring problem between the controller board and the siren amplifiers. Check the wiring between these components
: 5.      Remove the Red siren driver lead frc>m each siren amplifier. Press "Cancel" on the control panel and then press "Wail". Measure across the output of each amplifier (White Weco connector) with the siren driver disconnected. 70 VAC should be measured. If this voltage level is measured, proceed to step 6. If this voltage level is not found and 5 VAC was measured at the input, proceed to step 7.
: 6.      Set your meter to measure resistance at its lowest scale. Measure across each of the speaker drivers, making sure that at least one wire of each driver is removed from the power amplifier (or else the transformer in the amp is being measured as well).
Each driver should have a DC resistance of approximately 3 Ohms +/- .3 Ohms. If a resistance value outside of this range is found, contact factory.
Page 1~
: 7. Set your meter to measure DC Volts. Connect the negative lead of your meter to ground (one of the solid black wires in the multi-position connector on the amplifier is a good ground source). With a siren tone activated, measure the following wires for the following voltages (approximately):
Grey                  6VDC Brown                  5VDC Solid White (all)      24VDC AC Battery Charger The AC-powered battery charger has two charging modes: Equalization Mode and Float Charge Mode. The charger is in equalization mode when AC power is first applied; the charger will stay in equalization mode until the battery voltage reaches approximately 30VDC. Once the battery voltage reaches that point, the charger will switch to float voltage mode. In that mode it will charge the batteries to the appropriate voltage relative to the temperature of the batteries (25 to 29VDC).
The AC battery charger contains three circuit boards. The filter board contains a single, green LED, while two charging boards each contain a pair of LED's, one green and one yellow. This pair of LED's provides diagnostic information for the battery charger. The following chart defines their various diagnostic states.
Green LED                        Yellow LED Not Working                      Nonnal Condition Charger Operating Properly      Equalization voltage mode OFF                      No AC voltage present            Not Applicable ON                      AC voltage Is present            Not Applicable Solar Regulator The following procedure can be performed to confirm proper operation of the solar regulator:
: 1. Disconnect the solar panel from the charger. With a DC voltmeter, measure the voltage across the wires coming from the solar panel. The voltage should be greater than 32 VDC (NOTE: The solar panel must be in direct sunlight).
: 2. Reconnect the solar panel to the charger. Monitor the battery voltage with the cabinet voltmeter. The float voltage will vary between 25 to 30 VDC, depending on battery temperature. When the solar regulator is charging, the DC LED on the circuit board will be on. During normal operation the charger will cycle on and off.
Page 19
 
The float voltage will vary with battery temperature. The following is a brief description of the nQrmal charging cycle:
If the float voltage for the current temperature of the batteries is 26 VDC, the regulator will turn on at 26 VDC (LED will come on) and it will charge the batteries to 28 VDC. Once the battery voltage reaches 28 VDC, the regulator will turn off (LED will go off), "and the battery voltage will be allowed to drop to 26 VDC. The cycle would then repeat itself. If the float voltage was 27 VDC, it would cycle from 27 VDC to 29 VDC.
* When AC power is applied to the battery charger, the following voltages should ,be
* measured on the wires coming off the charger:
Note: Refer to "Fig. la: Station Wiring Diagram (designations)" page 3.
Fig. 10:
Solar Regulator Connector                  GREY                            -+-+------          RED Pin-outs                ORANGE -----+-+--+-++-              -+-+---+--+-----    WHITE
                                                            -++-----BLACK REAR VIEW OF PIN HOUSING Pin Position 1  RED - Battery Voltage to Ground (BLK wire in BC-1)
Note: Voltage present only when siren is powered up.; this is sourced from the siren motherboard Pin Position 2  WHITE - Charger output wires (25 to 31 VDC)
Pin Position 3  BLAGK - Charger output wires (25 to 31 VDC)
Pin Position 4  GREY - 19VDC from GREY to Ground (BLK wire in BC-1)
Pin Position 5  ORANGE - 5VDC from ORANGE to Ground (BLK wire in BC-1)
Pin Position 6  Not Used Page 20
 
Digital Voice
: 1.      Remove all amplifier fuses.
: 2.      Install an 8 ohm speaker at amplifier audio input connector pins 1 and 2 (Blue and Black w/White wires) in the 16 position connector.
: 3.      Select a siren tone by pressing one of the controls on the front panel.
: 4. If the tone can be heard through the speaker, press the DVM-Test control to play the predesignated message.
Partial or Full Diagnostic Failure This procedure is to be used if the Partial or Full diagnostic LED (located on the controller board) indicates that a problem has been detected. A Partial indication means that at least one speaker and/or amplifier is operational. A Full indication means that all speakers and amplifiers are operational. NOTE: In order for a good Full indicator to be valid, a good Partial indicator must also be present).
: 1.      Connect the SDPTS to the siren station via the com port on the front of the siren cabinet control panel.
: 2.      Display the "Status" screen on the SDPTS.
: 3.      Press the SI TEST control on the front control panel.
: 4.      Each amplifier contains a red LED that is visible on the front of the control panel.
Note if all the LED's are on. Tap the "Update Status" button on the SDPTS and note which amp is displaying an error.
: 5.      Open the front panel and swap the speaker driver wires from the amplifier that indicated a failure, with an amplifier with a lit LED. For example: if the LED for amplifier 1 is the only LED not on, install amplifier 1 speaker wires onto amplifier 2 and install amplifier 2 speaker wires onto amplifier 1. This will diagnose if it is the speaker or the amplifier that has failed. You may also measure the DC resistance of the speaker driver with your ohm meter. Be sure that the speaker driver wires are disconnected from the amp prior to measuring. A good driver will read 3 ohms+/.:. .3 ohms.
Page 21
 
Section V: Maintenance Although The WPS-2900 is of a dependable, solid-state design, periodic activation, field inspection and preventive maintenance is recommended to insure the maximum performance of each station.
Frequency of Testing and Activation A system of twice-monthly activation and confirmation, combined with a quarterly service and preventive maintenance is recommended to help insure the successful performance of a station. Increasing the frequency of testing will support and improve a station's test record.
Stations located in environ~entally adverse locations will require inspectio~ and preventive maintenance at more frequent intervals than just discussed.
IMPORTANT! STATIONS SHOULD ALWAYS BE INSPECTED IMMEDIATELY FOLLOWING SEVERE STORMS.
If a station is activated by remote control (landline or radio), the twice-monthly activation should be performed using_ the remote control link.
The twice-mon(hly activation of a station can be confirmed by several different methods, depending upon the options selected with each Whelen System.
Local Site Confirmation For a basic station activated at the cabinet, or by landline or radio, have, an observer confirm that the station activated audibly. The observer should report successful _as well as failed station tests. Station Performance Logs should be maintained. It is important to understand that audible confirmation alone is not assurance that the station is operating at 100% power. This requires inspecting the station in greater detail.
Stations 'may be optionally equipped with counters that advance upon radio or tone generator activation. These counters do not confirm 'total operation or the final expected output of an outdoor warning device.                                        *          '
If a* station is equipped with the "Status Display" option, full power station activation can be visually confirmed from outside the siren cabinet. This diagnostic display, located on the right side of the cabinet, will indicate the following:
(from left to right)
Red        indicates the presence of AC power (if equipped with an AC Battery Charger)
Yellow indicates the presence of DC power at minimum operating level (at least 19VDC)
Red        indicates partial amplifier/driver function G~n indicates full amplifier/driver function Red        indicates rotor operation (WPS-4000 systems only)
Page 22
 
This diagnostic function is enabled by either a full power siren tone activation or by performing a SI TEST.
The same information is available on the control board LED numbers 4 - 8. The "Status" option is not required for the on-board LED's to function.
Following activation and observation, the results should be noted in the performance log.
Any indication of incomplete operation presented by the LED indicators should prompt IMMEDIATE service attention.
The system retains diagnostic information until cleared by a specific command.
The diagnostic information stored at the station, if not cleared, will update itself automatically with subsequent SI TEST or siren tone activations.
Remote Monitoring and Confirmation Stations equipped with the optional Whelen COMM/STATTM Command and Status Monitoring control, allow remote monitoring of status as well as confirmation of system activation. COMM/STAP:M returns the results of a remote station activation (both SI TEST@ and siren warning mode) in a DTMF encoded format via radio link.
Remote monitoring by RF link eliminates the necessity of physically visiting a station to confirm an activation.
Following the activation of a station, a "Status Request" may be sent to that station by DTMF encoded radio command. Diagnostic information is then presented to the status encoder at the station, converted into DTMF code and transmitted back to the control center, where one of several COMM/STATTM base station products will convert the DTMF code into meaning.fol inform~tion.
Quarterly Maintenance Devel9ping a quarterly inspection and preventive maintenance program for an outdoor warning station requires a thorough understanding of all the elements and .expectations of the system. The following section provides an overview and basic guideline for quarterly station inspection and preventive maintenance program for the sample station.
Page 23
 
Visual Siren Station Physical Inspection
* Obsenre the speaker cluster, siren cabinet and AC Sernce for any signs of damage or loose mounting hardware (Some shrinkage of a newly treated utility pole may occur in the first several years following installation, requiring the tightening of mounting hardware.
* Check all conduit for :watertight connection and entrance into the siren cabinet.
* Inspect the AC Service for damage, blown fuses, degraded (corroded) power connections and integrity of the lightning arrestor.
* Inspect the grounding system for AC Service, Siren Cabinet and pole top equipment.
Verify connections and acceptability of earth ground.
* Observe the pole for any shifting and/or leaning. Poles that are not plumb will not properly direct alerting sounds.
* Examine entire station for any signs of vandalism or forced entry.
Siren Cabinet and Components
* Inspect AC Outlet, fuse and surge suppression equipment. Examine system for infiltration of foreign material(s), rodents, insects or other pests.
* Inspect and, if necessary, clean all drain holes and vent screens.
* Inspect battery terminal connections and clean if necessary. Re-apply silicone coating to battery terminals if necessary. Observe battery voltage with siren in inactive state (AC power must be on to s~ation, otherwise station must be powered up to obsenre meter).
* Examine all wiring harnesses for chafing. Verify wiring terminations for tightness and wiring connections for proper electrical connections. Replace and correct any corroded or marginal connections. Inspect antenna for proper connection.
Speaker Assembly and Pole Top Equipment NOTE: Any examination of Pole Top equipment should be performed with the station audibly disabled.
* Inspect speaker for blockage by rodents, pests, insects or other foreign material. Clean if necessary. Inspect any wiring cables or harnesses for chafing. Inspect the siren driver compartment for infiltration of foreign materials, rodents or pests. Clean if necessary.
Confirm that the driver compartment will allow for water or moisture drainage. Inspect speaker wiring connections for any sign of corrosion.
Page 24
* Verify tightness of all mounting hardware.
* Check all wiring terminations and connections.
Station Performance Testing NOTE: Depending on local conditions and station options selected, the station may be tested on or off line. Off line testing of the station involves disconnecting the speaker drivers from the siren amplifiers, so as not to disturb the public when verifying tone generator operation. A complete test must, however, include the testing of the siren amplifier operation. This can be accomplished inaudibly using the SI TEST command.
A basic routine, verifying the performance and operation of the sample station previously described, would be as follows:
: 1. Local and Remote Activation -
Activation of each remote station function by local control and remote control. With amplifiers on and off line as needed. An examination of each activation function will also facilitate a verification of related and subsequent system module activations and electrical connections that would be caused by an activation command. Also confirm function time outs (ex.: does the Alert signal time out at three minutes as per user
      ~pecification ?).
: 2. Response to Station Address and All Call address programming -
Control Center reception and activation on SI TEST or non-tone activation, for individual station address and All Call address selection.
: 3. Public Address -
With the station on line, activation of PA for both local and remote control, verifying PA Audio path and proper set up level of volume.
: 4. Siren Amplifiers -
Inspect for complete operation with speaker drivers (observe LED's).
: 5. SI TEST Station Analysis -
Observe and confirm diagnostic status of:
AC DC Partial Amplifier & Speaker Driver Operation {disable one amplifier to confirm this test).                        ,
Full Amplifier & Speaker Driver Operation NOTE: Verify AC drop out during SI TEST mode.
: 6. Battery Charger Operation -
Observe for proper charging operation.
Verify AC drop out in PA or SI TEST mode.
Page25
: 7. Batteries -
Verify voltage stability under load.
Perform a load test.
: 8. Status Encoder -
Perform a diagnostic SI TEST of the station.
Compare sta~s information with observations made locally at the station.
Disable one speaker and verify that the "Full" LED indicator is off.
Disable AC and verify that the "AC" LED indicator is off.                            _
Compare battery voltage return status with observed and measured battery voltage.
: 9. Transmitter-Check status encoder DTMF tone level modulation with transmitter.
Wide Band                                  Narrow Band Wrth CTCSS                3.1 kHz dev1abon  Wrth CTCSS            1 8 kHz deviation
        ' Without CTCSS            2.5 kHz deviation  Without CTCSS          1.5 kHz deviation Check transmitter set up.
Verify power output and SWR.
NOTE:On concluding any examination of a station where connectors have been opened and closed, a final radio test by either SI TEST or full power should be performed and the results observed for a complete successful test. The PA audio path should alsf! be audibly verified by sending PA and broadcast a voice message.
The following is a sample form that may be used for quarterly inspection and maintenance.
Page 26
 
MAINTENANCE CHECK LIST Station #: _ _ _ __                      Siren Address: _ _ _ _ _ _ _ _ _ _ _ _ __
Installation Date: ______ __
                        /  ....._      Inspection Date: _ _ _ _ _ _ _ _ _ _ _ __
Inspector: _ _ _ _ _ _ _ __
PHYSICAL INSPECTION:
OK      NOTOK        COMMENT Mounting Hardware Speaker Assembly AC Service Proper Grounding Solar Panels*
Antenna*
Conduit Connections Siren Case Assembly Batteries Components Secure Harnesses LOCAL OPERATIONAL TESTING:
Battery Voltage (Stand-by)
Battery Voltage (Under Load)
Manual Test:
Clear Wail Attack Alert Airhorn Hi/Low Whoop Clockwise Counter-Cloc),rnise SI TEST AC LED DC LED Partial LED Full LED Rotor LED Timer Set LED Audio Present LED Microphone Mic Volume
    *Optional Page 27
 
MAINTENANCE CHECK LIST (continued)
Radio*:
                        .QK      NOTOK  COMMENT Squelch Control Sensitivity Antenna Tuned*
Transmit LED Remote Activation:
Clear Wail Attack Alert Public Address Airhorn Hi/Low Whoop Wail/ 5 Sec.
All Call Speaker LEDs:
1 2
3 4
5 6
7 8
9 10 Status:
AC DC Partial Full Status Request Intrusion*
*Optional Page28
 
Fig. 11: System LED Diagnostic Indicators, 0                                  P1                      J6                                                                        0 j<ID <ID <ID[            9POS 'O" 0
RJ45.JACK          0      0 0                                                      JT J1 REMOTEAl..010                                                        MIC JACK (FOR USE ONLY (POR USE ONLY                                  l',f11f /IIOSCAD) wrTH lfOSCAD}                                                            0 J21 RS232 / RJ45 J2 Front Panel Swrtch Membrane Audra Presence (RED)- Normally off This G)
CD    LED WIii lrght when an audro SJgnai IS Parbal - Normally ori. If all siren amphfiers do not operate property dunng present on the board                                      a tone actJval!on or SI TEST, thlS LED wrll be off If at least one amplrfler operates PTT - Normally off Tors LED will lrght when              proper1y, rt wiU remarn on.
the stabon transmrtter IS active Full - Normally on If a siren amplifier does not operate properly dunng a tone aciJvatlon Squelch - Normally off. Ths LED wrll lrght or SI TEST, thrs LED will be off.
when the stabori is reC8!Vfng a radro broadcast If equrpped with the optional rece1ve tone/squelch tone, the LED WIii
                                                                    @  Rotator - Tors LED wtll llght dunng srren actlvatlon tf the rotor osaliates properly only bght when the r9C8lve frequency and sub-audrble torie squelch frequency tone rs detected                                        Acbve - This LED normally flashes at a rate of once every half seconds When a problem has been detected, thrs LED AC - Normally ori. If no DC voltage was will stop flashing or be off Also rndrcates detected during a SJren tone or SI TEST,                receipt of DTMF data by flashing at a
              !hrs LED will be off.                                    faster rate for about 1 second DC - Normally on If no DC voltage was detected dunng a Siren tone or SI TEST, Fault (RED) - Normally off When a problem has been detected, ttus LED ROTOR thlS LED WIii be off                                      will be on.
NOTE: In some Instances, optional circuit boarm may be located dlract/y above th&Se LED's.
CHARGER REMOTE STATUS INTRUSION                                            AUXCS                    SPARE            L.JGHTS    STROBE 0                                                                                                                                      0 Page 29
 
Fig. 12: Control Board Wire Colors f>1          J5                                                                                0 0  J(]I) (]I) (]I) r  BPOS "O"    RJ46.JN::Y.        0        0                          RADlO 0          0                            iT J1 RBIOTE.lJJDIO                                      MIC JN::i<.
0
                                                ,                                                        BATTERES
                                ~
J21                                                    "I RS232 /RJ45          NOTE: Some older systems 1 WHT/ORN use connectors that wlll not                                              2WHTIORN J2 properly Interface with the                                                3WHT/ORN 4WHTIGRN followlng connectors on                                                    SWHT/ORN 8WHT/ORN replacement control boards*                                                TWHT/GRN
* J14 (Batteries)                                                          1 ORO 2Ya
* J 15 (Charger)                                                          30RN 4BUJ 6V\0 PWRPMPS If the exlsting connector does                            1-5 SWHTIBRN TWHT/ORG not connect to the new board                                              8 WHTIBI.K 9 WHT/YEl.
so that the wires are oriented                                            10WH17GRN as shown, contact Whelen prior to connecting any wires                0                            11WHT/BI.U to the board.
                                                ....                                            ~                                10RG 2Ya 3GRN 4BlU
                                                      ,                I                                      PWR/>Jlf'S 6-10 SVIO 8WHTIBRN
                                                          ~~~~~i TWHT/ORO 8 WlfT/BU(
                                                          .-,:,,jP,;,ranCI OWHTIYEL 1 I.&deg; a  a c 1
IJ10                                                  10WHTIGRN 11 WHT/BLU DIGITAL VOICE 1 RED 2BRN 30RG 4YEI..
6GRN 6BW ROTOR          TORY
                                                                                                                                  !WHT OWHT/B\.K 10WHT/Rell 11 WHTIORG 12 BU<
00                                          10RG 2REO a-tARGm          3 BU(
4GRY 00000 REMOTE STATUS 0                      00                AUXCS                          SPARE    LIGHTS        STROBE 1              0 Page30
 
APPENDIX E Siren Test Result Report
                        /
 
Results from Near and Far-Field Tests of the Outdoor Warning System Near Arkansas Nuclear One 25 Sept 2020 FINAL REPORT Prepared by:
Bruce J. lkelheimer, Ph.D.
Acoustic Analytics Asheville, NC
 
Project Summary Acoustic Analytics was contracted by KLD Engineering, P.C. (KLD) to help perform near-field and far-field acoustical tests of Arkansas Nuclear One's (ANO) outdoor warning system. Testing was conducted on July 23 rd and July 24 th
* 2020_. During thclt period two types of tests were conducted.
The first were near-field ANSI 512.14 tests designed to accurately ascertain the output levels of the sirens. The other, far-field tests were conducted simultaneously to the ANSI 512.14 tests and measured the received sound level in the community, thousands of feet away from the siren. For all tests, the sirens were sounded for one minute, with background noise data collected before and after ea~h sounding at all locations. Seven sirens we_re tested in total, with two Whelen Model WPS2807 sirens and five Whelen Model WPS2907 sirens. All sirens have a pure tone alert signa.I with a frequency of about 560 Hz.
The ANSI 512.14 measurements were performed using a microphone raised to the height of the siren (approximately 50 feet above ground) with a bucket truck. The microphone was positioned 100 feet from the siren and moved slowly during the test. Once all seven sirens were tested, data from similar siren types were combined to determine the expected output for each siren type, displayed in Table 1. In this table, the 'Maximum Level' is the single highest one-second sample, and the 'Average Level' is the arithmetic average of all the one-second samples collected during the siren sounding (about 60 in total). All values are reported using C-weighted values as per FEMA guidelines 1 . More details about C-weighting can be found in Appendix A.
Table 1. ANSI S12.14 final test results Maximum Level            Average*Lev'el Sire!'!
(dBC)                  (dBC)
WPS2907              119.0                  115.5 WPS2&J7              118.6                  115.1 For the far-field tests, sound level meters were set to collect data for at least ten minutes before the sirens sounded and continued collecting data for at least ten minutes after the sirens stopped.
* Meter placement was selected to provide safe, accessible locations for the testers in positions that were expected to have low background noise levels. They were also located in places that initial modeling (based on manufacturer data) predicted would receive siren levels up to 70 dBC. One meter failed to collect any data for two of the tests and in four instances the tests collected unexpectedly high levels of background noise. The rest of the meters collected valid data. The results showed that, for the fifteen valid data points collected, four reported received maximum siren levels above 70 dBC, with the rest report1ng levels below 70 dBC.
1 FEMAsREP-10, "Guide for the Evaluation of Alert and Notlflcatlon Systems for Nuclear Power PlantsH, November 1985.
 
Testing Procedure Acoustic Analytics and KLD collected acoustic data from seven sirens around ANO, with two different types of tests. The first was a near-field ANSI S12.14 test to ascertain the output level of the sirens, and the second was a far-field test to confirm received sound levels in the surrounding community.
Near-Field ANSI 512.14 Test Procedure The ANSI S12.14 standard defines the method for testing omni-directional sirens. The siren sound measurements are performed using a microphone raised to the height of the siren, positioned 100 feet from the siren. KLD provided all of the acoustical testing equipment for this test and Entergy provided a lift truck capable of reaching the required height for the test.
All of the acoustical data were collected using Larson Davis 831 Sound Level Meters 2 (SLM). The SLMs were programmed to record acoustical data at one-second intervals, collecting slow C-weighted sound levels and one-third octave band levels. Each SLM had its calibration checked before and after each test, with at least 30 seconds of calibration tone recorded between each test.
The siren sounding lasted for one minute for each test.
In addition to the elevated microphone extended from the bucket truck, an additional microphone was calibrated and used to determine the maximum sound level experienced on the ground. This measurement was conducted by walking an SLM radially outward from the siren pole during the siren test. Distance from the pole was recorded along with the maximum sound level. This measurement is performed to ensure that the sound levels received at the ground do not exceed recommendations from the Committee on Hearing, Bioacoustics, and Biomechanics of the National Academy of Sciences. These recommendations suggest that no person should be subjected to sound levels above 123 dBC 3
* Weather data were measured locally during the siren tests with a Kestrel Model 4500 Weather Meter. This weather meter is capable of recording wind speed, direction, temperature, and relative humidity. For each siren test, the weather meter was positioned close to the siren, mounted approximately 5 feet above ground level. Results from these measurements are recorded on the ANSI S12.14 datasheets.
Far-Field siren sound test procedure The testing methodology used to measure the far-field siren sound closely follow the ANSI Standard S12.9 Part 34
* This is the governing standard for collecting data from a specific source such as the sound from an outdoor warning system.
2 Larson Davis, "Model 831 Sound Level Meter Operation Manual", 2006.
3 FEMA CPG 1-17, "Outdoor Warning Systems Guide", 1980 4
ANSI $12.9 Part 3 (R2008), "Quantities and Procedures for Descriptions and Measurement of Environmental Sounds.
Part 3: Short-term measurements with an observer present", 2008
 
For these tests, Larson Davis 831 SLMs were used to collect the acoustic data and Kestrel 5500 Weather Meters were used to collect the weather data. For each measurement location, the SLM was mounted on a tripod with the r:nicrophone approximately 5 feet above the ground. The SLMs were programmed to record acoustical data at one-second intervals, collecting slow C-weighted .
sound levels and one-third octave band levels. Each SLM had its calibration checked before and after each test, with at least 30 seconds of calibration tone recorded between each test. The weather stations were mounted on a tripod close to the SLM and programmed to collect the wind speed, direction, temperature, and relative humidity during the test. The siren sounding lasted for one minute for each test.
The observers present recorded the position of the meters relative to all major features, including building and changes in the local terrain. The observers also collected notes during the tests, identifying specific noise or weather events that occurred during the testing. Weather conditions during the test were written down, as were the observed sound levels before, during, and after the sirens sounded: Any significant sounds noticed during the test were also written down. The meters were set to begin recording at least ten minutes before the siren sounding and were left running for at least ten minutes after the siren test ended to collect background noise levels. These procedures were h~nded out to all test participants, and a copy is provided in Appendix B.
Frequency Analysis Frequency analysis of the siren signal is a useful tool in the system analysis. One of the SLMs used for the ANSI S12.14 test had the capability of recording high-quality audio file samples. These audio files were then analyzed using the analysis software, Audacity5
* This software performs a Fast Fourier Tran_sforr:n on the audio signal to determine the frequency content. Figure 1 has a sample frequency spectra for the siren signal as measured from the bucket truck, 100 feet from siren 3~4.
In this plot, the frequency is on a logarithmic scale on the x-axis, and the amplitude is in dB is on the y-axis. Note that they-axes on this plot is not calibrated, but is useful in determining where the maximum frequency occurs. All sirens measured has the same frequency content, with a maximum level at approximately 560 Hz indicative of a pure tone signal.
5 https://www.audac1tyteam.org/
 
    -25dB
    -30d8*
    -33d8*
    -36dB--
    -39dB *
    -42dB *
    -45d8*
    -48dB--
    -51d8*
    -54d8 *
    -57d8*
    -60dB--
    -63dB *
    -66d8*
    -69d8*
    -72dB--
    -75dB *
    -78d8*
    -81dB*
    -87d8 *
    -90dB 2.00Hz  4.00Hz 6.30Hz 10.00Hz 20.00Hz 40.00Hz 100.00Hz    200.00Hz    400.00Hz 1000.00Hz 2000.00Hz Curso9 560 Hz (05) =-36 dB                      jPeak:J559 Hz (C-s) =-25.8 dB Figure 1. Frequency spectra of the Federal Signal 2001-130 siren as measured in the field Another method of analyzing the frequency content of the siren sounds is to look at the One-Third Octave Bands collected by the SLMs. One-Third Octave Band analysis divides the sound into individual frequency bands, with three bands to every octave (or doubling of frequency). Since the frequency of these sirens is approximately 560 Hz, that falls between the 500 Hz and 630 Hz One-Third Octave Bands. This can be seen in the plots of the One-Third Octave Band spectra in Figure 2 with the two peaks at the appropriate frequencies. In this figure, the frequency is on the x-axis, plotted logarithmically, and the amplitude of the siren signal is on the y-axis in dB. In this plot they-axis is from calibrated data, so the values are accurate .
 
120 Siren tone at about 560 Hz - - -~
110 100 90 80 60 50 40
      ,o 20 IIIIIIIIIIIIIIII One Third Octave Band Figure 2. One third octave band spectra for the Whelen WPS2907 Siren Test Results Seven different sirens were measured over two days, with three sirens measured on June 23 rd ,
2020 and four measured on June 24th, 2020. At each siren, a bucket truck was used to complete the ANSI S12.14 measurement. Results from all of these tests are provided below in Table 2.
Simultaneously, three SLMs were placed in the far-field for each test, identified as ANO 01, ANO 02, and ANO 03. These locations were selected close to the estimated 70 dBC sound contour from each siren (based on initial manufacturer data). The tabulated results from these tests are provided in Table 3. For Table 2 and Table 3, the 'Maximum Level' is the single highest one-second sample collected during the test and the 'Average Level' is the arithmetic average of all one-second samples during a siren sounding (approximately 60 in all). The 'LlO Level' on Table 3 is the top 10th percentile of the data. This means that the received sound level was at that level or higher for 10 percent of the siren sounding, or approximately 6 seconds.
When reporting the data from the far-field meters, Acoustic Analytics has plotted two different acoustic metrics. The first is the C-weighted value. However, because of the way that the (-
weighted levels are computed they often include elements that have nothing to do with the siren signal itself. Therefore, the combined 500 Hz and 630 Hz One-Third Octave Bands were also computed. This will often clearly show the siren signal even when the C-weight does not. The
 
combined value is much better at accurately representing the received output from the siren at these far-field locations and this is the value reported on Table 3.
To be certain that a measured signal is attributable to a siren (as opposed to just some other background noise), the measured signal must be at least 10 dB above the background noise. If the siren signal is not 10 dB above the background noise, the received siren level can only be estimated. For these situations, the level is denoted by the less-than symbol(<) to show that the siren signal is less than the value provided on the table. Th is happened to 4 measurements as shown in Table 3. More details about each siren test, including data collection sheets, ANSI 512.14 sheets, and graphs of the acoustic time histories for the collected data are provided in the next section.
Table 2. Results from all ANSI S12.14 tests Maximum Level    Average Level Siren        Model (dBC}            (dBC) 2Z14        WPS2907            116.6            113.1 lZll        WPS2907            118.5            114.3 1Z9
* WPS2807            110.7            107.4 SZ2        WPS2807            118.6            115.1 3Z4        WPS2907            120.3            116.9 3ZS        WPS2907            119.2            116.1 2Z13        WPS2907            120.3            117.2
* Siren 1Z9 had lower than expected output levels.
 
Table 3. Far-field Test Results Siren 2214                                        Siren 1211 Maximum Level      LlO Level Average Level        Maximum Level      LlO Level Average Level Meter                                                Meter (dB)            (dB)        (dB)                  (dB)              (dB)      (dB)
ANO0l          58.2              55.4        52.1    ANO0l        <67              <49        <45 ANO02          73.7              67.4        61.8    ANO02      67.4              64.4        58.6 ANO03          72.7              68.6        61.6    ANO03      < 59              <57        <53 Siren 129                                          Siren 522 Maximum Level      LlOlevel  Average Level        Maximum Level      LlO Level Average Level Meter                                                Meter (dB)              (dB)      (dB)                  (dB)              (dB)      (dB)
ANO0l            -                -          -      ANO0l      58.7              57.5        52.7 ANO02          58.6              56.5        52.1    ANO02      77.1              75.5        70.2 ANO 03        70.1              68.8        61.6    ANO03      67.9              66.3        62.3 Siren 324                                          Siren 325 Maximum Level      LlO Level Average Level        Maximum Level      LlO Level Average Level Meter                                                Meter (dB)              (dB)        (dB)                (dB)              (dB)      (dB)
ANO0l          69.7              68.1        63.6    ANO0l        -                -          -
ANO02          66.7              65.3        60.6    ANO 02      59.5              54.3        52.1 ANO 03        47.8              46.5        43.9    ANO03      61.0              58.6        55.1 Siren 2213 Maximum Level      LlOLevel  Average Level Meter (dB)              (dB)        (dB)
ANO0l        <72              <69        <65 ANO02        60.7              59.1        56.3 ANO03        <53              <52        <50 Summary Acoustic Analytics, with the help of KLD and Entergy, conducted a successful acoustical test of the full outdoor warning system for the ANO outdoor warning system over the two day period from June 23 rd to June 24th 2020. Data were collected from seven different sirens representing two different models. Weather conditions during the test were good, with low winds and no precipitation as measured by weather stations used duing the testing. Five SLMs were used for each siren test. Two SLM was used for near-field ANSI S12.14 measurements and three SLMs were used for far-field measurements. Of the 35 different sets of acoustical data collected over the week, two samples were lost due to equipment malfunction and four experienced elevated background noise levels that made it impossible to determinine the siren level.
Bruce lkelheimer, President of Acoustic Analytics
 
Detailed Data from All Field Measurements This section contains all of the detailed data from the field measurements including graphs, photos, and data sheets. It is useful as a reference for looking at specific siren tests. The data is organized by siren, with the ANSI S12.14 test provided first, followed by the data collected by the far-field SLMs. They are also provided in the order that the testing occurred. Table 4 provi des the date, siren, and GPS location for all of the far-field test locations, with more information provided in each section.
Table 4. Date and locat ion of far-field measurements June 23rd, 2020 Siren 2214, Model Whelen WPS2907        Siren 1211, Model Whelen WPS2907 Meter ID      Latitude    Longitude      Meter ID      Latitude    Longitude ANO0l        35.323279  -93.141710    ANO0l        35.242431  -93.157977 ANO02        35.304833  -93. 119475    ANO02        35.236126  -93.189973 ANO03        35.304651  -93.128141    ANO03        35.223787  -93.165692 Siren 129, Model Whelen WPS2807 Meter ID      Latitude    Longitude ANO0l        35.258326  -93.230217 ANO02        35.250495  -93.207652 ANO03        35.257309  -93.203675 June 24th, 2020 Siren 522, Model Whelen WPS2807          Siren 324, Model Whelen WPS2907 Meter ID      Latitude    Longitude      Meter ID      Latitude    Longitude ANO0l        35.306951  -93.289443    ANOOl        35.333159  -93.245631 ANO02        35.296799  -93.274475    ANO02        35.324876  -93.261671 ANO03        35.287405  -93.294007    ANO03        35.306421  -93.246369 Siren 325, Model Whelen WPS2907        Siren 2213, Model Whelen WPS2907 Meter ID      Latitude    Longitude      Meter ID      Latitude    Longitude ANO0l        35.324739  -93.273720    ANO0l        35.305384  -93. 148826 ANO02        35.324037  -93.244078    ANO02        35.306214  -93.122389 ANO03        35.345280  -93.258734    ANO03        35.313796  -93.135871
 
Field Measurements of Siren 2214 Siren 2214, a Whelen model WPS2907 siren, was measured on June 23 rd , 2020 at approximately 9:50 am. This siren is located across the street from the Darby Lane Baptist Church in Russelville, AR. This siren is mounted on top of an approximately 50 foot wooden pole. Far-field SLM ANO 01 was placed to the north-west of the siren and SLMs 02 and 03 were placed south-east and south of the siren, respectively. This is shown below in Figure 3. The ANSI S12.14 data sheet form this test is provided in Figure 4, with a photo of the siren in Figure 5 and the time history of the measured sound level in Figure 6.
Figure 3. Position of siren 2214 relative to the far-field SLMs
 
Siren Sound Output Measurement per ANSI S12.14 Data Sheet Siren Mfg:    Whelen                                Modal No: WPS2907                            SIN:-----
 
==
Description:==
In situ measurement of ANO siren 2Z14 Meas. Loe. Across the road from a church along the side of a road Date:    6/23/20            Tlme:    9:50 am          ev: Bruce I.                Tille: _ _ _ _ _ _ __
Temp jg_ &deg;F            Wind speed: 5.6 mph            Wind Dir: 320        Clouds    100  % Precip. (YIN)? __N Elevation Sbleh of TNI SI..
100Feet SO Feet Grass Mfg rec'd mtg. height: ....22.... feet Acklal height:  ...aL leet Method: Laser Power correct <Y"')? _ __
Ground type & cover between ann anct meas. 1oc. _G......,ra  ...s..,.s_ _ _ _ _ _ _ __
Deviations from test procedure: _N_o_n_e____________________
SLM Mg: _____l __
D__ Model No: __8_3__1__                            SIN 3174                    Pri Cal Dale:. 3/11/20 Filler Mfg: _ _ _ _              Model No: _ __                    SIN _ _ _ _ __
Pri Cal Dale:.
Calib Mtg: _l_O__                Model No: ca1200                  SIN  15674                  Pri Cal Da1e: .6/19/20 Field Calibration: Before _____        9__4__.0____
d__B__
C_ _            Affer 94.0 dBC Max ambient: Before                    60            dBC slow        Attar          57                            dBC slow Microphone SN: 311593 Preamp SN: 51309                                                          Base Line Position        Secondary Position
                                                                                                          ~
Siren Sound:                                                                    Alert                      Alert MXSCL (max d8C. slow):                                                        116.6 Average SCL, dBC slow:                                                        113.1 Max 1/3 octave band, Hz:                                                500 Hz & 630 Hz MXSCL in max 1/3 octave band, dBC slow:                                        116.5 Average SCL in max 1/3 octave band, dBC slow:                                  112.8 Bystander MXSCL. dBC slow                                                      111                        xxx Dist of bystander MXSCL from mount. feet                                        53                        xxx Other pertinent information: _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ __
Figure 4. ANSI S12.14 Data Sheet for Siren 2214
 
im;~~--*W.MID.&#xa9;W~~'i/@QJijll
                      -~  [oJl!f.112,!;J11(Mj ,- wi-Figure 5. Photo from the bucket truck, looking at siren 2214 130.0
                                                                          -    Measured Siren Level
                                                                          - - - Average Siren Level 120.0 110.0 100.0 u    90.0 a:,
    ~
    "ii
      >  80.0
    ~
70.0 60.0 50.0 40.0 9:43:45AM                9:44:lSAM          9 :44 :45AM  9:45:lSAM                    9:45:4SAM Time Figure 6. Time history of the received sound from siren 2214 as measured from the bucket truck
 
Far-Field Measurement of Siren 2214 from So und Leve Meter ANO 01 SLM ANO 01 was placed by the water in Pleasant View Park. Figure 7 shows the time history for siren 2214, with the siren signal clearly evident above the background noise by at least 10 dB in the combined 500 Hz and 630 Hz signal. Background noise levels in this area were in the 55 dBC to 58 dB range . Figure 8 has the data collection sheet for this meter.
100.0
                                                                            - - - C-Weight
                                                                            -    500 Hz+ 630 Hz 90.0 80.0
                                                    -<--  Siren Signal 70.0 I
I I
iii
      ~    60.0 qj 50.0 40.0 30.0 20.0 9:42:00AM    9:43:00AM      9:44:00AM          9:45:00AM 9:46:00AM            9:47:00AM Time Figure 7. Time history from SLM ANO 01 for siren 2Z14
 
ANO Si ren Test Datasheet
:ro be fllled by support ~
Date:            w~~/"ttJ                                Time:        ~ S'O  fr4" SLM Modef: t.-1) S:31                                    SLM Serial Number:      3 $:$:9 Preamp SN:              <) 8 S-0 b                      Microphone SN:      "3 I OD 8 Ll Tester's Name:              D'",o~c    11,      tY1~1Jao GPS Coordinates: -P\3 *\fr, I                                West ~f.Y~)}:zq                          North Checked Battery? @                  No Checked Clock?                ~ No Memo,y Checked? ~ No Calibration le"81 before teat:              0\ f
* 0        dBC 30 second calibration tone ~ bJ1fOf9 test? ~ No Calibration level after test:              ~~ dBC _
30 second calibration tone recorded after test? (fe, No Calibrator Model:              C#-1 )o O                    Callfntor SN: __t;....',";...._&....iJ_+-_ __
- - - - - - - - - T o be filled In be by the netd crew et the                site---------
Plan View \
      ,....._ (<:an also use proylded map b:>me
                              ~~~-( ~
r, vef Figure 8. Data collection sheet for SLM ANO 01 for siren 2214
 
Far-Field Measurement of Siren 2Zl4 from Sound Leve Meter ANO 02 SLM ANO 02 was placed by the side of Sparksfor Dr. south of its intersection with E. Aspen Ln.
Figure 9 shows the time history for siren 2214. Here the combined 500 Hz and 630 Hz siren signal is clearly evident above the background noise by over 10 dB. Also evident in this time history are the passing of cars - shown as sudden spikes in the received noise level. Figure 10 shows the data collection sheet for this test.
100.0
                                                                                        - - - C-WeJeht
                                                                                        -    500 Hz+ 630 Hz 90.0 Siren Signal 80.0 70.0 I
                        ,,',    ~
iii"
:!:!. 60.0 i', I
                        ~:*.,.,,' \.
                            \ ~
      "ii 50.0 40.0 30.0 20.0 9 :42 :00AM              9 :43 :00AM    9:44:00AM          9:45 :00AM 9:46:00AM            9:47:00AM Time Figure 9. Time history from SLM ANO 02 for siren 2214
 
ANO Siren Test Datasheet
      -~!'9'7r---7..------To be filled by support ltaff- - - - - - - - -
Oate: _ _ _~....~-).._).Q____                              Time:                          '] ~CO              f"'
SLM Model:            ~ D 8 '3 I                            SLM Serial Number:                                              '33C) 7 Preamp SN:          5 I } :t e                            Microphone SN:                                                3 o7 72 k Tester's Name: .&+f..._t_CJy~<11\....d"'-r'---- - - - - - - - - - - - - - -
GPS Coordinates:_'l_~_.__      1;p  ________ Weat __-q                                          _____~__.__1__1._____ North Checked Battery?      ~              No Cheeked Clock?        ~ No Memory Checked? ~ No Calibration level before test:                '\  *':14-*O dBC 30 second calibration tone recorded before test?                            Q                  No Calibration level after test:                    f:
* Ci\ f dBC 30 second calibration tone recorded after test?                          &                  No Calibrator Model:        ~, }DO                                  Calibrator SN: _ _l_~_~._7._+                                  ____
- - - - - - - - - : r o b e n11ed In be i,y the field aew at the                                              site---------
Location Drawi
.------------------  Plan View
                                                                                  -----------------~      Major Elevation Changea (C.n also use provided map to martc locatlOn)
Measurement Location description: ..              O'-f'pb~-O~i...d---=.-"...,:._-s,f,,l,.,=~a..;t'_.r.;.,;f,&lc/.....;.,.P..;;..r_ _....,.._ __
Microphone height:c t : ft.                                                                                            VYind Dir: N\A/ 31'2. deg.
Photos Taken?                            No                                                                            VYind Spd: _<_.1__ mph Meter Recording? Y                    No                                                                              Temp*      f'( ,q      *F Weather Station on and wind cover removed? ~                                              No Ambient noise level before test: _ _~_,_._'\______ dBC                                                                                        ~
Maximum level observed duri~the tNt:                        ,.,                                    dBC ""'i'"" 0,,-                  ~            'ti Could you hear the sirens? (!!] No Ambient noise level after test:                      6g                                            dBC Notes about test (including background noise and noise intrusions during the test):
Tester's Signature:  ---i~l'Jill---~------------------
Figure 10. Data collection sheet for SLM ANO 02 for siren 2214
 
Far-Field Measurement of Siren 2Z14 from Sound Leve Meter ANO 03 SLM ANO 03 was placed by the side of Steel City Ln, about halfway down the road . Figure 11 shows the time history, with the combined 500 Hz and 630 Hz siren signal is clearly visible above the background noise. Background noise before and after the test was approximately 65 dBC. The data sheet for this test is shown in Figure 12.
100.0
                                                                                      - - - C-Welght
                                                                                      -    500 Hz + 630 Hz 90.0
_ . . _ Siren Signal -
80.0 70.0 ii        .,'''\ /
      ~    60.0 "ii QI 50.0 40.0 30.0 20.0 9:42:00AM            9:43:00AM      9:44:00AM          9:45 :00AM  9:46:00 AM            9:47 :00AM Time Figure 11. Time history from SLM ANO 03 for siren 2Z14
 
ANO Siren Test Datasheet Date:    g>>-L :::=  to                  To be nlled by support:::
Time: __:1.{_;......._
                                                                      !{1C
                                                                        ..,,.,,..""'1.....,.._ _ __
SLM Model:        r()      3 31
                      \ , I 3 '2 SLM Serial Num~                              4: ). 7 f Preamp SN:                                        Microphone SN:                              3c, 7 3 'J b Tester's Name: -(b.:M:%~ &#xa3;A~\                    "3 ,et,\'1:;
GPS Coordinates: 'i .3,Jl'.}18fJ1                      West 1-&#xa2;. +K 14'~                                  North Checked Battery? ?fij No                -q3, Id i\41 \..I          , , . , o .+ b'> I "1 Checked Clock?        ~ No Memory Checked? Y-!I No Calibration level before test:          &deg;14-        dBC 30 second calibration tone recorded before test? y&sect;i No Calibration level after test:        q4, /          dBC 30 second calibration tone recorded after tnt? '@) No Calibrator Model:          Cc..l ~o                  Calibrator SN: _('l_lo...;.7_.4-_ _ __
- - - - - - - - - - T o be nned              In be by the netd crew  at the Sit---------
Location Drawi
......-------------- Plan View Major Elevation Changu cc.n also use provided map to mark IOcatlon)
Ye:~ LI'-
                            ~
                ~
                      ,,  f
                      ~
                            ~
V\
Measurement Location description:
Microphone height:        ?,O        ft.
toot@~'!{:                        Et                    In Dir:
L S't<Jt!Ls~L-..
                                                                                                          ~ZS'  deg.
Photos Taken?          &;)      No                                                        VVlnd Spd:      ? ,4  mph Meter Recording? Yea No                                                                    Temp:        f,4 .o  *F Weather Station on and wind cover removed? Q N o Ambient noise level before test:                        U,            dBC Maximum level obMrved during the t*t:                1:3, *"l:        dBC Could you hear the sirens? ~ No Ambient noise level after test:
* h  4          dBC
~ ~b:\~J~~~~nd~~ ~ ~ ~ t t r ~ > = w r                                                                          ~t.
Tester's Signature: ' )  \w.n.t".'\ :')\M\
Figure 12. Data co llection sheet for SLM ANO 03 for siren 2214
 
Field Measurements of Siren lZll Siren 1211, a Whelen model WPS2907 siren, was measured on June 23 rd , 2020 at approximately 10:50 am. This siren is located by the corner of N. 2nd St. and East St. in Oardenelle, AR. This siren is mounted on top of an approximately SO foot wooden pole . Far-field SLM ANO 01 was placed to the north-east of the siren, SLMs 02 was placed to the west of the siren, and 03 was placed south-east of the siren . This is shown below in Figure 13. The ANSI S12.14 data sheet for this test is shown in Figure 14, with a photo of the siren in Figure 15 and the measured time history of the test in Figure 16.
Figure 13 Position of siren 1211 relative to the far-field SLMs
 
Siren Sound Output Measurement per ANSI S12.14 Data Sheet Siren Mfg:    Whelen                                Modal No: WPS2907                        SIN: _ _ _ _ __
 
==
Description:==
In situ measurement of ANO siren 1211 Meas. Loe. Measurement is across a small road from the siren, close to a da care facili Data:    6 23 20            Time: 10:50 am 8'f: Bruce I.
 
==Title:==
Temp M_ &deg;F              Wind speed: ...Q__"1)h Wind Dir:_:__ Clouds                100  % Precip. (YIN)? _.N....___
Elevation Slceleh of TNI SIie 100 Feet 50 Feet Grass                                  Grass Mfg rec'd mtg. height: _2Q_ feet Actual height: -2,L laet Method: Laser Power COO'eCt (Y,1>-0? _ __
Gr0IAld type & cowr between siren and meas. loc.
Deviations trom teat prooedure: _N_o_n_e____________________
Grass and asphalt SLM t.tg: ___L=D__              Model No: ....,8.,.3..,l_ _    SIN  3174 SIN _ _ _ _ __
Pri Cal Oata:.3/11/20 Filtar Mfg:____                Model No: _ _ __                                              Pri Cal Date:
eub Mtg:  _Lo___              Model No: ca1200                SIN  1S674                  Pri Cal o.::6/19/20 Field Calibration: Before _ _ _    9..,3.,.,9.,_d.,B.._c_ __  After 94.o dee Max ambient: Before _ _ ____... 6 .._5_ _ dBC slow          After          65                              dBCslow Microphone SN: 311593 Preamp SN: 51309                                                      Base Line Position        Secondary PoatiQn JiUlllsa Siren Sound:                                                              Alert                        Aled MXSCL (max dBC, slow):                                                  118.5 Awrage SCL. dBC &low:                                                    114.3 Max 1/3 octave band, Hz:                                          500 Hz & 630 Hz MXSCL In max 1J3 octave band, dSC slow:                                  118.S Awrage SCL in max 1/3 octave band, dBC slow:                              114.2 Bystander MXSCL. dBC slow                                                  113                          xxx Dist of bystander MXSCL from mooot, feet                              92' and 35'                      xxx Otherperlinent inf0ffl'l8tion: _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ __
Figure 14 ANSI S12.14 Data Sheet for Siren 1211
 
          ~~'iiblil5ll'im..!lm l~~ in~*
          ~~/~U~ni~
          ~~~~
          ~~
          ~~~ ~
          ~~~
          ~~~
si Figure 15. Photo from the bucket truck, looking at siren 1211 130.0
                                                                          -    Measured Siren Level
                                                                          - - - Average Siren Level 120.0 110.0 100.0 90.0 i~
1  80.0
      ~
70.0 60.0 50.0 40.0 11:09:45AM            11:10:lSAM      11:10:45AM        11:11:lSAM                  11:11:45AM Time Figure 16. Time history of the received sound from siren 1Z11 as measured from the bucket truck
 
Far-Field Measurement of Siren 1Z11 from Sound Leve Meter ANO 01 SLM ANO 01 was placed close to a boat ramp at the end of Old Post Park Rd. The time history from this measurement is shown in Figure 17. In this case there is no evidence of the siren in the C-weight, while it does appear that there is siren signal in the 500 Hz and 630 Hz signal. However, because that level is not consistently 10 dB above the background, it is not possible to determine what portion of that signal comes from the siren and what is from the background noise. The data sheet for this test is shown in Figure 18.
100.0
                                                                                  - - - 500 Hz + 630 Hz
                                                                                    -    C-Weight 90.0 80.0 Probable
                                                      ,... _    Siren Signal ~
70.0 ii"
::!:?. 60.0
      "'ii
        ~
50.0 40.0 30.0 20.0 11:08:00 AM    11:09:00 AM    11:10:00AM              11:11:00AM 11:12:00AM            11:13:00AM Time Figure 17. Time history from SML ANO 01 for siren 1211
 
ANO Siren Test Datasheet
: 7.                    To be filled by support~
Date:          pl?- '313.D                              Time:        10:00 o.~
SLM Model:        kl) r ~ i                            SLM Serial Number:          >S~g Preamp SN:          S: 8 S- o b                        Microphone SN:              -,,, Dd'J j Tester's Name:              l,e,(' ;t lie,      ~  llc"'
GPS Coordinates: - O\ '; *I 5 7 5 7 7                      West    ~ S . ~ 4}. 'l 3 I          North Checked Battery? 'lea No Checked Clock?            " - No Memory Checked?
* No Calibration level before test:            q f *I        dBC 30 second calibration tone recorded before test? ~ No Calibration level after test:              ~ 1.J        dBC 30 second calibration tone l'9COfded after teat? ~ No Calibrator Model:          ( -1 ~ o                      Calibrator SN:      I 'l t, 7 +
  - - - - * - - - - ~ T o be tllled In be by the field crew at the              stt.---*----- -
Location Drawi
  ---------                Plan  View Major Elevation Changu (can also use provided map ID mark location)
Microphone height:
Photos Taken?
* Meter Recording?
                          !:ft.
Measurement Location description:
e No No
                                                ?t1t: ~::i}sibN:d o..                  &deg;Sir' c~JCtd:t,, sc4 i:i:~ '(~)r~
(,b6-\S. Wnd Dir:    ~
Wnd Spd: ~ mph Temp: "ls$
deg.
                                                                                                              *F
                                                                                                                                    ~ -*
Weather Station on and wind cover removed?                  ~ No Ambient noise level before teat            63                          dBC :'Tb ( t 0<) ,          ,
* Maximum level observed during the test: '-36-2.                          dBCW M- w &-i:k ~
* t'b"I ~ (} ' -~ ~
* Could you hear the sirens?              (fjj . No
* Ambient noise level after test:              "23                        dBC No.tes.Jlbolilt te1~including ba                  no_i1.e and noise iptrUSiOnl~
                                                                              -    during ltle telt):6-J<aS1 ~i ( Qd..aiek.
    ~ \ <0? C.k\lf \ ~ ~ ~ ~ ~ ~ ~ , s ; ; ( n < -\'\.){O, tq                          ~a:\-ratn.a.J~1,t<+> -t-+ur 1 ,<l;.
    ~~                  C            f              Ii\. * ,v~CQ..(l,i}, ( \ v 1r -~ &deg;!* -CC)"):,Jr~i2i,/ tr1J ~~ ~          -~
* 1 Tester's Signature:r,,,;;;.,.:.a.1:..i.o..i.. :x.::~...;..J,jl.llC~---------==-&#xa3; :4".i.i::.....c::>Q1 _-t, ,l~  -" ., '.t.-'f'I .
                                                                                                                      , tdg r -
figure 18. Data collection sheet for SLM ANO 01 for siren 1211
 
Far-Field Measurement of Siren lZll from Sound Leve Meter ANO 02 SLM ANO 02 was positioned close to the intersection of Rte 51 and Hillside Dr. The time history from this test is shown in Figure 19, with the comined 500 Hz and 630 Hz siren signal clearly evident above the background level. Background levels at this location was around 55 dBC. The test data sheet is provided in Figure 20.
100.0
                                                                            - - - C-Weight
                                                                            -    500 Hz+ 630 Hz 90.0 i
Siren Signal - '
80.0 70.0 ai
      ~    60.0
      'ii Q) 50.0 40.0 30,0 20.0 11:08:00AM    11:09:00AM      11:10:00AM        11:11:00AM  11:12:00AM            11:13:00AM Time Figure 19. Time history from SLM ANO 02 for siren lZll
 
ANO Siren Test Datasheet
      - - - - - - - - - T o be fllled by supportstatlblf'lffr----------
Date: Q(;,/'l2  I :z.020                              Time: ....Jt_:"I_~_ _ _ _ _ __
SLM Model:      f... 0 I} I                            SLM Serial Number: _ __..,... 3_.'l._.7__
Preamp SN:          5: I };  O                        Microphone SN:              ; o 71 7 h Tester's Name:_.$,.,....~1"'~W::'-----------------
GPS Coordinatea:____.~....S....,t_,,!t_____ VVest_..q........,J_.1....i&deg;'-------NOfth Checked Battery? Yee              No Checked Clock?            Yes      No Memory Checked? Yes No calibration level before test:              C\ q. *\      dBC 30 second calibration tone recorded Calibration level after test:
::'en "l i_E teat?
dBC
                                                                @        No 30 second calibration tone recorded after test? 'lej No Calibrator Model:          (.,.) >oo                                                      ! ____
calibrator SN: ______I_S-_&t_..7...
- - - - - - - - - T o be nned In be by the field crew at the                    site---------
Location Orawin :
Plan View                                              Major Elevation Changu ccan also use provided map to mark location)
Measurement Location description:            tJ:....~" *{              H:P.i,J*  .-J ~ - OP!' .f?tlo-Microphone height:          ?            ft.                                      W i ~W 1'10'deg. ~* . .
Photos Taken?            @          No                                          Wind Spd: l .1            mph      ,    **
Meter Reeotding?        t:!&sect;J)    No                                              Temp: 'R,2,S              *F    :
* Weather Station on and wind cover removed?                  @s        No Ambient noise level befote test:                      52                  dBC Maximum level observed duri~ teat:                        ,.,              dBC Cou~you~arthesirens?                  \t!J      No    'll                                        s:..... .f.J,.,i: UJ?.~
Ambient no1Se level after teat:
                                >>:                  S7..                  dBC Notes about test (including background noise and noise Intrusions during the test):
Tester's Signature:
                                                                                                ~ ;,~    f,J: 1. ~:.ZJ 0,,1, E...ls 0w-y;1 d,.,;1 ....)T Figure 20. Data collection sheet for SLM ANO 02 for siren 1211
 
Far-Field Measurement of Siren 1Zll from Sound Leve Meter ANO 03 SLM ANO 03 was located in a large parking lot close to the busy road Rt. 22. Unfortunately because of the busy road, the elevated background noise made it almost impossible to identify the siren signal in the time history (shown in Figure 21). Background levels in this location were in the low 60s dBC. The data sheet for this test is shown in Figure 22.
100.0
                                                                                          - - -C-Weight
                                                                                          -    500 Hz +630Hz 90.0 80.0                                                          Possible Siren Signal 70.0
      =
      ~    60.0                I._
                                      ..,,,.r ti        .,,,*' , .....,
      ~
50.0 40.0 30.0 20.0 11:08:00AM                        11:09:00AM 11:10:00AM      11:11:00AM  11:12:00AM          11:13:00AM Time Figure 21. Time history from SLM ANO 03 for siren 1211
 
ANO Siren Test Datasheet Date: 6 / z }l to to
                              - - - - T o be filled by support Time:
staff----------
iO ', J oe..-
SLM Model:          L.Q      jll                          SLM Serial Number:              f'").7 f Preamp SN:              l~  13,                              Microphone SN:                '30 7 3 ')  b Tester's Name: 2.Lw e1:+ "'is '"- A:>::i::u4)            1 *1&#xa3;1/4&#xa5;j:
GPS Coordinates: - q '3.\ ~S-- (,'} ~                            West      3&#xa3;, ). }. 3 t B7              North Checked Battery?            &i1      No Checked Clock?              ~ No Memory Checked? ~ No                              a Calibration level before test:                    * ,4 *I      dBC 30 second calibration tone recorded before test?                    '@      No Calibration level after test:                  C\4. \        dBC 30 second calibration tone recorded after test?                    ~        No Calibrator Model:            (""'    4'00                      Calibrator SN:              ( ') lei 14-To be fllled In be by the  ne1c1 aew at the S l t e - - - - - - - - - -
,-------------------. Plan View Location Drawing:
Major Elevation Changes (can also use provided map to mark location)
Measurement Location description: ?,50 :fm(                      erv,t    &deg;f  iltt Z,t Microphone height:            &#xa3; 'v            ft.                                        Wind Dir.        , ,o 5 deg.
Photos Taken?              ~          No                                              \Mnd Spd:        <<>o      mph Meter Recording?          t~.        No Weather Station on and wind cover removed?                      ~        No Temp:        B~-~        *F Ambient noise level before test:                        64                  dBC Maximum level observed duri~ test:                          t 6.'k          dBC Could you hear the sirens? Q:!!) No Ambient noise level after test:
Notes atx,ut test (including backgl"Qund
~      ~,'f.Q. is  c_ l,,f\  ~ C\. wti:i--JIYY" t'tltl
                                                        = 63                  dBC and noi~ intrusions during the test):
t Rf.e U . \Jir.\.v.e,\l,~ f tW-    ~ ... ~It)
J
                                                                                                              'Z,-~~l.t"llPS Tester's Signature: s. b          """"'"1'; "'-'~    ':) \o ~
Figure 22. Data collection sheet for SLM ANO 03 for siren 1211
 
Field Measurements of Siren 129 Siren 1Z9, a Whelen model WPS2807 siren, was measured on June 23 rd , 2020 at approximately 12:00 pm. This siren is located on Bay Ridge Dr. in Dardenelle, AR, next to the Lion's Den Golf Course . This siren is mounted on top of an approximately 50 foot wooden pole. Far-field SLM ANO 01 was placed to the west of the siren, SLMs 02 was placed to the south-east of the siren, and 03 was placed east of the siren. This is shown below in Figure 23. The measured output from this test were significantly lower than other similar models of siren suggesting there may be a maintenance issue with this particular siren. After the testing Acoustic Analytics learned that the siren had, in fact, suffered damage (possibly from a lightning strike) and was repaired shortly after the testing was completed. The ANSI S12.14 data sheet is provided in Figure 24, with a photo of the siren in Figure 25 and the measu red time history in Figure 26.
Figure 23. Position of siren 129 relative to the far-field SLMs
 
Siren Sound Output Measurement per ANSI S12.14 Data Sheet Siren Mfg:    Whelen                        Modal No:      WPS2807                                SIN: _ _ _ __
Oe1Cf1)tion:  In situ measurement of ANO siren 129 Meas. Loe. Measurement alon the side of a road next to a olf course Oas:      6 23 20          Time:  12:00 pm    By:  Bruce I.                        Tide: _ _ _ _ _ _ __
Temp_&sect;&sect;_ &deg;F            Windspeed:_Q__q,ti Wind Dir:_:__ Clouds                        100  % Precip.(Y/N)?_N    _____
Elwatlon Sketch ofT* SIii 100 Feet SO Feet Grass Mfg rec'd mtg. height: ...2Q_ feet Actual height:~ feet Method: Laser Power conect (Y.t4)? _ __
Ground type & COY8f' between sken and meas. loc. _G&#xa5;+'r....
a &#xa3;.,.S_ _ _----:----.,...,....---,-
Oevialions from test prooadura: There appearedto be some repairs or modification to this siren. One of the bird screens was a different size than the others.
SLMMlg: LO                    ModelNo:    831                SIN 3174                            PriCalDal8:.3/11/20 Filter Mfg:____              Model No:___                  SIN______                            Pri Cal Date:
CalibMtg: LP                  Model No:  ca1200            SIN  15674                          Pri CaJ Data::6/19/20 Field Calbration: Before          94.0 dBC                  AAer.94.,,....0_,d...B.,.C..,__________
Max ambient: BefORI                53      dBC slow        Afler _____5__6_________ dBC slow Microphone SN: 311593 Preamp SN: 51309                                                  Base    Line Position            Secondary P06ition
                                                                                                          .ti1.Jlasn Siren Sound:                                                                Alert                          Aflrt MXSCL (max dBC, slow):                                                    110.7 Avvrage SCL dBC slow:                                                    107.4 Max 113 octave band, Hz:                                        500 Hz & 630 Hz MXSCL in max 1/3 oclave band, dBC slow:                                  110.9*
Avvrage SCL in max 1/3 octave band, dBC slow:                            107.3 Bystander MXSCL, dBC slow                                                  119                            xxx Dist of bystander MXSCL from mooot. feet                                    52                            xxx Other pertinent information:
* The fact that the 500 Hz & 630 Hz appears higher than the C-welghted level Is an artifact of the sound level meter's processing and Is within the experimental error.
Figure 24. ANSI S12.14 Data Sheet for Siren 129
 
            ~~~*.!mil
            ~        ~-oo m ~ v~~@.U &#xa9;'IDV 1~@>'t!W'W <<::tn~
            ~aK?~nia
            ~~
            ~--~
            ~*                . ~-4$1,,
Figure 25. Photo from the bucket truck, looking at siren 129 130.0
                                                                              -    Measured Siren Level
                                                                            - - - Average Siren Level 120.0 110.0 100.0 u      90.0 ID 1      80.0
      ~
70.0 60.0 50.0 40.0 12:12:30 PM          12:13:00PM        12:13:30PM        12:14:00 PM                12:14:30PM Time Figure 26. Time history of the received sound from siren 129 as measured from the bucket truck
 
Far-Field Measu rement of Siren 1Z9 from Sound Leve Meter ANO 01 This SLM was placed close to the intersection of Rte. 406 and Rte . 22. Because of an equipment malfunction, no data was collected from SLM ANO 01 for this siren.
Far-Field Measurement of Siren 1Z9 from Sound Leve Meter ANO 02 This SLM was placed at the intersection of Bay Ridge Rd. and Marina Rd. The time history from this tests is shown in Figure 27, with the data sheet provided in Figure 28. As identified in the data sheet (and as is clearly obvious in the time history), three cars passed by the meter during the siren sounding. This briefly artificially elevates the received sound level and does not accurately represent the siren signal. Therefore, those portions of the data were removed when computing the siren characteristics. Despite the intrusion of the cars, the siren signal is clearly evident above the background noise, which is in the low 60 dBC range for this location.
100.0
                                                                            - - - C-Weight
                                                                            -    500 Hz+ 630 Hz 90.0                                                                With car data included 80.0 70.0 iii"
        ~    60.0 "ii
        ~
50.0 40.0 30.0 20.0 12:11:00 PM    12:12:00 PM    12:13:00 PM      12:14:00 PM  12:15:00 PM            12:16:00 PM Time Figu re 27. Time history from SLM ANO 02 for siren 129
 
ANO Siren Test Datasheet
                                  - -- To be fi lled by $t1Pl)Ol't staft!----------
Date:  ab/11,,/    1 O,Z. 9                          Time:      \1~011 SLM Model:        L C> S~ i                          SLM Serial Number:_...,3.._}....        9...7___
PreampSN:            S--1 }4o                        Microphone SN:                  30-717
* Tester's Name: ef, "f~cr GPS Coordinates:____.1,"'S:;...._2_?_ _ _ _ _ West                ~3. 2.l                            North Checked Battery? Yes No Checked Clock?          Yes No Memory Checked? Yes No Calibration level before test:          &deg;'- 4*(}      dBC 30 second calibration tone recorded before test? ~ No Calibration level after test:              vi (c,.,I' dBC 30 second calibration tone recorded after test? ~ No Calibrator Model:        C"' ) ").c)O                    Calibrator SN: ___l_S"_~                    t ___
                      - - - T o be ftlled In be by the neld aew at the site--
Location Drawin
~-------------------,Plan View
                                                                ..--~--------------,
Major Elevation Changes (can also use provided map to mark location)
Measurement Location description: frjAJ1c,              !  A,!b, .-0,,\- ~~(              *"-4      "" 4      N~,"M ,..,J ~
Microphone height:        ;-          ft.                                            \i\'ind Dir: /JV) ~ t'1.. deg.      Q{t!....
Photos Taken?        ~                                                                \i\'ind Spd:          0    mph Meter Recording? ~ No                                                                  Temp:          ~Sc!<<        &deg;F Weather Station on and wind cover removed?                  ~      No Ambient noise level before test:                St>                      dBC Maximum level observed duriN-the_t_eat_        :  --~-2---- dBC ,                    \ ~4,-    &deg;"~ po**"- I,,,~ ~        ~  O..f" Could you hear the sirens?        \!:J      No Ambient noise level after test:                  S'f                    dBC Notes about test {including background noise and noise intrusions durinq the test):                            B;,/5  ~ ~
Tester's Signature: _ _ _
                                      <d.77
                                          .                        3t:SA
__._(t-==-,..,_*--------------1-,....    '::::......_c:M,~
_______.!!n.......,    _ _ __
41.t        lj1ti ,/~II:.
Figure 28. Data collection sheet for SLM ANO 02 for siren 129
 
Far-Field Measurement of Siren 1Z9 from Sound Leve Meter ANO 03 This SLM was in a cul-de-sac at the end of Birdie St. The siren signal is clearly evident above the background noise shown in the time history in Figure 29. Backgroun d noise levels in this location were in the low 60 dBC range. The data sheet for this test is provided in Figure 30.
100.0
                                                                                  - - -C-Weight
                                                                                  -    500 Hz+630 Hz 90.0
                                                -<    Siren Signal 80.0 70.0 iii
:!:!. 60.0 "ii
      ...I so.a 40.0 30.0 20.0 12:11:00 PM    12:12:00 PM    12:13:00 PM            12:14:00 PM 12 :15:00 PM          12:16:00 PM Time Figure 29. Time history from SLM ANO 03 for siren 129
 
ANO Siren Test Datasheet Date:
      - - - - - - - - - : r o b e filled by support btU l 2 ow staff---------
                                                                      ) \e_o______
Time: ___, .....
SLM Model:        t,.. I)      ~3 I                  SLM Serial Number: __f_)._.7...,B_ __
Preamp SN:              I'i, 13    b                  Microphone SN:          }O 73'l
* Tester's Name:        7144,p:f:,r)j CA~) 1" :<<-**?J:
GPS Coordinates:        -q3 .'M 3 b 75*                    Welt      ?&sect;. lf7)tt~                  North Checked Battery?          Gs No Checked Clock?            'flp No Memory Checked? ... No Calibration level before test:                :J I 4,      dBC 30 second calibration tone recorded before test? ~ No Calibration level after test:                  0\4-. I dBC 30 second calibration tone recorded after test? ~ No Calibrator Model:        l. .... ) )cc                    Calibrator SN: _ _      l _~-~...7...f _ __
- - - - - - - - - - - T o be filled In be by the field aew at the            sl*~ --------
Location Drawing:
.-------------------. Plan View Major l!levatlon Chang*
(can also use proylded map to mark location)
Measurement Location description:                J\.u,. .f414    ctt: fbv4:, Cr: a,t, , tow,;rL4 m p. M                ~
Microphone height:              .; *o      ft.                                    Wind Dir:        299    deg. t'\l,l~
Photos Taken?            ~ No                                                    \Mnd Spd:        t, \  mph Meter Recording? Yes No                                                          Temp:            $9 . l &deg;F Weather Station on and wind cover removed?                    (i;)  No Ambient noise level before test: _ __.~.,_5&deg;..,_____ dBC Maximum level obeerved during the test:                3:9.9            dBC Could you hear the sirens? ~ No Ambient noise levef after test:                        6Y                dBC
                                                                                                                        ~ 1t.e Notes about tnt (includina background ,n ol~nd noise intrusions ~uring the test): 't
~ l"J...ifJ'J.,,bC r- V\.)&#xa3;\ 7J., ,~ .~ c:....J+il\J}      w., M~1 , \ t \S, ~'l.,O'f" IC1,<.A ~          m-, ~*,c.">t'
* Tester's Signature:          )    k  '>i- 1 ~:J ::S \. :4:':2S Figure 30. Data collection sheet for SLM ANO 03 for siren 129
 
Field Measurements of Siren SZ2 Siren 522, a Whelen model WPS2807 siren, was measured on June 24 th , 2020 at approximately 8:40 am. This siren is located on Rt. 393 between Oak Rd. and Riverside Dr. in Illinois Township, AR. This siren is mounted on top of an approximately 50 foot wooden pole. Far-field SLM ANO 01 was placed to the north of the siren, SLMs 02 was placed to the east of the siren, and 03 was placed south-west of the siren. This is shown below in Figure 31.
Figure 31. Position of siren 522 relative to the far-field SLMs
                  /
 
Siren Sound Output Measurement per ANSI S12.14 Data Sheet Siren Mtg:    Whelen                        Modal No:  WPS2807                        SIN: _ _ _ __
 
==
Description:==
In situ measurement of ANO siren 522 Meas. Loe. Measurement across a road near a farm.
Date:    6/24/20          Time:  8:40 am        By:  Bruce I.
 
==Title:==
Temp.l!_ &deg;F            Wind speed:  2.5  mph Wind Dir:  100    Clouds _Q_ % Precip. (YIN)?_.N...__ _
Elwation SUld'I of T... Sill 100 Feet SO Feet Grass                                  Grass Mfg rec'd mtg. height: ..2Q_ feet Actual height: _9_ leet Method:    Laser      Power conect (YIN)? _ __
Ground type & COYel' between siren and meas. loc. Grass and asphalt Deviations from lest procedura: _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ __ __                                        _
SLM Mtg:      LO              Model No: __8__
3__
1 __      SIN  3174                    Pri Cal Oal8:. 3/11/20 Filter Mfg:                  Model No: _ __            SIN _ _ _ __
Pri Cal Data:
Calib Mtg:    LP              Model No: ca1200          SIN  15674                  Pri Cal Oa: :6/19/20 Field Calibration: Befora        94.0 dBC              Mer  94.0 dBC Max ambient: Befora _ _ ___.._    5 ....
2 __ dBC slow      Mer            56                              dBCslow Microphone SN: 311593 Preamp SN: 51309                                              Base Line Position        Seconda,y posjtjon fil.Jlll5a Siren Sound:                                                        Alert                        Alert MXSCL (max dBC, slow):                                            118.6 Average SCL dBC slaN:                                            115.1 Max 1'3 octave band, Hz:                                    500 Hz & 630 Hz MXSCL in max 1/3 octave band, dBC slow:                            118.6 Average SCL in max 1/3 octave band. dBC slow:                      104.6 Bystander MXSCL dBC slow                                            116                          xxx Dist of bystander MXSCL from mount, feel                            47                          xxx Other per1nent information: _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ __
Figure 32. ANSI S12.14 Data Sheet for Siren 522
 
            ~~Lfi:&sect;1,~/.l!)ij l~l&~
m*:ii.--.~~
            ~~
            &,q Figure 33. Photo from the bucket truck, looking at siren 522 130.0
                                                                            -    Measured Siren Level
                                                                            - - - Average Siren level 120.0 110.0 100.0 90.0 u
Ill
    ~
    'ii    80.0
    ....II 70.0 60.0 so.a 40.0 9:06:4SAM          9:07:lSAM        9:07:4SAM          9:08:15 AM                  9:08:4SAM Time Figure 34. Time history of the received sound from siren 522 as measured from the bucket truck
 
Far- Field Measurement of Siren 5Z2 from Sound Leve Meter ANO 01 Ths SLM was placed on the side of the road on Riverside Rd. The siren signal is clearly evident in the time history provided in Figure 35. Background noise levels in this location were in the mid 50 dBC range. The data sheet for this test is provided in Figure 36.
100.0
                                                                                              - - -C-Weight
                                                                                                -      500 Hz +630Hz 90.0 80.0 70.0
:!:!. 60.0 "ii
        ~
                                                                \' . . ,,, ' t~
I , ,.._ 1 \I ' \ -,'- ,._,
                                                                                                      ~' ,.,",, ,. .,.,'",,,,
                                                                                              , ... ,,,,, ,,    '1 *
* 50.0 40.0 30.0 20.0 9 :0S :30AM    9:06 :30AM    9:07 :30AM      9:08 :30AM                    9:09:30AM                9 :10:30AM Time Figure 35. Time history from SLM ANO 01 for siren 522
 
ANO Siren Test Datasheet
                          ,")                          *To be fifled by support mfr Date:          Gz/4~?-o                                          Time:            1;30    9:c'!'
SLM Model: kQ ~ 1 I                                              SLM Serial Number:                  ~ s--s-g Preamp SN: 5:i: S:o &                                            Microphone SN:          }I 0,,; ')
Tester's Name:                D"    c ~ t-1 le..    '""&deg;") l4'"
GPS Coordinates: - ~ *} ~'\ 4f~                                      West ~f. '0 bct",' I                          North Checked Battery? ~ No Checked Clock?                ~ No Memory Checked? 'NI No Calibration level before test:                    "7 41            dBC 30 second calibration tone recorded before test? Y)i) No Calibration level after test:                    'j "&deg;* 0        dBC 30 second calibration tone recorded after test? Yo) No Calibrator Model:              CA I )co                            Calibrator SN: _..._1__
                                                                                            .r;-...:i:,_7.....4-_ _ __
  - - - - - - - - - T o be l'Hled tn be t,y the fleld crew at the                          stte---------
Location Drawing:
      ~                    Plan View                                        _  '9 ~ -~*jor Elevation Changes n also use provided map to martt                              "&deg;1' _-\
(;,'<ff                  - ~-                                                    "'\
        ~ ....                              ~                                          ~
    ~ J("... s
    ..I --- c7':~                  .
                                                                                            /+\
qJs        ">'s,1                                            -~-~?- \
i    \              ..\--    (~                                                    ~*\- \_
              ,\.'                        ~              -                  -
et, ~              "          r-:;,C- -      --'                .)                                            \
    '"'I-- ------            ---- - - -                                                                          \
Measurement Location description: ~ff:V\                                \aue i:Oie- ,ooq                      m  ~deanai    ~ ~l Microphone height: ~ f t . ~ -t-reeS                                                      Wind Dir: 6 IO\ dig.
Photos Taken?                    es No                                                  Wind Spd: J* 'R mph Meter Recording?                es No                                                    Temp:              %          *F Weather Station on and wind cover removed? ~ No Ambient noise level before test: $3                                                  dBC
* Maximum level obeerved during the tett: ' 2 , $"                                    dBC Could you hear the sirens? @                          No Ambient noise levet after test:                  S::3                              dBC Notes about test (including background 119ise and notJIJI intrusions during the test): {ot5 dt-brro\sc~
...- ~~~ - t:n~f3..Y -W-"l.Qc.,,nJ'.VH1tt? l-&#xa5;' ~1YfoU-n,,.
Tester's Signature: lla n:::<R1J'- ~11 allc:u Figure 36. Data collection sheet for SLM ANO 01 for siren 522
 
Far-Field Measurement of Siren 5Z2 from Sound Leve Meter ANO 02 This SLM was placed in the Delaware Park Public Use Area. The time history for this SLM is provided in Figure 37, with the siren signal clearly rises above the background noise. From the data sheet shown in Figure 38 it appears that a car pulled up close to the meter shortly after the test. This is also evident in the time history as the peak in noise shortly after the siren sounded. Fortunately this did not impact these measurements. The background noise in this area was in the low 50 dBC range.
100.0
                                                                                                                                            - - -C-Weieht
                                                                                                                                            -    500 Hz + 630 Hz 90.0
                                                                                              . Siren Signal 7
80.0 I
II 70.0                                                                                                            11 I I                                                                                                    I    I I 1                                                                                                    I      I I 1                                                                                                    I      I iii'        I 1
      ~      60.0        I 1
                                                                                                                        ,,I          I I
      'ii                  \
I
                                                                                                                                        \
        >                                                                                    I Qj                    1 I
                                  \,
                                          .                        I *
                                                                        "i ll          I \ I
                                                                            "' \,,',,' l '
50.0 40.0 30.0 20.0 9:0S:30AM                        9:06:30AM                                9:07:30AM            9:08:30AM                  9:09:30AM              9:10:30AM Time Figure 37. Time history from SLM ANO 02 for siren 522
 
ANO Siren Test Datasheet
      - - r - r - - - , - - - - - -
* T o be ftlled by support 11:ltalllllffr----------
Oate:        "1'}):f/~
              ;                                            Time:      ?i3'2""tr' SLM Model:          L- D &sect;-\ I                            SLM Serial Number: _          _.1-3...9...,7......___
Preamp SN:            S- I },t.o                          Microphone SN:                }97771>
Tester's Name: ....EQ:..,.__tpg__.,.._r_ _ _ _ _ _ _ __,,.,,,---------
GPS Coordinates:___1__5__....,f\""""""C.__.1_ _ _ _ _ West -1'~ , .l."J'f (p                                          North Checked Battery? 'iii No Checked Clock?            ~ No Memory Checked? ~ No Calibration level before test:                "14: .i)        dBC 30 second calibration tone recorded before test? ~ No Calibration level after test:                  e*H  ,o      dBC 30 second calibration tone recorded after test? ~ No Calibrator Model:          C"'J );90                          Calibrator SN: _      ___,;l....S'"_.~....7....4..___ __
- - - - - - - - - T o be filled In be by the field crew at the                        slte---------
Location Drawi
.------------------. Plan View Major Elevation Changes (Qin also use provided map to mar1<
location)
Measurement Location description: -'t];_,_,,"""-J"""c_&\.___B'-""..-UJ.,s...._~  t ______,.__,,,..--,--
Microphone height            5            ft.                                        Wind Dir:                  N001      deg.
Photos Taken?            rr!l          No                                              Wind Spd:                    _0
____ mph Meter Recording?      @              No                                                Temp:                    '79        &deg;F Weather Station on and wind cover removed?                      @      No Ambient noise level before test:                        Su                dBC Maximum level obaerved duri~ te8t: ___                      rn,
                                                                .2._____ dBC Could you hear the sirens?            ~          No Ambient noise level after test:                        5"'1                dBC Notes about test (including background noise and noise intrusions during the test):                                    O"' ''I. 'o:,J.1 Tester's Signature:                        ~
                                            ,,:,6;:7                                                                      ~ '""'<J ~,,f A    ~.. ~        *,. .:.                ,J,...,"  rJlfd Olfff
                                                                  ~~ J.. ~ ~*'* .Q.. IJ. 1...-f. IM}., ,rt:;.1 Figure 38. Data collection sheet for SLM ANO 02 for siren 522
 
Far-Field Measurement of Siren 5Z2 from Sound Leve Meter ANO 03 This SLM was placed towards the end of Western Shores Drive. The time history from this test is shown in Figure 39, with the data sheet in Figure 40. The siren signal is clearly visible above the background noise, with the background noise level in the mid 50 dBC range. The data sheet for this test in provided in Figure 41.
100.0
                                                                                                              - - -C-Weight
                                                                                                              -    500 Hz +630 Hz 90.0 80.0 70.0 iii
      ~    60.0 "ii f',. . ,. , ,"''{-, \ r
                                                              \            \      '
      !l            -                  \ . , , , , , *\,,'" "''''-""I\ ,1 \ 11" I
                                                                              \
so.a 40.0 30.0 20.0 9:05:30AM                          9:06 :30AM                      9:07 :30AM      9:08:30AM 9:09:30AM            9:10:30AM Time Figure 39 . Time history from SLM ANO 03 for siren 522
 
ANO Siren Test Datasheet
      - - - - - - - - - - T o be tilled by support                staff*- --------
Oate:          kz (>-4,/ rO                            Time:          7 ~ 3o    &deg;' ...,..
SLM Model: L-0 i ~ I                                  SLM Serial Number:          4) 7  8 Preamp SN:            l 'i l '3 b                    Microphone SN:            30    7 3') (,
Tester's Name: j~AA:1,,,,          M ( ~ ) 1 *,et,H}:
GPS Coordinates: -q 3 1d- ".I 4t?(1J                        West    s 5'. ):B 1 +o              North Checked Battery? ~ No Checked Clock?            .... No Memory Checked? Y~ No Calibration level before test:          .?\3 . "I      dBC 30 second calibration tone recorded before test? ~ No Calibration level after test:          &deg;l  I <J      dBC 30 second calibration tone recorded after test?              -6'    No Calibrator Model:          (-..\ ')oo                    Calibrator SN: _ _l_~_~_7_+-    _____
- - - - - - - - - - T o be ftlled In be by the fleld crew at the 111stte.__ _ _ _ _ _ __
Location Drawing:
,-----------------,    Plan View Major Elevation Changes (can also use provided map to mart(
location)
Measurement Location de6cription: .... ,goo* sc:u;e...          ,t Wwm :swc.,            Pc,  uwtu< "i"W'P-,
Lr Microphone height:            Li .a      ft.                                    Wind Dir:      ti~ deg. N,~~
Photos Taken?              (fi;>    No                                          'MndSpd:          o  mph Meter Recording? Yes No                                                          Temp:        1',&83*F Weather Station on and wind cover removed? ~ No Ambient noise level before test:                  $5                    dBC Maximum level observed duri~ teet:                      '2l:z '\        dBC Could you hear the sirens? (!!Y No Ambient noise level after teat:                      Pb                dBC Notes about test (induqing background noiff --~ noise intrusions during the test):
~    ..;.~1, ~ ~ ~                  A. 1-Wt:t re~          MIA .
Tester's Signature:)        k0\ VX    1        1  \ '1A4; Figure 40. Data collection sheet for SLM ANO 03 for siren SZ2
 
Field Measurements of Siren 3Z4 Siren 324, a Whelen model WPS2907 siren, was measured on June 24th , 2020 at approximately 10:15 am . This siren is located on Fleetwood Rd, London, AR, about3/4 of a mile north-west of Akransas Nuclear One. This siren is mounted on top of an approximately 50 foot wooden pole. Far-field SLM ANO 01 was placed to the north of the siren, SLMs 02 was placed to the north-west of the siren, and 03 was placed south of the siren. This is shown in Figure 41 below. The ANSI Sl2.14 data sheet is provided in Figure 42, with a phot of the siren in Figure 43 and the acoustic time history of this test shown in Figure 44.
Figure 41. Position of siren 324 relative to the far-field SLMs
 
Siren Sound Output Measurement per ANSI S12.14 Data Sheet Siren Mtg:    Whelen                            Model No:    WPS2907                        SIN: _ _ _ __
 
==
Description:==
In situ measurement of ANO siren 324 Maas. Loe. Measurement along the side of a small road.
Daw:      6/24/20          Time:  10:15 am        By:  Bruce I.              Tdla: _ _ _ _ _ _ __
Temp ..&sect;2.. &deg;F        Wind speed:~,.-.            Wind Olt: _Q__      Clouds  _g_ %      Precip. (Y/N)? _N  _____
Elevation Suleh of Teet SIii 100 Feet -
SO Feet Grass Mfg rec'd mtg. height: _fill_ feet Actual height:_&#xa3;/_ feet Method: Laser Power correct (YIN)? _ __
Ground type & cover between siren and meas. loc. -'G_,._,.ra_s__
s _ _ _ _ _ _ __
Deviations from test procedure: _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ __
SLM Mfg:      LO              Model No: . .a:8=3-=1__          SIN 3174                    Pri Cal Dat/1:.3/11/20 Fitter Mfg:                  Model No: _ __                  SIN _ _ _ __
Pri Cal Date:
Calib Mfg: LO                Model No: Cal200                SIN  15674                  Pri Cal Oata::6/19/20 Field Cabation: Before            94,0 dBC                    After 93,9 dBC Max ambient: Before _ _ _ _4,...,8,.__ dBC slow                After          48                              dBCslow Microphone SN: 311593 Preamp SN: 51309                                                    Base line Position        SecOf)dary posjtion
                                                                                                    .!it.JllmU Siren Sound:                                                              AJert                        AIQrt MXSCL (max dBC, slow):                                                  120.3 Average SCL dBC slow:                                                  116.9 Max 113 octave band, Hz:                                          500 Hz & 630 Hz MXSCL in max 1/3 octave band, dBC stow:                                120.1 Awrage SCL in max 1/3 octave band, dBC slow:                            116.7 Bystander MXSCL, dBC slow                                                114                          XXX Dist of bystand9r MXSCL from mount. feet                                  92                          XXX Oth8rper11nentinformatlon: _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ __
Figure 42. ANSI S12.14 Data Sheet for Siren 324
 
Figure 43. Photo from the bucket truck, looking at siren 324 130.0
                                                                          - - - Average Siren Level 120.0 110.0 100.0 90.0 u
GI
    ~
    "ii  80.0
    ..J 70.0 60.0 50.0 40.0 10:32:4SAM          10:33:lSAM        10:33:45AM        10:34:lSAM                  10:34:45 AM Time Figure 44. Time history of the received sound from siren 324 as measured from the bucket truck
 
Far-Field Measurement of Siren 3Z4 from Sound Leve Meter ANO 01 This SLM was placed in the corner of a baseball diamond, close to the corner of Old Wire Rd . E. and Hays Ln. N. The siren signal does rise above the background noise when viewing the 500 Hz and 630 Hz signal (as shown in Figure 45). Background noise in this area was in the low 70 dBC range, probably driven by the presence of 1-40 nearby. The data sheet for this test is provided in Figure 46.
100.0
                                                                          - - -C-Weight
                                                                          -    500 Hz+ 630 Hz 90.0 80.0 70.0 iii"
      ~      60.0 "ii QI
        ...I 50.0 40.0 30.0 20.0 10:31:00AM    10:32:00AM    10:33:00AM      10:34:00AM  10:35:00AM          10:36:00AM Time Figure 45. Time history from SLM ANO 01 for siren 324
 
ANO Siren Test Datasheet
      - , - . . - - - . . - - - - - - ~ T o be ftlled by suppo,t statr*----
Oate:      ',h-A /'HJ                                Time:          9f}O ... ,,...
SLM Model;        {  D ii 3 I                        SLM Serial Number:            *~ ~  8 Preamp SN:            t; g ,;-,o b                    Microphone SN:            ~ / o <.: 'Z> 1 Tester's Name:              UP-e:; d!<        IY'\"'}1'2.-,.
GPS Coordinates: -0\1,d- 4 t, lo~I                        West '\S-, '\131~5                    North Checked Battery? Y,s No Checked Clock?            'Gs No Memory Checked?          t,s      No Calibration level before test:          P\A-. O        dBC 30 second calibration tone recorded before test? ~ No Calibration level after test:              4.
                                        'j 0          dBC 30 second calibration tone recorded after test? '<Ml No Calibrator Model:          (A./ ,-co                    Calibrator SN:      IS-~ 14
- - - - - - - - -
* T o be nned In be by the field crew at the Site--
.--------------......                              Location Drawin :
Major Elevation Changes I
I Figure 46. Data collection sheet for SLM ANO 01 for siren 324
 
Far-Field Measurement of Siren 3Z4 from Sound Leve Meter ANO 02 This SLM was placed on Hill Blvd ., close to its intersection with West Dr. The siren signal time history is provided in Figure 47 and the measurement data sheet is provided in Figure 48. The siren signal is evident above the background noise, with the background noise in the low 60 dBC range.
100.0
                                                                            - - -C-Weight
                                                                            -    500 Hz + 630 Hz 90.0
                                                      --  Siren Signal 80.0 70.0 al
:!:!. 60.0
      'ii 50.0 40.0 30.0 20.0 10:31:00AM    10:32:00AM      10:33:00AM      10:34:00AM    10:35:00AM            10:36:00AM Time Figure 47 . Time history from SLM ANO 02 for siren 3Z4
 
ANO Siren Test Datasheet Date:
      - - . - - - - - - - T o be ftlled by support ah{l1/JD2P                                      Time:
staff-*--------
p:10 SLM Model:      L. Q $:'>I                              SLM Serial Number: __'3...,3...9.._7_ __
Preamp SN:            ~ I } +o                            Microphone SN:                                    16 777 &,
Tester's Name:      'ft      =,-'"""'r GPS Coordinates:          35 .12~'\                                                                                      North Checked Battery? )'" No Checked Clock?          ~ No Memory Checked?        "e          No          .,
Calibration level before test:          "l 1, O              dBC 30 second calibration tone recorded before test? ~ No Calibration level after test:            ""14  ~            dBC 30 second calibration tone recorded Calibrator Model:        ( .._ J ~ 0 after  test?              '(!!)
Calibrator SN:
No l ~' 14-      __
nned In be by tne field crew at the                    stt---------
- - - - - - - - - T o be
,--------------.....                                  Location Orawi                __.,.__
Plan View                                                                Major Elevation Changu (can also use provided map to mark locatlon)
                  -;: I
                  ~
i;...
Photos Taken?
W=ft.
Measurement Location description:
Microphone height:
Y e No No
_.O&-tpt!l,..-..--#-<f....d"----~--*._fl-._/.c......_{"""'.....  .,_,
A ,"""'*__      __,,.___
Wind Dir: IJIJW lr~eg.
                                                                                                          'Nind Spd: 6, (
Temp:        f2  .o mph
                                                                                                                                  *F Meter Recording?
Weather Station on and wind cover removed?                        @              No Ambient noise level before test:                        5'.'1_                          dBC                        "-40'-ld -lrl Maximum level observed duR9 tat:                            1,,,f                      dBC                            36.32.'141\ -  q;:(~ t,G Could you hear the sirens? ~ No                                                                                    I,.,,_.          1 Ambient noise level after test:                      5  ! 5                            dBC                                __..
Notes  about  test (including      background    noise      and      noise      intrusions            during    the  test):
                                  ~                                                                0-,.,. '--'1 wrO,              .JJ.. ,-,*,c-..,
Tester's Signature: - - . . . . . ~ - - - * - - - - - - - - - - - - - -
Figure 48. Data collection sheet for SLM ANO 02 for siren 324
 
Far-Field Measurement of Siren 3Z4 from Sound Leve Meter ANO 03 This SLM was placed in the cul -de -sac at the end of Sta r Harbor Rd . The time history for this test is shown in Figure 49 with the data sheet provided in Figure 50. The 500 Hz and 630 Hz signal is moe then 10 dB above the background noise, where the levels were in the high 40 dBC range.
100.0
                                                                              - - -C-Weight
                                                                              -    500 Hz+ 630 Hz 90.0 80.0 70.0 L- Siren Signal ----.
iii"
:!:!. 60.0 ti 50.0 40.0 30.0 20.0 10:31:00AM    10:32:00AM    10:33:00AM      10:34:00AM      10:35:00AM          10:36:00AM Time Figure 49. Time history from SLM ANO 03 for siren 324
 
ANO Siren Test Datasheet Cate:    1/4,vpo:)l)                              To be fll~:.~pport              it-;~--~
SLM Modef: 1-D 'i'1>1                                        SLM Serial Number:___,,...4-....  ~....
Z.. S_ _
Preamp SN:        I q ,:3&                                  Microphone SN:                  3073') ~
Tester's Name: ~t14 ( A(!),14) 1,e.Nt GPSCoordinates: - Cj3.)-+(e31,')                                        West    3S.1Cb,4))                North Checked Battery? @                No Checked Clock?          ~ No Memory Checked? 'Qa No Calibration level before test:              &deg;'\4- ,0              dBC 30 second calibration tone recorded before test? '@ No Calibration level after test:                v) f. v dBC 30 second calibration tone recorded after test? '(js No Calibrator Model:      ( .... I };oo                                Calibrator SN: _ _1_>-=b_7....:4:..-_ __
      - - - - - - - T o be filled In be by the fleld crew at the                        site----------
,_ ___________        Plan View Location Drawing:
Major Elevation Chango (can also use provided map to mart<
      ~                  location)
                  ~ r Hc.>.(\;,or ~
Measurement Location description: :rt,, 4 flt'f,~                      P\  ',to, t-4&#xb5;(1;,Q < 84    <e:t ~ ~-tfptxe of t'lP Microphone height:        tz. 0        ft.                                              Wind Cir:      4 I deg .Stllr ffr.k.-
Photos Taken?          {&sect;)          No                                                    Wind Spd: \-4        mph r<eA)
Meter Recording? ~ No                                                                      Temp:      i3 *l      &deg;F Weather Station on and wind cover removed?                              fi_;;>  No Ambient noise level before test:                            so                    dBC Maximum level oblerved du~e teet:                              t;I,, t            dBC Could you hear the sirens?          l'!.!IJ    No Ambient noise level after test:                    4  ""+-                      dBC Notes about test (including background noise and noise intrusions during the test):
V~ ~~,.t.t tl((Q\ , ~        ~~ c,..-o-c4o- ~",,,,\ f,o,.._ ~ ~ooun.41'1) {(U .L Tester's Signature:  _J_    te+w"l<<\ ::S'\Ao&(
Figure SO. Data collection sheet for SLM ANO 03 for siren 324
 
Field Measurements of Siren 3ZS Siren 325, a Whelen model WPS2907 siren, was measured on June 24th, 2020 at approximately 11:15 am. This siren is located on Hwy 64, just west of the junction with Old Hwy 64 Win London, AR. This siren is mounted on top of an approximately 50 foot wooden pole. Far-field SLM ANO 01 was placed to the south-west of the siren, SLMs 02 was placed to the south-east of the siren, and 03 was placed north of the siren. This is shown below in Figure 51. The ANSI Sl2.14 data sheet is provided in Figure 52, followed by a photo of the siren in Figure 53 and the measured time history in Figure 54.
Figure 51. Position of siren 325 relative to the far-field SLMs
 
Siren Sound Output Measurement per ANSI S12.14 Data Sheet Siren Mtg:    Whelen                        Model No:  WPS2907                        SIN: _ _ _ __
 
==
Description:==
In situ measurement of ANO siren 325 Meas. Loe. Measurement on the side of a bus road, alon a dirt road with some shrubs.
Date:    6 24 20          lime: 11:15 am By: Bruce I.
 
==Title:==
Temp_&sect;&sect;_ &deg;F            Wind speed: ...Q_~ Wind Dir:...:,__ Clouds _Q_ % Precip. (YIN)? _.N              _____
Elevallon Slleletl of T..a SIii 100 Feet so Feet DlrtRoad Mfg rec'd mtg. height: ..2Q_ feet Actual height: .2Q_ feet Method: Laser Power cooect (YIN)? _ __
Ground 1ype, COY9I' between siren and meas. toe. Grass. dirt road. and shrubs Deviations from teat procedure: _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ __
SLM t.tg:    LO              Model No: _8_3_1_ _        SIN 3174                      Pri Cal Oala:_3/11/20 Fbar Mtg:                    Model No: _ __            &N_____                      PriCalOale:
Calib Mtg: LO                Model No:  Cal200          &N 15674                      Pri Cal Oale: :6/19/20 Field Cali>ration: Before        93.9 dBC              Ahet93.9dBC Max ambient: Before _ _ ___._7=3__ dBC slow              Ahet          75                              dBC slow Microphone SN: 311593 Preamp SN: 51309                                              Base line Position          Secondary Poeition
                                                                                                ~
Siren Sound:                                                      Alert                          Alert MXSCL (max dBC, slow):                                          119.2 Awrage SCL. dBC slow:                                            116.1 Max 113 octave band. Hz:                                    500 Hz & 630 Hz MXSCL in max 1/3 octave band, dBC slow:                          119.2 Awrage SCL in max 1/3 octave band, dBC slow:                      116.0 Bystander MXSCL dBC slow                                          114                            xxx Dist of bystanc>>r MXSCL from mount. feet                            92                            xxx Othef per1inent Information: _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ __
Figure 52. ANSI S12.14 Data Sheet for Siren 325
 
Figure 53. Photo from the bucket truck, looking at siren 325 130.0
                                                                            -    Measured Siren level
                                                                            - - - Average Siren Level 120.0 110.0 100.0 90.0 u
a:i j    80.0
    ~
70.0 60.0 50.0 40.0 11:33:15 AM          11:33:45AM        11:34:15 AM        11:34:45 AM                  11:35:15 AM Time Figure 54. Time history of the received sound from siren 325 as measured from the bucket truck
 
Far-Field Measurement of Siren 3Z5 from Sound Leve Meter ANO 01 Because of an equipment malfunction, no data was collected from SLM ANO 01 for this siren.
Far-Field Measurement of Siren 3Z5 from Sound Leve Meter ANO 02 This SLM was placed on Rte. 333, just to the east of some train tracks. The time history for this test is provided in Figure 55. The 500 Hz plus 630 Hz signal from the siren is over 10 dB above the background. Also visible in this plot are peaks generated by cars passing, fortunately not during the siren test. The background level (when cars were not present) is in the mid 50 dBC range. The data sheet for this test is shown in Figure 56.
100.0
                                                                                                  - - -C-Weight
                                                                                                  -    500 Hz +630 Hz 90.0                              ,,J.
80.0                            ,,,,                    .      Siren Signal I I I I I I 70.0 iii
::!:!. 60.0 Ii II          ,,v ..... ',' "
50.0 40.0 30.0 20.0 11:31:30AM                        11:32:30AM  11:33:30AM        11:34:30AM    11:35:30AM          11:36:30AM Time Fig&#xb5;re 55. Time history from SLM ANO 02 for siren 325
 
ANO Siren Test Datasheet
      - - - - - - - - - : r o b e ftlled by supportsWf.---------
Oate:  b/2.'i  /'J!l1.&                                  Time:              lt:2'!,
SLM Model: &.,I) 'I~ I                                  SLM Serial Number: __,_1_'\..,.7___
Preamp SN:          '>' I ')-4o                          Microphone SN:                30777 '1 Tester's Name:          ft        -rui&!r GPS Coordinates:              1;. 12. 'CO                    West ~'t. Vf'{ (                  North Checked Battery? ~                  No Checked Clock?              Gs      No Memory Checked?            'M        No Calibration level before test:            &deg;'.) 4.0        dBC 30 second calibration tone recorded before test? Y@ No Calibration level after test:                ') 4 ~      dBC 30 second calibration      tone  recorded      after test?      (ii) No Calibrator Model: C~          I  &#xa3;PO                          Calibrator                        _ _ __
SN: __l_t;"_&__i __4-
- - - - - * - - - -
* T o be filled In be by the fleld aew at the Site---------
Location Drawina:
Plan View                                                  Major Elevation Changee (Can also use proylded map to mark location) l
                            \
Measurement Location dnaiption: _O_f!'_l}__              d...._d1\__trr-
__    R.il
__          ~~.
                                                                                  ~.,J_ _ _
Microphone height:            ~          ft.                                                              deg.
Wn~i Photos Te,ken?          ~                                                              WndS :            mph Meter Recofding? ~ No                                                                  Temp:              *f Weather~ on and wind cover removed?                            @          No Ambient noise level before test: ___5_?                .a......=--,,---- dBC Maximum level observed duri~ test:                        9-/.!,              dBC Could you  hear  the    sirens?      ~        No Ambient noise level after teat:                      5l/ :                  dBC Notes about teat (ind&#xb5;ding background noise and l1()iae intrusions during the test):
                                                  ~,I~ .                                    0,,t~ bi,<}-;.
Tester's Signature:    ------~-_e,.,___________
(/
Figure 56. Data collection sheet for SLM ANO 02 for siren 325
 
Far-Field Measurement of Siren 3Z5 from Sound Leve Meter ANO 03 This SLM was placed at the end of Rock ln. The time history is provided in Figure 57 and the data sheet is in Figure 58. The 500 HZ and 630 Hz combine signal clearly shows the siren more than 10 dB above the background noise, which was in the mid 60 dBC range .
100.0
                                                                            - - - C-Weight
                                                                            -    500 Hz + 630 Hz 90.0 80.0                                        Siren Signal 70.0 cc
      ~    60.0 "ii
      ...J 50.0 40.0 30.0 20.0 11:31:30AM    11:32:30AM    ll:33:30AM        11:34:30AM  11:35:30AM            11:36:30AM Time Figure 57. Time history from SLM ANO 03 for siren 325
 
ANO Siren Test Datasheet
      - - - - - - - - -To be ftlled by suppo,t *IUl~rF' - - -- - -- - -
Date:    ~(2!:ll:l,QR                                  Tme:            (l:OCJ SLM Model: L. 0 83 I                                    SLM Serial Number:            41-7      S Preamp SN:          l '\ I ~    b                      Microphone SN:                '.} 7 ~ Cf&#xa3;,
0 Tester's Name:    ?Ji,,,  ,&M*~ ( Atfl1) ,tu\{4:    1 GPS Coordinates: -"13,)?~ 73-t                              West 3S-,"34W                                North Checked Battery? '11is No Checked Clock?          '(js No Memo,y Checked? 'th No Calibration level before test:              &deg;}{I t) dBC 30 second calibration tone ~ before test? '(je No Calibration level after test:                l 4-, \)    dBC 30 second calibration tone recorded after test? '6J) No Calibrator Model:        ( .... j }DO                    Calibrator SN: __l....~      ;...;le~J+..____
- - - - -- - - - T o be ftlled In be                    by the field aew It the dll~----
te                    -----
~ - - - - -Plan          - View- - - - - -Location                Drawi Major Elevation Changes (Can also use provided map to mane loeatlon)
                                                        ,,, a ioa,t t:U\AA!'Sl:' A I Q(.tl\ v Microphone height:
Photos Taken?
Meter Recording?
i Measurement Location description:
                          ~
CJ c No No ft.
Weather Station on a a wind cover removed?
I acrtod
                                                          @          No Wind Dir:
Wind Spd:
Temp:          ~, .o
                                                                                                              +M-
                                                                                                          ~t;tj.
3,2
                                                                                                                  &#xb5;yJ.. o,\ ~ le:.
deg.
mph
                                                                                                                  *F lf\ .
Ambient noise level before test:                ~'l.                    dBC Maximum level observed during the tat:                blcl              dBC Could you hear the sirens?          a-        No Ambient noiae level after test:                        $                  dBC Notes about test (Including background noiae and noiM Intrusions during the test):
\ . \ ~ r,.. olo'a ~ ;"1 *~ ~ ~ ~b\ ~ \~ i,,fl..t\ vJ>.b ~                                                      .
Tester's Signature:  ) L:-Yi:~ ::J\M=,r Figure 58. Data collection sheet for SLM ANO 03 for siren 325
 
Field Measurements of Siren 2213 Siren 2213, a Whelen model WPS2907 siren, was measured on June 24 th , 2020 at approximately 1:00 pm. This siren is located near the corner of Reasoner Ln . and N. Arkansas Ave in Russelville, AR, next to a fire department. This siren is mounted on top of an approximately 50 foot wooden pole . Far-field SLM ANO 01 was placed to the north-west of the siren, SLMs 02 was placed to the north-east of the siren, and 03 was placed north of the siren. This is shown below in Figure 59. The ANSI S12.14 data sheet is provided in Figure 60, with a photo of the siren in Figure 61 and the measured time history in Figure 62 .
The decision to measure this siren was made while in the field to add an additional test after siren 1Z9 appeared to be having a maintenance issue. Unfortunately, this meant that there were limited supplies, so the testers had to resort to hand-written datasheets rather than the pre-printed version usually employed.
Figure 59. Position of siren 2Z13 relative to the far-field SLMs
 
Siren Sound Output Measurement per ANSI S12.14 Data Sheet snn Mfg:      Whelen                              Model No:        WPS2907                        SIN: _ _ _ _ __
 
==
Description:==
In situ measurement of ANO siren 2213 Meas. Loe. Measurement across grass In front of a fire department.
0a1e:    6/24/20            Time:  1:00 pm e-,: Bruce I.
 
==Title:==
Temp  JlL &deg;F          Wind speed: _2_mph Wind Dir: ~                      Clouds _ L % Precip. (Y/N)? _N        _____
Elevation Sulctl of TNt SIie 100 Feet SO Feet Grass Mfg rec"d mtg. height: ..fill_ feet Actual height ~ feet Method: Laser Power corract (Yh-,1)? _ __
Ground type & cover between siren and meas. loc. _ Gllll.&.lra...,s""'
s _ _ _ _ _ _ _ __
Deviations from lest procedure: _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ __
SLM t.tg: ___L=D__            Model No: -"8__  3=1__              SIN 3174                      Pr1 Cal D*: .3/11/20 Filler Mfg: _ _ _ _            Model No: ____                      SIN _ _ _ _ __
Pri Cal Data: .
Calib Mfg: _L_p__              Model No:      Cal200              SIN  15674                    Pri Cal Data: .6/19/20 Field Calibration: Before _ _ _    9_3...,9...d_B_c___            Arter 93.9 dBC Max ambient: Before                66            dBC slow        After          69                              dBC slow M icrophone SN: 311593 Preamp SN: 51309                                                          Base Line Position          Secondary Position
                                                                                                          <it usect>
Snn Sound:                                                                    Afet:t                      Alert MXSCL (max dBC, slow):                                                      120.3 Average SCL. dBC slow:                                                      117.2 Max 1/3 octave band, Hz:                                              500 Hz & 630 Hz MXSCL in max 1/3 octave band. dBC slow:                                      120.2 Average SCL in max 1/3 octave band, dBC slow:                                117.0 Bystander MXSCL, dBC slow                                                      114                          XXX Dist of bystander MXSCL from mount. feet                                        72                          XXX Other pertinent information: _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ __
 
Figure 60. ANSI S12.14 Data Sheet for Siren 2213 Figure 61. Photo from the bucket truck, looking at siren 2213
 
130.0
                                                                          -    Measured Siren Level
                                                                          - - - Average Siren Level 120.0 110.0 100.0 90.0 uCD
      ~
      "ii  80.0
        !l 70.0 60.0 50.0 40.0 1:03:45 PM        1:04:15 PM      1:04:45 PM          1:05:15 PM                  1:05:45 PM Time Figure 62. Time history of the received sound from siren 2213 as measured from the bucket truck Far-Field Measurement of Siren 3Z5 from Sound Leve Meter ANO 01 This SLM was placed a pull out along Lake Front Dr. Unfortunately, t his location was close to 1-40 which resulted in elevated backgrou nd noise levels. There is no obvious siren signal in the time history shown in Figure 63, with the background in the mi d 70 dBC range. The hand-written data sheet is provided in Figure 64.
 
100.0
                                                                                                                                - - -C-Weight
                                                                                                                                - - 500 Hz + 630 Hz 90.0 Possible Siren Signal    --->-
80.0
                                            ,              *                                  !      i          ,,
                                            't 70.0  I
                    ~*
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                                                    , 1 I It 1I , ), .._'\I r"'-\
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                                                                                    ,*,,"'' '\r, , ,,I'
                                                                                                                  ',I I
iii'
~    60.0 ai
~
50.0 40.0 30.0 20.0 1:02:00PM                      1:03:00 PM                            1:04:00 PM                      1:05:00 PM        1:06:00PM            1:07:00 PM Time Figure 63. Time history from SLM ANO 01 for siren 2213
 
C\4,1  J~ re.\ - sO        ~<'.C
.. q1 . \ If~ 8>\, '-"  ',-, ) 0}' ~ ~ if- ~
Figure 64. Data collection sheet for SLM ANO 01 for siren 2213
 
Far- Field Measurement of Siren 3ZS from Sound Leve Meter ANO 02 This SLM was placed at the corner of Cain Ave. and E. Aspen Ln. The time history is provided in Figure 65 with the data sheet in Figure 66. The 500 Hz and 630 Hz combined signal clearly shows the siren soun ding over 10 dB above the background noise. There is clearly an intrusion in the C-weighted levels at the beginning of the siren sounding, but it did not appear to impact the 500 Hz and 630 Hz combine signal.
100.0
                                                                                                                                                    - - - C-Weight
                                                                                                                                                    -          500 Hz +630 Hz 90.0
                                ,,,                                                                        ~
I
                                                                                                              -ir-        Siren Signal -
80.0            I I I I I I II  , ,
I I                                                                    1"' ,, *' I\
                                                                                                    't .,. i I    1, 70.0        I I      11 I
                                                                                      \
I I
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                                                                                    ,, '                              I
                          '                                                        I 1'1  I
        =
        ~    60.0    I I
I
                                                                                                                                                                                ,' v,'
                                        \ /\,._/    , "...                      I                                                                                              I
        'ii                                                                \                                                              \
CII 50.0 40.0 30.0 20.0 1:02 :00 PM                            1:03 :00 PM                        1:04:00PM                      1:05:00PM              1:06:00PM                          1:07:00 PM Time Figure 65. Time history from SLM ANO 02 for siren 2213
 
II
  'f SSW      .ZH, 4,fAyt,..,
                                                              '8'f.20~
Figure 66. Data collection sheet for SLM ANO 02 for siren 2213
 
Far-Field Measurement of Siren 3Z5 from Sound Leve Meter ANO 03 This SLM was placed on the side of an unnamed road just north of Elliot Pl., off of Rte. 7. The time history is provided in Figure 67, with the hand-written data sheet provided in Figure 68.
Unfortunately, the siren signal was not clearly visible in the time history and was not 10 dB above the background noise. Background noise in this area was in the mid 60 dBC range.
100.0
                                                                                    - - -C-Weight
                                                                                    -        500 Hz+ 630 Hz 90.0 80.0
                                                      . Possible Siren Signal I I I \
                                                                                        ,,,I
* 70.0                                                                      ~ ,,
I    I iii                                                                \
                                                                            . , ,,I
      ~    60.0 "ii CII 50.0 40.0 30.0 20.0 1:02:00 PM    1:03:00PM      1:04:00PM      1:05:00PM            1:06:00PM                  1:07:00 PM Time Figure 67. Time history from SLM ANO 03 for siren 2213
 
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                                                                                        ;'&deg;'
* Figure 68. Data collection sheet for SLM ANO 03 for siren 2213
 
Appendix A- Acoustics, Perception, and the Weighting Scales Perception of sound involves two main factors - amplitude and frequency. Amplitude is the measure of the sound's volume, while frequency is often described as the 'pitch' of the sound. For amplitude, sound is generally described using the logarithmic decibel scale, which uses the symbol dB. The 'd' is lowercase to represent 'deci' for a factor of 10, and the uppercase 'B' comes from the proper name in honor of Alexander Graham Bell. Zero decibels (O dB) is defined as the threshold of human hearing. An increase of 10 dB is perceived as roughly twice as loud, and a level of 120 dB is at the threshol d of pain.
In terms of frequency, humans can hear sounds in a frequency range from about 20 Hz (a very low rumble) to 20,000 Hz (a high-pitched whine). Our best hearing is centered around the frequencies most common in human voices, near 1,000 Hz. Because sound is so complex and has so many features, it is difficult to quantify a complex, time-varying signal with a single number. How does a noise at 20,000 Hz compare to a noise at 1,000 Hz?
To reduce the complexity, single number metrics are used. These metrics work by applying weightings to sounds of different frequencies. These weighting factors allow us to combine the noise from all frequencies into a single number by including a penalty (or addition) to certain frequencies, better representing human perception. The two most widely used weighting factors are the A-weighting, designated by dBA, and the C-weighting, designated by dBC. If no weighting is used, the am plitude is designated simply by dB. Figure 69 is a graph showing both the A and C weighting factors used to compute dBA and dBC values.
 
Frequency (Hz) 100                    1000                10000 0.00
            -5.00 i-10.00 0
                      -    A-Weight ti ca            -    C-Weight
      ~ -15.00 C
      .c
_gp 3:  -20.00
          -25.00
          -30.00
          -35.00 Figure 69. A and C frequency weighting.
The A-weighted factors, shown in blue in Figure 69, represents how the average human perceives sounds at normal, speaking amplitudes. We have the best hearing in the range from about 1,000 Hz to 5,000 Hz, and we have poor hearing at the very high and very low frequencies. A-weighted sound levels are the most commonly used when describing sound. Typical SLM tools and phone apps will often provide the A-weighted levels.
The C-weighting, shown in red in Figure 69, represents how humans perceive high amplitude sound. If the noise we hear is loud, our ear responds differently than for quieter sounds. At higher amplitudes, people can hear frequencies between 100 Hz and 5,000 Hz at about the same amplitude. This means that our ear responds better when the sound is louder - proof that music does sound better if it is played loud. For siren analysis, FEMA recommends using the C-weighting scale for descriptions of siren sound levels.
 
Appendix B - Testing Procedures for Measuring the Acoustical Output of a System Siren Test Overview:
The purpose of this measurement protocol is to collect acoustical data using hand-held sound level meters to characterize the sound produced from a full-scale siren system test Test Schedule and Procedure:
Please plan on arriving at your location at least 45 minutes before the test to ensure that you have time to find the spot and park your car and set up the equipment. Each measurement location has been selected so that the sound level should not be excessive. No hearing protection will be needed. In addition, each tester will be required to completely fill in the lower half of their datasheets, starting with the drawings.
At your location, you should find a good level spot away from any major vertical surfaces such as walls, large boulders, or even cars. The requirement is to be at least 50 feet from any such objects, and farther is better. Once the exact location has been selected, set up the two tripods a few feet apart. Then carefully mount both the Sound Level Meter (SLM) and the weather station to the tripods. For the weather station, please follow the instructions attached for assembling and mounting the weather vane and weather station.
The microphone of the SLM should be 5 feet above the ground (mark the actual meter height on your datasheet). Use the tape measure to make sure that the height of the microphone is correct. The weather station should be mounted as high as the tripod will normally reach.
Make sure that the weather station is level by adjusting the tripod such that the spirit level is centered. Once the weather station is properly set up make sure to open the impeller cover so that the system can collect wind speed data. Finally, please snap at least three pictures showing the measurement set-up in relation to the things around it from different vantage points.
After the test equipment is set up, please take a few moments to draw the top-down plan view of your measurement location, including all buildings, vehicles, and walls within 300 feet. Make sure to note where the meter is in relation to these and all major roads. In addition, please provide a brief identifying description so that someone else could find this same spot again (assuming they were in the right general location). For example, '75 feet in front of 32 W.
Walnut St.'
The measurement should be started at least 10 minutes before all the sirens sound off. First, turn the weather station on and then turn on your SLM. After the meter has started up (which may take a few moments for some of the meters), start the meter recording data.
 
Before the siren sounding, please record on the datasheet what the main source of background noise is (such as traffic, a lawnmower or dogs barking), what the ambient noise level is, and the current wind speed, direction, and temperature.
During the test, all cell phones should be turned off, and please refrain from talking while the meter is recording data. During the measurement observe the SLM and keep a note of the highest noise level recorded during the test. If this was caused by something other than the sirens (a barking dog for instance) please note that on the datasheet.
After the siren sounding is complete check and record the ambient noise level again. Please wait for a full 10 minutes after the sirens finish siren sounding before stopping the meters and turning them off. Then please return the meter and weather station with the datasheet to Dr.
Ikelheimer.}}

Latest revision as of 15:48, 20 January 2022

Alert and Notification System Design Report
ML21127A166
Person / Time
Site: Arkansas Nuclear  Entergy icon.png
Issue date: 04/28/2021
From:
Entergy Operations, KLD Engineering, PC
To:
Office of Nuclear Material Safety and Safeguards, Office of Nuclear Reactor Regulation
References
0CAN042104 KLD TR-1208, Rev. 4
Download: ML21127A166 (217)


Text

Enclosure to 0CAN042104 Arkansas Nuclear One Alert and Notification System Design Report

ENGINEERING, P.C.

ARKANSAS NUCLEAR ONE Alert and Notification System (ANS) Design Report Lepftd

  • WPS2907 Q Zone Contour
  • 70dBC 0 60dBC I"':: lOMileRlng  ::i'::~~U..>Oll tl.Of,..-.,(-.,,.
=::c~=~"S:-~.~1'1~ ~~~

Population Density

  • >2,000Peopte/Sq. MI. :=::.:i=~.... -=M

~~~ J.S Work performed for Entergy, by:

KLD Engineering, P.C.

1601 Veterans Memorial Highway, Suite 340 Islandia, NY 11749 E-mail: kweinisch@kldcompanies.com September 25, 2020 Final Report, Rev. 4 KLD TR-1208

SIGNATURE LIST My agency has reviewed the enclosed Alert and Notification (ANS) Design Report In its entirety. We find the report to be accurate and complete, and to be in agreement with our agency's emergency plans. My signature below is my attestation to such.

OSCAR MARTINEZ JR Date: Digitally signed by OSCAR MARTINEZ JR 2020.12.14 08:26:07 -06'00' Date 01 'J.8 J.tJ/ti>

Date Date

REVISION HISTORY Date Revision# Notes 3/5/1984 0 FEMA approval of original ANS for the ANO EPZ.

5/2009 1 Design report was updated to account for.

  • One-for-one replacement of 34 electromechanical sirens with Whelen and ATI electronic sirens without modifying or changing the control system, antennas and radio systems.
  • Results of an acoustical test following installation of the new sirens to demonstrate that the updated siren system meets the design objectives.
  • The Fallure Mode and Effects Analysis {FMEA) of the completed siren system
  • Replacement of transmitters and radios for the tone alert system .

6/14/2011 2 Design report updated to correct siren GPS locations and siren coverage map 5/2016 3 Design report was revised and supplemented to reflect the following changes:

2/2017

  • One-for-one*replacement of the 28 ATI sirens with Whelen 2900-7 series sirens.
  • Installation of an additional Whelen 2900-7 siren .
  • Results of the near-field tests Indicate that the replacement of the 28 sirens provide a higher siren rated output.
  • Provide the Manufacturer's Technical Data, Operations and Troubleshooting Manual for the Whelen 2900-7 siren.
  • A replacement triJnsmltter and replacement radios for the NOAA Tone Alert System.

9/2020 4 Design report was requested to update to lnclui:le.

  • Update the siren coverage map using detailed Sound PLAN acoustical model and field testing of siren sound levels.
  • New guidance on report format and report content in FEMA Rad1ologlcal Emergency Planning Program Manual dated December 2019.

Table of Contents EXECUTIVE

SUMMARY

....................... :......................................................................................... ES-1 MAIN BODY 1 Licensing Obligations .........................................................................................................

................... 1 2 Requirements ........................................................................................................................

................ 2 2.1 System Coverage .........................................................................................................

.................. 2 2.1.1 Population ........................................................................................................................

..... 2 2.1.2 Geographic Area .........................................................................................................

.......... 4 2.1.3 Means........................................................................................................................

............ 5 2.1.4 Primary Methods .........................................................................................................

......... 6 2.15 Backup Methods .........................................................................................................

.......... 6 2.2 Population/Demographics ..........................................................................................

.................. 6 2.3 Interoper ability .........................................................................................................

.................... 7 2.4 Operations ................................................. ******************:********** .. ****** ..............................

................ 8 2.5 Managem ent/Administration ..........................................................................................

............. 8 2.6 Security and Privacy .........................................................................................................

............. 9 2.6.1 Physical Security .........................................................................................................

........... 9 2.6.2 Logical Security ......................................................................................................................

9 2.7 Maintenance/Repair .........................................................................................................

............ 9 2.7.1 Preventative Maintenance ..........................................................................................

.......... 9 2.7.2 Corrective Maintenance ........................................................................................................

9 2.8 Availability/Rellablllty .........................................................................................................

........ 10 2.9 Testing ........................................................................................................................

................. 10 2.10 Responsibility ..................................................;............................................................

............... 11 2.11 Training ........................................................................................................................

............... 11 2.12 Quality Assurance .........................................................................................................

.............. 11 3 Description/Performance ..........................................................................................

......................... 12 3.1 Physical requirements .........................................................................................................

........ 12 3.1.1 System Components .........................................................................................................

.. 12 3.1.2 User Interfaces ....................................................................................................................

12 3.1.3 Functional Block Diagrams ..........................................................................................

........ 12 3.2 Administrative Components ..........................................................................................

............. 13 3.2.1 Organizational Responsibilities ..........................................................................................

. 13 3.2.2 Management .......................................................................................................................

13 3.3 Operational Components .........................................................................................................

... 14 3.3.1 Activation ........................................................................................................................

.... 14 3.3.2 nming .................................................................................................., ..............................

. 14 3.3.3 Geo-Targeting .....................................................................................................................

14 4 Verification ........................................................................................................................

.................. 14 Arkansas Nuclear One ANS Design Report- Rev. 4

4.1 Coverage ..................................................................................................................................... 14 4.2 Population/Demographics .......................................................................................................... 1~

4.3 Metrics ........................................................................................................................................ 17 5 Availability/Reliability ......................................................................................................................... 17 6 Security and Privacy ............................................................................................................................ 17 7 Training and Public Outreach .............................................................................................................. 18 REFERENCES ....................................................................................................................................... R-1 LIST OF APPENDICES A. Compliance with Federal Regulations and Guidance ............... :....................................................... A-1 B. ANO EWS Activation Procedures .......................................................................................................B-1 C. ANO SWS Testing and Maintenance Procedures ............................. :................................................. C-1 D. WPS2800 and WPS2900 Series Operating and Troubleshooting Manuals ....................................... D-1 E. Siren Test Result Report ..................................................................................................................... E-1 LIST OF FIGURES Figure 1. Site Location ................................................................................................................................. 26 Figure 2. Permanent Resident Population by Sector for the ANO EPZ ....................................................... 27 Figure 3. Census Blocks with Population Density Exceeding 2,000 People per Square Mile ..................... 28 Figure 4. Census Blocks with Population Density Exceeding 2,000 People per Square Mile (Filter 1 Applied) ..............................................................................................................................'. ....... :................ 29 Figure 5. Applying Filter 2 to Eliminate Isolated Neighborhoods from High Population Density Consideration ..............................................................................................................................................30 Figure 6. Final Census Blocks with Population Density Exceeding 2,000 People per Square Mile after Applying Filters ..................................;.......................................................................................................... 31 Figure 7. Siren Coverage Map for the ANO EPZ .......................................................................................... 32 Figure 8. Siren System within the ANO EPZ ................................................................................................ 33 Figure 9. Control System Layout for the ANO ANS Siren System ............................................................... 34 Figure 10. Sound Transmission in Temperature Lapse Conditions ............................................................. 35 Figure 11. Sound Transmission in Temperature Inversion Conditions ....................................................... 35 Figure 12. Outdoor Sound Propagation near the Ground .......................................................................... 35 Figure 13. Upwind Sound P~opagation ....................................................................................................... 36 Figure 14. Downwind Sound Propagation with Terrain and Vegetation Effects ........................................ 36 Figure 15. Near-Field and Far-Field Test Locations ..................................................................................... 37 LIST OF TABLES Table 1. EPZ Population by Decennial Census ............................................................................................ 19 Table 2. Population Density Computed using Different Geographic Areas ................................................ 20 Table 3. Siren Details for the ANO EPZ ....................................................................................................... 21 Table 4. SWS Activation Points for ANO Site .............................................................................................. 25 Table 5. Siren System Reliability ................................................................................................................. 25 Table 6. Summary of Near-Field Acoustical Test Results ............................................................................ 25 Table A-1. Regulations Crosswalk ..... i ....................................................................................................... A-2 Arkansas Nuclear One II ANS Design Report - Rev. 4

EXECUTIVE

SUMMARY

The Arkansas Nuclear One (ANO) is located on a peninsula near the Town of Russellville in southwest ern Pope County, Arkansas. The Emergency Planning Zone ('EPZ) for ANO Includes parts of Johnson, Logan, Pope, and Yell Counties. The permanent resident population for the EPZ is 52,871 people as per the 2010 U.S. Census.

The Alert and Notification System (ANS) for the ANO relies on the Siren Warning System (SWS) and the National Oceanic and Atmospheric Administra tion (NOAA) Tone Alert System as the primary means of alerting the public. Route alerting is used as the bc1ckup means to alert the residents around the failed or inoperable siren(s). Public Informatio n materials are distributed to the EPZ populace to Inform people what to do if they hear sirens sounding or a loud tone from the activated NOAA Tone Alert Radios, and what radio stations to tune into for additional informatio n.

The SWS consists of SO omni-direc tional electronic sirens (21 Whelen WPS2807 sirens and 29 Whelen WPS2907 sirens). The location, model type and mounted height of each siren were input to Sound PLAN acoustic modeling software to estimate the audible level of the sirens throughou t the 10-mile EPZ surrounding ANO. The SWS provides 60dBC coverage to 92.6% of the p~pulation within the EPZ and 70dBC coverage to the areas with population density exceeding 2,000 people per square mile.

NOAA Tone Alert Radios are provided to residents of the 10-mlle EPZ who live outside the 60dBC coverage or who have special needs. The radios are also provided to facilities within the 10-mlle EPZ with significant population. The ANO tests the ANS routinely and has an extensive maintenance program in place to ensure continuous, reliable operation of the ANS. The ANS for ANO has had a reliability performan ce Indicator of 100% for 2019. The reliability of the ANS has not dropped below 99% during the la~t decade of operation. Operators of the ANS are offered training as needed to ensure continued reliable operation of the system.

All siren batteries and control boxes are locked and mounted on the siren pole to prevent tampering The siren activation equipmen t is installed at secure locations (the Arkansas Departme nt of Health offices). The ANS system includes a DTMF encoder that requires key-lock a~ivation to make It resistant to cyber-attack.

This ANS design report is an update to the last ANS report (Rev. 3 dated 2/2017) to update the siren coverage map using outputs from the detailed SoundPLAN acoustic model and field testing of siren sound levels, and to address the new guidance on ANS design report formatting and content documented in the December 2019 FEMA REP Program Manual.

Arkansas Nuclear One ES-1 ANS DeslgT\ Report - Rev. 4

1 Licensing Obligations Title 10 of the Code of Federal Regulations {CFR) §S0.47{b), item (5) and Trtle 44 of the CFR §350.S(a),

item (5) state:

uProcedures have been estabflshed for notification, by the licensee, of State and local response organizations and for notification of emergency personnel by all organizations; the content of initial and follow-up messages to response organizations and the public has been established; and means to provide early notification and clear instruction to the populace within the plume exposure pathway Emergency Planning Zone [EPZ] have been established."

The December 2019 FEMA Radiological Emergency Preparedness {REP) Program Manual states, "the alerting and notification of the public Is a function of the state, local, tribal and territorial governments' emergency plans. An NPP [Nuclear Power Plant] applicant/licensee is required to demonstrate that the administratl\/e and physical means are established for alerting the public and providing Instructions, regardless of who implements the ANS [Alert and Notification System] capability. An applicant/licensee may install and maintain the ANS but the responsibility for the alerting and notifying the public, as well as the activation of the ANS, remains with the state, local, tribal and territorial governments."

This ANS design report describes the physical and administrative means established by Entergy to assist the states and counties in alerting and notifying the public in an emergency. Detail of the state and county actions can be found in the state and county radiological emergency plans.

As discussed rn the December 2019 version of the FEMA REP Program Manual, the initial federal guidance on ANS provided in NUREG-0654/FEMA-REP-l, Rev. 11, Appendix 3 {1980) and FEMA-REP-10 ("Guidance for the Evaluation of Alert and Notification Systems for Nuclear Power Plants") (1985) "predated technology many citizens now take for granted (e.g., smartphones, social media, etc.)." As such, the FEMA REP Program Manual is now the recognized federal ANS guidance document as it uallows evaluators to account for new technologies, consider updated NRC/FEMA guidance, and incorporate REP l~ssons learned." This ANS design report adheres to the guidance of th~ latest FEMA REP Program Manual (December 2019), but does rely on data and Information from the following additional guidance documents:

  • NUREG-0654/FEMA-REP-l, Rev. 11 (1980) including Supplement 4 (2011)
  • FEMA CPG 1-17, HOutdoor Warning Systems Guide" (1980)
  • FEMA-REP-10 (1985)
  • FEMA Technical Bulletin (Version 2.0) uautdoor Warning Systems" (2006)
  • NEI 13-01, Revision 0, "Reportable Action Levels for Loss of Emergency Preparedness Capabilities" Part V, Section B of the 2019 FEMA REP Program Manual discuss ANS design objectives. The minimum acceptable design objectives for coverage by an ANS - what the system must be able to do when speed is critical - Include:

1 This document IS outdated, being replaced with Rev 2 rn December 2019. One of the goals of Rev. 2 of this document and of the December 2019 revision of the FEMA REP Program Manual was to not rnen!Jon spectfic technologies (1 e, Sirens) m reference to ANS Nonethel-, Rev 1 of 1h18 document does indude valuable guidance on outdoor warning sirens Arkansas Nuclear One 1 ANS Design Report - Rev. 4

  • The capability to provide both an alert signal and an informati onal or instructional message to the population In the EPZ within 15 minutes.
  • The initial notificati on system will ensure direct coverage of essentially lQO percent of the population within 5 miles of the NPP site.
  • Notification methods will be established to ensure coverage within 45 minutes of essentially 100 percent of the population in the EPZ who may not have received the initial notificatio n including any special requirem ent exceptions (e.g., large water areas with transient boats or remote hiking trails).
  • The capability of the ANS to cover essentially 100 percent of the population within the EPZ, regardless of failures. The corrective means/measures will be conducted within a reasonable time, with a recommended goal of 45 minutes. The use of a sequential failure model or "primary and backup" ANS model Is acceptable. Other models, such as simultaneous or concurre nt activation models, could be !,JSed.

All of these criteria are met by the ANS system in the Arkansas Nuclear One (ANO)

EPZ, as discussed in the sections below.

2 Requirements 2.1 System Coverage 2 1.1 Population The ANO site is located near the Town of Russellville in southwes tern Pope County, Arkansas. The EPZ is located entirely within the State of Arkansas and consists of portions of four counties

-Johnson , Logan, Pope, and Yell Counties. Figure 1 shows the location of ANO as well as the approxim ate 10-mile EPZ.

The permanent resident populatio n In the EPZ Is 52,871 people according to the 2010 Census. Table 1 summarizes the permane nt resident population and population density In the EPZ, by Zone, for the last two decennial censuses conducted by the U.S. Census Bureau. As the data indicate, population in the EPZ has increased since 2000, with an increase of +3.8% for the 2-mlle radius of the plant, +12.8% for those Zones within the 5-mile radius, and +13.6% for the EPZ as a whole.

A common method for displaying population around a nuclear power plant is by sector.

The EPZ Is divided up into one-mile increments and the sixteen cardinal and Inter-cardinal wind directions

, for a total of 160 sectors. The 2010 EPZ permane nt resident population, by sector, Is shown In Figure 2.

The federal guidance; FEMA-REP-10, "Guide for the Evaluation of Alert and Notificati on Systems for Nuclear Power Plants/ indicates that sirens are in compliance with federal guidance if they meet either of the following conditions:

  • "The expected siren sound pressure level generally exceeds 70dBC where the populatio n exceeds 2,000 persons per square mile and 60dBC in other inhabited areas; or
  • The expected siren sound pressure level generally exceeds the average measured summer daytime ambient sound pressure levels by lOdB (geographical areas with less than 2,000 persons per square mile).H FEMA CPG 1-17, "Outdoo r Warning Systems Gulde" indicates that people typically mentally block out sounds that are not pertinent to what they are doing. In order to break the mental block, a warning sound Arkansas Nuclear One 2 ANS Design Report - Rev. 4

must be about 9dBC greater than ambient noise to capture the attention of the listener. This is.the basis of the conseivative l0dBC above ambient noise guidance. Ambient noise levels were not measured in the ANO ,EPZ; thus, 60dBC and 70dBC will be used as the criteria for siren sound levels in this report, depending on the population density In a given area In order to determine whether 60dBC or 70dBC coverage is needed, population density was computed.

There are many different methods for computing population density:

  • Population density by radial distance mile radius, 5-mile radius, or the full approximate 10-mile EPZ
  • Population density by county
  • Population density by municipality As shown in Table 2, these population densities differ significantly, underscoring the uneven distribution of population in the EPZ. Higher sound pressure levels are required in densely populated areas to overcome the' higher ambient noise levels associated with a larger number of people and increased activity. Computing the population density by a large radial distance, or by county can distort population density by incorporating large land areas that are unpopulated or sp~rsely pop'ulated. This could result In the failure to adequately identify areas that need 70dBC coverage. For example, Table 2 indicates that ~he municipalities in the EPZ have population densities ranging from 211 to 1,303 people per square mile.

However, when considering the population density for each county as a whole, it is considerably lower (ranging from 24 to 76 people per square mile).

The most refined method for computing population density is by census block. The U.S. Census Bureau divides the U.S. into census tracts. These census tracts ara in turn divided into block groups, and block groups are comprised of multiple blocks. The census block is the finest level at which the U.S. Census Bureau aggregates detailed population data.

Census blocks vary in size from as small as a single city block to as large as an entire county. Given the variance in block size, there is the potential to have abno.rmaliy high population density for a block with a very small area. Similarly, a* small neighborhood can have a population density exceeding 2,000 people per square mile but it may be the only community for miles. Assuming this neighborhood has 100 people living in an area of about 0.04 square miles (approximately 26 acres - 50 homes on 1/2-acre plots), the population density would exceed 2,000 people per square mile. However, if there are no surrounding neighborhoods, 100 people are not likely to generate enough background noise to warrant 70dBC coverage.

The last physical census'in the United States was conducted in 2010 (the 2020 Census is ongoing, but data will not be released until March 31, 2021). Thus, the 2010 Census serves as the basis for all population estimates m this document. Each year in May, the U.S. Census Bureau releases projected populations for each state, county and municipality in the U.S. The latest available census population estimates, as of July 1, 2019, which were released in May 2020 (when this analysis documented in this report was started),

from the U.S. Census Bureau were used to compute annual growth rates by county and municipality.

These growth rates were then used to extrapolate the 2010 census population In the EPZ to 2020 at the Arkansas Nuclear One 3 ANS Design Report- Rev. 4

block level. For more informati on, please refer to the 2020 Evacuation Time Estimate (ETE) update 2 for ANO.

The following methodology was used to compute populatio n density within the EPZ, by census block.

Population block data was overlaid on the EPZ boundary using Geographic Informati on Systems (GIS) mapping software. The population density was computed by dividing the 2020 extrapola ted population by the area of the bloc~ In square miles. Any block with a density exceeding 2,000 people per square mile was flagged (block color coded red) as high density as shown In Figure 3.

As discussed above, there Is a possibility of isolated neighborhoods or extremely small census blocks being flagged with abnormally high populatio n densities. While mathematically the populatio n densities are correct, these anomalous census blocks do not represent densely populated areas, that would have significant background noise warrantin g 70dB siren sound levels. Two steps were taken to remove these anomalous census blocks from the actual high population density areas:

1. A filter was applied which eliminate s all flagged blocks that have a population less than 100 people or an area less than 0.02 square miles. This filter eliminates sparsely populated census blocks which are abnormally small and result In unrealistically high populatio n densities. Figure 4 displays those blocks which are still flagged after applying this filter.
2. Each flagged census block with a populatio n density exceeding 2,000 people per square mile was converted into a circle with an area of 1 square mile, centered at the center ofthe block. These 1 square mile circles were then overlaid with the census block data once again and the population density of the 1 square mile circle was recalculated. If the density exceeded 2,000 people per square mile, the block which the circle was centered at remained flagged as having a high population density. If the density of the circle fell below the threshold, the block the circle was centered at was removed from consideration. This filter eliminates isolated high population density neighborhoods that are surrounded by areas of low populatlo n density.

Figure 5 shows an example of this filter applied to three census blocks In the EPZ. Both blocks shown in Step 1 are flagged as high population density blocks after applying Filter 1. However, when drawing the 1 square mile circles (Step 2.1) centered at the blocks, the populatio n density (Step 2.2) is well below the 2,000 people per square mile threshold. As a result, both blocks are eliminate d as high population density blocks (Step 2.3). Figure 6 shows the final blocks flagged as having population density exceeding 2,000 people per square mile in the EP~ after the two filters were applied.

2.1.2 Geographic Area The ANO site Is situated on a peninsula formed by Lake Dardanelle, which Includes the Arkansas River and the former Illinois Bayou. The land within 5 miles of the plant is gently rolling and contains a number of ridge-valley configurations. The Arkansas River and Lake Dardanelle roughly bisect the ANO EPZ.

The meteorological Information for each of the EPZ counties is described below.

Johnson County3 is characterized by hot summers and cold winters, with an average high temperature of 90 degrees Fahrenheit ("F) in July and an average low temperat ure of 27°F in January.

The average rainfall 2

"Arkanaas Nuclear One 2020 Population Update Analysis", KLD TR - 1167, dated September 19, 2020

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and snowfall in the county is 50 inches and 4 inches, respectively. The number of days with any measurable precipitation is 96. Johnson County is at an averag': elevation of 1,017 feet.

Logan County" Is also characterized by hot summers and cold winters, with an average high temperature of 92°F in July and an average low temperature of 28°F in January. The average rainfall and snowfall in the county is 49 inches and 2 inches, respectively. The number of days with any me_asurable precipitation Is

95. Logan County is at an average elevation of 678 feet.

Pope County5 is also characterized by hot summers and cqld winters, with an average high temperature of 91 °F In July and an average low temperature of 28°F in January. The average rainfall and snowfall in the county is 50 Inches and 4 inches, respectively. The number of days with any. measurable precipitation is 101. Pope County is at an average elevation of 835 feet.

Yell County6 is also characterized by hot summers and cold winters, with an average high temperature of 93°F In July and an average low temperature of 29"F in January. The average rainfall and snowfall in the county Is 5.1- inches and 3 inches, respectively. The number of days with any measurable precipitation is

95. Yell County is at an average elevation of 626 feet.

j;igure 1 identifies the municipal areas and major roads in the area, as well as the 15 Zones that comprise the approximate 10-mile EPZ. The Zones are color-coded based on the county they are In.

The National Oceanic an_d Atmospheric Administration {NOAA) commissioned a study 7 to summarize historical wind data from 1930 to 1996 in the United States. Wind data was aggregated for Fort Smith Regional Airport, which is the closest airport to ANO. The average wind speed at Fort Smith Regional Airport, based on the data gathered, ranges from a low of 6 miles per hour (mph) in July to a high of 8mph in January.

As shown In "Figure 1 and listed in Table 2, there are 6 municipalities within the EPZ. Most of the municlpallties are located adjacent to the Arkansas River and Lake Dardanelle. Beyond the population centers is sparsely populated rural farmland or undeveloped land.

The population centers in the ANO EPZ are connected by_an extensive highway network. Interstate 40 and US Route 64 travel northwest-southeast through the EPZ. The major state highways servicing the EPZ include Arkansas State Routes -7, 22, 27, 28, 124, 164, 247, 315, 326, 331, 333 and 359. The primary railroads within the EPZ include Dardanelle and Russellville Railroad and Missouri Pacific Railroad .

2.1.3 Means The physical means of alerting and notifying the public within the ANO 10-mile EPZ is the Emergency Warriing System (EWS} that consists of a mixture of the Siren Warning System {SWS) and the NOAA Tone Alert Sy51:em. The ANS is essentially designed to notify the Individuals In the 10-mile EPZ within 15 minutes of the issuance of recommendations by the State of Arkansas for radiological emergencies at ANO. Local fire departments in the EPZ and route alerting are used as the backup method to alert the public to receive instructions, information, and necessary actions to be taken.

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2.1.4 Primary Methods The primary ANS for ANO is the EWS as discussed above. The SWS is used to alert the more densely populated areas shown in Figure 7. Based on the population estimates discussed in Section 2.1.1, the SWS covers 92.6% of the population within the EPZ at 60dBC or higher. Those residents of the 10-mile EPZ who live outside the siren coverage area or who have special needs are alerted by NOAA Tone Alert Radios (TAR). NOAA TARs are also provfded to the facilities within the 10-mile EPZ with significant population.

These Individuals and facilities are further discussed In Section 2.2.

The SWS relies on SO Whelen omni-directio nal electronic sirens (21 WPS2807 sirens and 29 WPS2907 sirens). Of the 50 sirens, there are 2 sirens in Johnson County, 3 sirens in Logan County, 33 sirens In Pope County and 12 sirens in Yell County. All sirens are mounted at pole top, approximate ly SO feet above the ground. The location, height and ID for each siren are presented in Table 3.

All of the sirens are radio-contro lled and a DTMF (Dual Tone Multiple Frequency) encoder is required for activation. Sirens include a National Nuclear Attack signal that insists of an up-and-down scale tone. This three-minute continuous tone signal will be used to alert the populace to tune into NOAA TARs and local radio stations for emergency information (primary notification). Sirens also include a warning signal. This signal is used to alert ,the populace of not only a radiological incident, but also of natural disasters, especially tornado warnings.

The Arkar:isas Department of Health (ADH) maintains a database of addresses that are outside of the 60dBC siren coverage area. Each year a letter Is sent to those addresses to verify if they have a NOAA TAR and If It is functioning. If they do not have a TAR or if the TAR is not functioning, they can request that ADH provide a TAR. The ADH also mails batteries to the TAR holders annually.

The NOAA Tone Alert System is operated in cooperation with the National Weather Service (NWS). When activated, a loud tone is emitted from the radio to alert the user. Following activation of the receivers, live or pre-recorded emergency messages are broadcast to instruct/noti fy the public. Section 3.1 below provides additional details of the EWS.

2.1.5 Backup Methods Supplem_ental notification to the EPZ population is provided by local fire departments In the EPZ. In the event of siren or NOAA Tone Alert System failures, route alerting is implemented in the affected fire distrlct(s) using truck sirens and Public Address (PA) systems for notification of residents around the failed or inoperable siren(s). The truck sirens serve as the backup alert method, while the announceme nts being made over the PA system serve as the backup notification method.

2.2 Population/Demographics In addition to the permanent resident population detailed in Section 2.1.1, there are transients who may be visiting the EPZ for recreational purposes. Those people who live and recreate In the EPZ have already been considered as permanent residents to avoid double counting population.

According to the latest ETE study done for ANO (KLD TR-S17, "Arkansas Nuclear One - Developmen t of Evacuation nme Estimatest Rev. 1, dated December 2012), there could be as many as 11,74S transients in the EPZ at peak times. Th'e transient estimate is based on data provided by county emergency management agencies.

Arkansas Nuclear One 6 ANS Design Report - Rev. 4

There are 69 special facilities identified in the EPZ. These facilities lndude schools, universities, parks, campgrounds, golf courses, marinas, recreational areas, lodging facilities, major employers, medical facilities, and correctional facilities. The EWS is capable of alerting and notifying each of these special facilities. Nonetheless, the State has plans in i;:ilace to notify each of these facilities individually.as discussed below.

As per the Arkansas Comprehensive Emergency Management Plan (ARCEMP), Rev. 39, dated September 30, 2019, the State Department of Parks and Tourism will provide notification of the public within the park system; the State Game and Fish Commission and State Forestry Division will provide backup communications and personnel for notification purposes in remote forest areas, and on rivers and lakes; the ADH repeater system will alert the emergency response agencies and schools within the 10-mile EPZ through the Early Notification System (ENS) component of the EWS; and infonnation contained in the Emergency Instruction Booklet8 (EIB) is posted and/or placed in public locations within the 10-mile EPZ such as public buildings, state and national parks, recrea_tional areas, tourist infonnation centers and rest areas located on major highways, _which are routinely visited by transient populations. Postings will be checked periodically and updated as needed. In addition, letters of agreement formalizing the emergency notification interfaces between Entergy and Arkansas tech University in Russellville are kept on file in Entergy's offices.

None of the areas discussed above are considered exception areas. They can all be alerted and notified in a timely fashion. - -

Special provisions have been developed by ADH Nuclear Planning & Response Pr(?gram (NP&RP) and Entergy for the alerting of identified handicapped individuals. A p~stage-prepaid, detachable postcard is provided in the' annual mailing of the EIB for use by persons who may have special needs. This form is to be completed and then mailed to the ADH NP&RP office, and the infonnation Is subsequently provided to the appropriate local government. The individuals wlth special needs, depending upon their handicap, are notified appropriately. The notification may includ~ door-to-door notification by law enforcement officers, neighbors, telephones, or tone activated NOAA TARs. Persons who are hearing impaired, or who require special notification are provided NOAA TARs free of charge. These receivers ~re also made available to the large businesses, hospitals, nursing homes, schools, day reception centers, and other applicable groups within the 10-mile EPZ.

According to American Community Survey 2014 - 2018 data9, the percent of non-English speakers within the EPZ is approximately 0.56%. Given the small size of non-English speaking population, English is the only language used for notification.

2.3 Interoperability The SWS is divided into 5 siren activation zones of relatively higher population density covering parts-of the 10-mile EPZ, specifically: Yell County (lZ as Zone 1), the Russellville/Dover area and the Village of London in Pqpe County (2Z and 3Z), Johnson County (4Z), and Logan County (SZ). Each of these zones can be activated independently or in conjunction with other zones. All zones would be activated in the event of emergency at the ANO site.

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The ADH has the sole ability to activate the SWS. There are three activation points - one primary and two backup points, as discussed in Section 3.1.3 and Section 3.3.1. The locations of the activation points are outlined in Table 4. All the activation points have backup power and two independe nt paths for activation slgnals to reach the sites. The SWS is activated by radio signal in the UHF (Ultra High Frequency

) band which Is ~ransmitted by the primary/ba ckup siren radio transmitte r. The architectur e of the SWS activation is discussed in detail In Section 3.1.3. The SWS activation Is also made available to local governme nts for use in severe weather and other emergencies. Authorized officials may request siren activation for various zones in their jurisdiction s.

The sirens are battery operated and are powered by four high capacity batteries. Battery charge is maintained by AC power through "smart" chargers to avoid overchargi ng. Sirens, depending on use, can keep operating up to 10 days without AC power. The ADH has mobile generator units that can be used in the event an AC power outage exceeds that length of time.

The NOAA TARs are activated by the NWS through a 300-watt transmitte r with a 300-watt backup transmitte r. The NWS is contacted by the ADH staff and infomied of the intent to activate the EWS. The NWS is notified in advance of the sirens being activated such that, In conjunctio n with the siren activation, the NWS activates the NOAA tone which automatica lly turns the receivers on.

2.4 Operations ANO maintains the capabilities to assess, classify, and declare an emergency condition within 15 minutes of the availability of Indications to plant operators that an emergency action level has been exceeded.

Emergency personnel are trained to promptly declare the emergency condition as soon as possible following identificati on of the appropriat e emergency classificati on level. There are four emergency classification levels - Notificatio n of Unusual Event, Alert, Site Area Emergency and General Emergency .

The EWS within the 10-mile EPZ might be activated by ADH for a Site Area Emergency and will be activated for a General Emergency.

The final decisions to alert and notify the public by the EWS are the decisions of governmen tal officials.

Initial notification is made to the state and local authorities within 15 minutes after declaring an emerge'ncy. An Emergency Action Authentica tor is used to verify messagl:!s that are received over a non-secure system, such as commercia l telephone system. The NRC is notified Immediate ly following notification of state and local authorities and within 1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br /> of the de~ared emergency.

'The EWS cari be fully activated from the ADH Emergency Communic ation Center (ECC), the alternate State Emergency Operations Facility (SEOF) or the ADH NP&RP office. Anytime the SWS is to be activated to notify the public, ADH NP&RP will take over operation of radio station KXRJ, 91.9 FM at Arkansas Tech University. ADH NP&RP has the capability to remotely take over broadcast of this station and provide the public with any emergency communic ations or protective actions that might become necessary.

The detailed activation process Is included In Appendix B.

2.5 Management/Administration It is the responsibi lity of ADH to manage and oversee the EWS network. The NOAA radio pr~ram Is administra ted by ADH NP&RP and operated by NWS. The NWS is responsible for managing the weather radio transmitte rs nationwide .

Arkansas Nuclear One 8 ANS Design Report - Rev. 4

2.6 Security and Privacy 2.6.1 Physical Security All siren batteries and control boxes are pad locked and mounted on the siren pole to prevent tampering, and both AC and battery voltage can be monitored remotely. The siren activation equipment is installed at se_cure locations that are manned 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> per day. Entry into all activation points is limited to authorized personnel only. Additionally, all activation consoles are equ'ipped with a physical keyed lock to prevent access to the activation keys.

2.6.2 Logical Security To prevent cyber-attack, the actual activation of the EWS is accomplished by use of a DTMF encoder requiring key-lock activation. Details of either activation procedure are limited to a "Need-to-Know" basis for security reasons.

2.7 Maintenance/Repair 2.7 1 Preventative Maintenance It is the responsibility of ADH NP&RP to perform the Preventive Maintenance (PM) on the SWS. On a quarterly basis, the PM is performed following the instructions listed in the ANO SWS Maintenance Plan (see Appendix C). During the scheduled PM, each siren may experience brief periods when it is not able to sound, but it Is not taken out of service for more than a few minutes and could be returned to service immediately, if needed. As noted in the maintenance plan, a wide variety of inspections are performed at each siren site including verification that there is no vegetation growth that can obstruct sound propagation near the siren head; visual inspection of the pole, the antenna, the siren head, the cabinet and associated connections; verifying acceptable condition of the batteries and chargers; and running a silent test. In addition, the ADH performs the maintenance with contractor assisted items, such as crane rental for upper driver maintenance.

The ADH NP&RP also checks the operation of the control points and transceivers associated with the activation system on a routine basis. The operability of key components, for Instance, is verified every weekday. Additionally, a contractor Is used to measu~ the transceiver perimeters.

The ADH NP&RP mails Information annually to every address within the 10-mile EPZ to provide the contact in'formatiO!J for the request of the NOAA TARs. On a monthly basis, the ADH mails letters to t~e new residents within the 10-mile EPZ to notify them of the same information. Recipients of the NOAA TARs are tracked in a master database by the NP&RP staff as discussed in Section 2.1.4. Needed repair and/or replacement of the receivers identified as defective is also carried out by the NP&RP staff. All the holders of the NOAA TARs receive new batteries and instructions from the ADH annually.

2.7.2 Corrective Maintenance Upon notification of a siren malfunction, the ADH determines if the failure(s) is reportable in accordance with 10CFR 50.72, and the noted siren malfunction is immediately serviced by an ADH NP&RP Electronics Technician and every attempt is made to return the unit to operation. If the siren is unavailable, the appropriate county is notified that the backup alert method - route alerting - will be required in the affected area until the unit is returned to service.

I A siren that did not fully respond to the activation command signal during a valid test is considered as an activation failure and would not have provided adequate public alert. It would be reported as a siren Arkansas Nuclear One 9 ANS Design Report - Rev 4

failure to FEMA and to ANO Emergency Planning (EP) personnel. A siren is considere d out of service when it cannot receive, process, or sound the appropria te audible warning tone through the driver section.

When determin ation has been made that a SWS compone nt is not responding appropria tely to polling, such as low battery, AC voltage or related issues; or reports or concerns from the public indicating siren abnormal behavior, an on-site Inspection and repair will be performe d by an ADH NP&RP Electronics Technician. The Electronics Technician will follow the guidelines recommended in the manufact urer's operating and troublesh ooting manuals (see Appendix D) to restore compone nt functiona lity. The Electronics Technicians also meet routinely with the ADH Section Chief to Identify any maintenance and/or performance trends. Trends are noted and corrective actions are impleme nted, if needed.

In addition, the ADH tests the siren control transmitt ers and consoles every weekday morning, when the state offices are open. If a problem is identrfied , the corresponding corrective action Is immediat ely undertaken. The use of redundan t transmitt ers and activation points minimizes the risk of a failure of the activation system.

2.8 Availability/Reliability Appendix 4 of FEMA REP-10 specifies that the operabili ty of a siren system is considere d acceptable "when an average of 90% of the sirens (as determin ed by a simple average of all regularly conducted tests) can be demonstrated functiona l over the 12-month period immediat ely preceding the submittal of the design report.N The Nuclear Energy Institute (NEI) Regulatory Assessment Performance Indicator Guideline, NEI 99-02 Revision 7, specifies a minimum performance indicator threshold of 94% for ANS Reliability during the previous four quarters for plants operating in the normal regulator y response band.

The ANO SWS reliability data is reported to FEMA for review on a quarterly basis.

According to the ADH, the ANO siren system has been operational since 1981 A review was complete d over the past 10 years and it was determin ed that the successful siren performa nce has not dropped below 99% during that time. Table 5 shows the results of siren tests at ANO for the last 4 quarters.

As shown, the siren performance in each quarter of 2019 was 100%.

2.9 Testing The EWS is tested by ADH and NWS periodically to ensure Its readiness. The testing includes functiona lity of sirens and of NOAA TARs.

The entire SWS is sounded weekly to reinforce public awareness of the system. This is not a silent or growl test, but either a 15-second or 1-mmute audible test each Wednesday at 12:00 pm. Testing will not be performed if severe weather is present in the area or the state offices are closed. Under a verbal agreement with FEMA, the 1-minute audible test is performe d on the 4 th Wednesd ay of the month. The operation of each siren Is verified once per month and the results are reported to FEMA. Due to the fact that the weekly audible test far exceeds the annual federal operabili ty requirem ent, other types of audible tests are not conducted at the ANO.

In addition to the weekly audible test, sirens are polled for health maintenance at least once per month.

The health of siren batteries is assessed by the ADH NP&RP Electronics Technicia n on a quarterly basis (see Section 2.7.1). Batteries are replaced at a frequency that exceeds the battery manufact urer's recommendations. The siren activation equipme nt is tested frequentl y (see Section 2.7 2). Special Arkansas Nuclear One 10 ANS Design Report - Rev. 4

observations may be conducted in the event of severe weather or high winds which might result In physical damage, such as identifying loose feed lines or pole damage. If any issues are identified during these observations, repairs will be undertaken using the ANO SWS Maintenance Plan in Appendix C.

The NOAA TAR activation is tested by the NWS and monitored by ADH NP&RP. The testing Is performed each Wednesday between 11:00 am and 12:00 pm. If inclement weather persists, the testing will be performed the next clear day.

The current testing conducted by ADH exceeds the annual maintenance recommended by the NRC. This includes actions specifically designed for the ANO EWS. The testing records are kept in the ADH NP&RP office.

2.10 Responsibility It is the responsibility of ADH NP&RP to perform or supervise maintenance on the entire EWS network (except for the NOAA radio system and local broadcast stations and radios) and to ensure that it Is functioning properly. In general, the electronic component control and radio parts are maintained and rep_aired by ADH. The items requiring the use of a crane or other specialized equipment are maintained and repaired by contractors. The NOAA radio system is tested by the NWS and monitored by ADH NP&RP and by ANO EP personnel (see Section 2.9 and Section 4.3). A local contractor is responsible for maintenance and repair of the NOAA weather radio transmitters.

2.11 Training It is the responsibilities of ADH NP&RP to identify organizations with a need for training and provide training and refresher training on a continuing basis. Refresher training shall be made available to emergency personnel at least annually. At a minimum, these emergency workers will have attended the FEMA REP Planning course. The training required for emergency personnel is discussed in Section 7.

2.12 Quality Assurance The ADH maintains several procedures pertaining to the ANS, including procedures on activation, testing, maintenance, repair and reportability. These procedures are included in Appendices Band C. The records regarding the SWS testing and maintenance are maintained by ADH and routinely reviewed by ANO.

Copies of the quarterly reports detailing siren system perfonnance are also provided to ANO. Additionally, the ANO is provided the results of activation verification on a monthly basis.

In addition to these procedures above, the EWS 1s tested on a weekly basis as discussed In Section 2.9.

Hence, the essential elements of the SWS activation are "practiced" weekly. These extensive exercises help to reduce errors during the operation.

The NOAA weather radio test data is not reported as the weekly test 1s not guaranteed due to the weather conditions The records of the NOAA radio system performance are not maintained as it is outside ADH's area of responsibility. However, the ADH notifies the NWS of service interruptions monitored (see Section 4.3) and provides assistance in resolving problems. As noted In Section 2.10, a local contractor is responsible for the maintenance and repair of the NOAA weather radio transmitters.

Arkansas Nuclear One 11 ANS Design Report - Rev. 4

3 Description/Performance 3.1 Physical requirem ents 3.1.1 System Components As discussed In Section 2.1.4, the siren system is comprised of SO omni-directional electronic sirens.

Figure 8 maps the sirens in the EPZ. The sirens are labeled with their Identification number and are symbolized by siren model type. Table 3 lists each of the SO sirens In the ANO EPZ. The table includes the siren Identification number, the latitude and longitude of the siren, the siren model, the mounted height of the siren and location description.

WPS2807 and WPS2907 sirens can produce approxima tely llS.ldBC and llS.SdBC, respective ly, at 100 feet along their centerline with operating frequencies between 500 and 630 Hz, based on the results of the near-field tests discussed In Section 4.1.

A WPS2807 or WPS2907 siren consists of a power supply (batteries), a control board, seven 400-watt audio drivers, seven audio amplifiers, and a radio transceiver for reception of control signals.

The batteries, control board, amplifiers and transceiver are located in a sealed and locked enclosure.

The siren drivers are pole mounted at approximately 50 feet above the ground. All sirens have multiple ground points and surge protection, including antenna feed lines.

Over the past 30 years, the ADH has Issued numerous NOAA TARs of various models and manufactu rers.

Nevertheless, all the radio receivers must respond to the 1050 Hz alert tone and feature an audible warning. The ADH also provides models with a visual signal to alert deaf or hearing-impaired individuals The NOAA TAR have a battery backup feature which allows the user to install batteries, such that the radio will work during a power outage. New batteries are Issued annually to each of the NOAA TAR holders as discussed in Section 2.1.4 and Section 2.7.1.

3.1.2 User Interfaces The WPS2800 and WPS2900 series sirens can be remotely activated by using an encoder and siren radio transmitte r. The logical connection between the siren control components is further discussed In Section 3.1.3. The NOAA TARs are activated by a primary 300-watt transmitter. A secondary 300-watt backup transmitte r would be used following a failure of the primary transmitter. Both primary and secondary backup transmitte r sites are located on Mount Nebo, which is approximately 6 miles SSW of the ANO site.

Entergy has provided backup generator capability for the transmitte r site. Hot standby switching for auto-start of the backup transmitte r and a backup generator with auto-start capability is also available and tested frequently.

3.1.3 Functional Block Diagrams Figure 9 shows the logical connection of the components of the siren control system. As shown in the diagram, there are three different locations that can communicate with the primary and backup siren radio transmitters which in tum communicate with the siren sites via a utility microwave link or a leased line which Is a circuit rented from a public carrier -AT&T in this case. The ADH Mobile Command Post can communicate with the primary and backup radio transmitte rs via radio line. The primary/ba ckup siren radio transmitters activate sirens by UHF-FM radio signal. Section 2.3 further discusses the physical connections of the system and the interopera bility.

Arkansas Nuclear One 12 ANS Design Report- Rev. 4

3.2 Administrative Components 3.2.1 Organizational Responsibilities The ADH ECC is the official 24-hours-per-day point of contact between the State and ANO for the Initial notification of a radiological incident. In the event of an emergency, the operator of ANO Is responsible for notifying the ADH ECC, Arkansas Department of Emergency Management (ADEM), and the warning points In Conway, Johnson, Logan, Pope and Yell Counties. The final decisions to alert and notify the public by the EWS are the decisions of governmental officials.

The responsibilities of ADH NP&RP include off-site emergency planning and response to emergencies involving ANO; the development and update of emergency response plans; the maintenance and operation of the EWS and the communication system used to notify state agencies and local governments of emergencies; the maintenance of equipment and supplies necessary to support emergency operations for state and local agencies; the development and training of emergency personnel who would respond to an emergency; and the distribution of emergency instructions to the public.

The primary means of notification and communication between ANO and the state and local governments will be via the ANO Dedicated Emergency Facsimile/Voice System (DEF/VS). In the event that the ANO DEF/VS is not operating properly, the operator of ANO will notify the ADH ECC directly by commercial telefax or by commercial telephone; and ADH, In turn, will notify the county warning points and ADEM using various means, such as the DEF/VS, ENS radio, ADEM radio, and/or commercial telephone. If both communication procedures outlined above fail, the operator of ANO will use commercial telephone to notify the ADEM which will, in turn, notify the ADH ECC. The ~ommunications link between the state and federal emergency response organizations is via the commercial telephone system, with the National Warning System (NAWAS) serving as the backup system.

3.2.2 Management As noted in Section 2.6, the activation consoles are key locked and kept at secure locations to prevent the inadvertent systemwide activation, and the siren control system is configured In such a way that a systemwide inadvertent activation is very unlikely to occur. There are limited failure paths which will result in an inadvertent activation, such as included high voltage that shorts a control cable. In the event of an inadvertent siren activation, the ADH sends the notification to area broadcast stations and to appropriate 911 Centers to assure the public there is no emergency involving ANO. In an emergency Involving ANO, this responsibility falls on which of the State's centers have "Command and Contror'. For other situations, it depends on the time of day. After hours notification falls to the ADH ECC if the radiological emergency response team is not activated.

If siren(s) are inadvertently sounded, the cancellation tones are not automatically sent to the siren(s) due to the time factor. In most cases, reports of spurious siren sounding come In the form of calls from the public to the aJpropriate 911 Center which the~ notifies the ADH. It is noted that the sirens in Arkansas are hard coded to sound for 3 minutes before shutting off. As such, the siren has most likely "timed out" when the incident is reported. When the ADH receives a report of inadvertent siren sounding, the first step is to gather the information of the Inadvertent sounding reported, including the number of calls received, the generation location of the sound reported, the caller names and call back numbers. The ADH then will verify the existence of a siren in the reported activation area. If a siren is Identified in the reported area, a repair technician will visit the site to ascertain the status of the siren, and attempt to determine If Arkansas Nuclear One 13 ANS Design Report - Rev. 4

there was an actual activation or if there were other noise sources that Imitate a siren. Most reported siren sounds are in fact from other sources, for Instance, emergency vehicle sirens.

3.3 Operational Compone nts 3.3.1 Activation As discussed previously in Section 2.3, the SWS is activated by ADH through the primary or secondary activation points. As shown In Table 4, the primary activation point for the SWS is located at the ADH ECC office that is manned 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> per day to accommod ate day or night activation. One secondary activation point for the SWS Is located In the SEOF which is co-located at the ANO site; another secondary activation point is located in the ADH NP&RP office. All the activation points have the ability to activate the entire SWS, but for events where ANO is not involved, such as severe weather, activation is usually conducted by ADH ECC or by ADH NP&RP.

The NWS is notified by the ADH staff in advance of the sirens being activated. The NWS in turn utilizes the primary/ba ckup weather radio transmitte r to transmit the NOAA tone which automatica lly turns the receivers on. Both primary and secondary backup transmitte r sites are located on Mount Nebo, which is approxima tely 6 miles SSW of the ANO site.

3.3.2 nming According to ADH, when an emergency is declared at ANO, the ANO operator must notify state officials within 15 minutes. State offlclals can then notify the public of an emergency within 15 minutes by use of the EWS. The EWS activation will be conducted with a sense of urgency without undue delay.

The sirens activate within seconds of the signal being sent from the controller. The N(?AA tone is activated in conjunctio n with the siren activation. The backup method - route alerting - Is capable of alerting and notifying the 10-mile EPZ population within 45 minutes (see Section 4.3 and Section 5).

There are no exception areas (rural, low population areas) In the EPZ that would require additional time to be alerted and notified.

3 3.3 Geo-Targeting Individual sirens within the siren system can be activated to pinpoint a geographic location for alerts; however, this is not part of the standard alert procedure. NOAA radios cannot be individually sounded.

4 Verification 4.1 Coverage ANO recently conducted an extensive ac0ustical study of the siren system, Including detailed acoustical modeling and field testing of siren sound levels. The results of this study are summarized below.

Section 2.0 of FEMA Technical Bulletin (Version 2.0) "Outdoor Warning Systems" dated January 12, 2006 provides an extensive discussion of sound propagation. Below are some key points on sound taken from this guidance document:

  • Sound travels in waves
  • Sound decreases in loudness at greater distances from its source
  • Refraction: Sound waves can refract or bend with differences in temperatu re and wind speed.

The specific heat of the ground Is higher than that of the air above It. Thus, during the day, the ground Arkansas Nuclear One 14 ANS Design Report - Rev. 4

is warm and temperature decreases as you move higher above the ground. This difference in temperature impacts the speed of sound waves as shown in Figure 10. The resulting shadow zone causes the audible level of the siren to be lower at the ground. The opposite happens in the evening when the ground releases its heat to the atmosphere resulting in higher temperatures the farther you get from the ground, as shown In Figure 11. This explains why sounds from the same source are louder at night than they are In the daytime.

  • Ground Absorption: Soft ground such as grass covered soil or dense foliage can cause significant absorption of sound, thereby reducing perceived loudness of sound. Hard surfaces such as cpncrete, ice, or water can cause sound waves to reflect upwards and be perceived as louder as shown in Figure 12.
  • Wind: Wind speed either adds or subtracts to the velocity of sound waves depending on whether the sound is moving upwind or downwind, resulting in refraction of sound waves. Wind speed also increases with height above the ground causing further refraction. The additive refraction of these two phenomena can result in a significant acoustical shadow zone In the upwind direction as shown in Figure 13.
  • Diffraction: Sound waves can also be diffracted {bent upward or downward) by objects (buildings, trees) in the path between the source and the listener resulting in lower perceived loudness.

Figure 14 shows IJlUltiple potential factors that could impact the sound heard by a receiver from a source.

One way to deal with the complications that can impact the audible level of outdoor sirens is to use a sophisticated acoustic model that accounts for terrain and atmospheric conditions. Such a model, Sound PLAN, was used to predict t~e siren coverage In the ANO EPZ. The SoundPLAN software is a state-of-the-art acoustic model written by SoundPLAN, LLC (a German company) and distributed in the U.S. by Navcon Engineering Network In California. This software has been used to model the sire~ coverage for more than a dozen U.S. nuclear plants, induding the Diablo Canyon Power Plant In California, which has one of the most difficult terrains of any U.S. plant in terms of siren coverage.

Modeling Inputs and Assumptions The following inputs/assumptions were used in the acoustic modeling:

  • Digital elevation d,ata was provided by the United States Geological Survey (USGS) National Map Vlewer1°. A standard DEMu, was downloaded with a resolution of 1/3 arc-second, which Is an approximate grid spacing of 10 meters. This is more than adequate to model the terrain in the EPZ.
  • Ground surface absorption wa~ explicitly modeled. The software default value for ground surface absorption is 1 for all soft grounds such as fields or other grassy areas, and forests. The ground surface value was changed to O for major bodies of water to accurately depict the reflective properties of the hard surface.
  • The siren locations and model type documented in Table 3 were input to the model.

10 http tMgwer na11onalr)lao aoy/baslc/

11 htlo*(lnationalmap aov/30EP/3deo orodsert html Arkansas Nuclear One 15 ANS Design Report - Rev. 4

  • Acoustical tests were conducted on June 23 and June 24, 2020 to measure the sound levels output by sirens. The tests included seven near-field tests in accordance with ANSI 512.14, wherein a sound meter was aimed at the center of the siren horns from a bucket truck parallel with the siren horns at a distance of 100 feet. In addition to the near-field tests, far-field tests were conducted with siren meters on the ground at varying distances form the siren pole. Five WPS2907 sirens and two WPS2807 sirens were tested. Figure 15 presents the locations of the near-field and far-field test locations. The tests were conducted by acoustical expert - Dr. Bruce lkelheime r - using Larson Davis Model 831 sound level meters - and were supervised by the ADH and Entergy personnel. Weather conditions during the tests were good, with low winds and no precipitation.

The test results were analyzed and reported by Dr. Bruce lkelhelmer (s-ee Appendix E). The results of the near-field tests are summarized in Table 6. Based on the overall average results, sound levels of 115.ldBC and 115.SdBC are adopted for WPS2807 and WPS2907 siren models, respectively. The ANSI 512.14 test sheets for the seven near-field tests which provide additional details on the test are included In Appendix E.

  • The acoustical standard International Organization for Standardization (ISO) 9613-:2. 12 was used.

150-9613-2 Is a widely used standard for sound modeling and Is accurate at predicting total coverage areas at extended distances from the source.

  • The average daytime temperature, pressure and humidity were used to account for atmospheric conditions. These data were estimated as the 3-month average of June, July and August of 2019.

The historical weather data was obtained from the Weather Underground website 13

  • The location used was Hot Springs, which is located approximately 55 miles southeast of ANO. The atmospheric conditions used were:

o Average tempera ture= 79.B"F (26.S-C) o Average relative humidity = 77.2%

o Average air pressure= 29.4 inHg (995.2mbar)

As discussed In Section 3.1.2, the NOAA TARs are activated by the primary/secondary weather radio transmitt er located in Mount Nebo. As per the latest county radiological emergenc y response plans, the NOAA weather radio primary/backup transmitt er at Mount Nebo covers the following counties - Conway, Johnson, Perry, Pope and Yell. This has provided adequate coverage to the radio receivers within the 10-mile EPZ.

4.2 Population/Demographics Based on the population density analysis using the 2020 population projections (see Section 2.1.1), the overall population density in the ANO EPZ is low. Only parts of Russellvllle have a population density exceeding 2,000 persons per square mile, as shown in Figure 6. As discussed in Section 2.1.1, federal guidance recommends siren coverage of at least 70dBC In areas where the populatio n density exceeds 2,000 people per square mile, and 60dBC In all other areas. Also, as discussed in Section

-1, the ANS should provide direct coverage of essentially 100 percent of the population within 5 miles of the NPP site.

Figure 7, maps the predicted siren coverage for the ANO EPZ output by the SoundPLA N software based on the inputs and_ assumptions discussed above. The map shows the 60dB and 70dB contours, as well as the high population density areas discussed in Section 2.1.1.

12 13 https //www ISQ,0rg/standard/20649 html httos llwww.wunderground com/

Arkansas Nuclear One 16 ANS Design Report - Rev. 4

As shown In the map, the 60dBC coverage covers the majority of the 10-mile EPZ. All the high population density areas flagged red in Figure 7 have adequate 70dB coverage. As discussed In Section 2.1.4, the ADH maintains a database of addresses that are outside the 60dBC siren coverage area. Letters are sent to those addresses an,nually to ensure NOAA TARs are available to ~hose addresses to ensure completed coverage of the EPZ by the EWS.

4.3 Metrics Sound levels during siren activation were measured In many locations as discussed In Section 4.1 and shown In Figure 15. These sound level measurements were used to calibrate the acoustical model and predict GOdBC and 70dBC of the siren system in the EPZ.

As discussed in Section 4.1, the NOAA TAR refeivers within the 10-mile EPZ are fully covered by the NOAA weather radio primary/backup transmitter at Mount Nebo. According to the ADH, the NOAA radio signal strength has not been reported as an issue by any NOAA TAR holders. As discussed In Section 2.5, the NOAA radio program is operated by the NWS and administrated by the ADH NP&RP staff. The ADH retains several radio receivers in the ADH NP&RP office for constant monitoring. The NOAA radio system is also monitored by ANO EP personnel.

As per federal guidance, the primary ANS means should be capable of alerting and notifying the EPZ population within 15 minutes, and the backup means should be capable of alerting and notifying the EPZ population within 45 minutes. According to the ADH, the time for the EWS (primary method) activation and route alerting (backup method) process has been evaluated by FEMA several times during the bi-annual evaluated exercises, al"!d the timeline has been acceptable. The time for actual physical activation of the ENS by pushing the button is a matter of seconds.

5 Availability/Rel~ability As discussed in Section 2.12, the ADH maintains several procedures to provide detailed information of performing testing, maintenance, and record keeping for system maintenance/repair activities. The system testing, maintenance and siren malfunctions have been discussed In detail In Section 2.7 and in Section 2.9. Appendices B and C details the Quality Assurance procedures that are in place which have resulted In a 100% reliability score for the ANS In 2019 and reliability scores in excess of 99% for the past decade (see Section 2.8}. The Inadvertent activation of the SWS and the actions taken thereafter are discussed In Section 3.2.2.

As discussed in Section 43, the ability to meet the minimum activation time of 15 minutes has been successfully demonstrated in the bi-annual evaluated exercises, including the latest one on July 17, 2018.

The evaluation details are reported in the After-Action Report/Improvement Plan published by FEMA.

6 Security and Privacy The applications used to activate the SWS can only be accessed by authorized personnel with unique user IDs and passwords. Section 2.6 provides additional detail on the physical and cyber security of the ANS.

Arkansas Nuclear One 17 ANS Design Report - Rev. 4

7 Training and Public Outreach The ADH NP&RP is responsible for arranging the initial and continuing training for all staff members who are assigned to the ANO radiological emergency planning effort. The elements of training required for emergency personnel include the review of emergency classification levels, protective action advisories, methods of notification, notification procedures, procedures for dissemination of public information during a nuclear generating plant emergency, emergency nptiflcation forms, emergency staff positions arid responsibilities, facility set-up, layout and equipment.

The publlc is instructed by the EIB to tune to NOAA TARs and local radio stations for emergency instructions when the sirens are activated. The local radio stations have the capability to broadcast emergency messages on a 24-hour basis to the general public. The EIB Is available in both English and Spanish and can be accessed thr9ugh the ADH webslte14

  • The booklet also Includes contact information for emergency planning agencies should additional information on alert and notification or other emergency planning issues be needed.

In addition to the EIB, emergency information regarding notification procedures and those steps that should be taken in an emergency Is included in the official telephone directory distributed within the 10-mile EPZ and is updated annually. Education and informational programs are offered annually to area civic and service organizations, including public and private schools. These pro~rams include information on the EWS, evacuation routes, and designated care centers. An annual media workshop is conducted by ADH NP&RP to provide pre-incident information to the representatives of the Arkansas news media. The workshop provides Information on notification, evacuation and planning efforts. The ADH NP&RP will also provide the news media with periodic releases containing Information on any changes In notification, evacuation or planning efforts.

14 https.JlwNw.heelthy.arJqlnsas gov/prooralJ}S=mces{toolCS{nudea[:pjannmg-and-resoonse Arkansas Nuclear One 18 ANS Dl:slgn Report - Rev. 4

SIGNATURE LIST My agency has reviewed the enclosed Alert and Notification (ANS) Design Report in its entirety. We find the report to be accurate and complete, and to be in 'agreement with our agency's emergency plans. My signature below is my attestation to such.

FEMA Regional Representative (Print/Signature) Date Entergy Emergency Planning Representative (Print/Signature) Date Arkansas Department of Health (Print/Signature) Date

REVISION HISTORY Date Revision# Notes 3/5/1984 0 FEMA approval of original ANS for the ANO EPZ.

5/2009 1 Design report was updated to account for:

  • One-for-one replacement of 34 electromechanical sirens with Whelen and ATI electronic sirens without modifying or changing the control system, antennas and radio systems.
  • Results of an acoustical test following Installation of the new sirens to demonstrate that the updated siren system meets the design objectives.
  • The Failure Mode and Effects Analysis (FMEA) of the completed siren system.
  • Replacement of transmitters and radios for the tone alert system. ,

6/14/2011 2 Design report updated to correct siren GPS locations and siren coverage map.

5/2016 3 Design report was revised and supplemented to reflect the following changes:

2/2017

  • One-for-one replacement of the 28 ATI sirens with Whelen 2900-7 senes sirens.
  • Installation of an additional Whelen 2900-7 siren .
  • Results of the near-field tests indicate that the replacement of the 28 sirens provide a higher siren rated output.
  • Provide the Manufacturer's Technical Data, Operations and Troubleshooting Manual for the Whelen 2900-7 siren.
  • A replacement transmitter and replacement radios for the NOAA Tone Alert System.

9/2020 4 Design report was requested to update to include:

  • Update the siren coverage map using detailed Sound PLAN acoustical model and field testing of siren sound levels.
  • New guidance on report format and report content in FEMA Radiological Emergency Planning Program Manual dated December 2019.

Table of Contents EXECUTIVE

SUMMARY

................................................................................................................. ES-1 MAIN BODY 1 Licensing Obligations ............................................................................................................................ 1 2 Requirements ................................................*....................................................................................... 2 2.1 System Coverage ..........................................................-................................................................. 2 2.1.1 Population ............................................................................................................................. 2 2.1.2 Geographic Area ................................................................................................................... 4 2.1.3 Means .................................................................................................................................... 5 2.1.4 Primary Methods .................................................................................................................. 6 2.1.5 Backup Methods ................................................................................................................... 6 2.2 Population/Demographics ............................................................................................................ 6 2.3 Interoperability ............................................................................................................................. 7 2.4 Operations .................................................................................................................................... 8 2.5 Management/Administration .........................................................:............................................. 8 2.6 Security and Privacy ...................................................................................................................... 9 2.6.1 'Physical Security .................................................................................................................... 9 2.6.2 Logical Security: ..................... '. ........................................ :..........................................._........... 9 2.7 Maintenance/Repair ......................................................'...... ._........................................................ 9 2.7.1 Preventative Maintenance ........................ '. ........................................................................... 9 2.7.2 Corrective Maintenance ........................................................................................................ 9 2.8 Availability/Reliability ................................................................................................................. 10 2.9 Testing ......................................................................................................................................... 10 2.10 Responsibility ...._.......................................................................................................................... 11 2.11 Training ....................................................................................................................................... 11 2.12 Quality Assurance ....................................................................................................................... 11 3 Description/Performance ................................................................................................................... 12 3.1 Physical requirements ................................................................................................................. 12

,3.1.1 System Components ........................................................................................................... 12 3.1.2 User Interfaces .................................................................................................................... 12 3.1.3 Functional Block Diagrams .................................................................................................. 12 3.2 Administrative Components ........................................................... ,........................................... 13 3.2.1 Organizational Responsibilities ..........................................-................................................. 13 3.2.2 Management ........................................................................................................................ 13 3.3 Oper~tional Components ..................................................*.............. :.......................................... 14 3.3.1 Activation ............................................................................................................................ 14 3.3.2 nming .................................................................................................................................. 14 3.3.3 Geo-Targeting ..................................................................... :............................................... 14 4 Verification .......................................................................................................................................... 14 Arkansas Nuclear One ANS Design Report - Rev. 4

4.1 Coverage ..................................................................................................................................... 14 4.2 Population/Demographics .......................................................................................................... 16 4.3 Metrics ........................................................................................................................................ 17 5 Availability/Reliability ......................................................................................................................... 17 6 Security and Privacy ............................................................................................................................ 17 7 Training and Public Outreach .............................................................................................................. 18 REFERENCES ***************************************************************************************************************************************R-1 LIST OF APPENDICES A. Compliance with F~deral Regulations and Guidance ....................................................................... A-1 B. ANO EWS Activation Procedures ....................................................................................................... B-1 C. ANO SWS Testing and Maintenance Procedures ............................................................................... C-1 D. WPS2800 and WPS2900 Series Operating and Troubleshooting Manuals ....................................... D-1 E. Siren Test Result Report ..................................................................................................................... E-1 LIST OF FIGURES Figure 1. Site Location ................................................................................................................................. 26 Figure 2. Permanent Resident Population by Sector for the ANO EPZ ....................................................... 27 Figure 3. Census Blocks with Population Density Exceeding 2,000 People per Square Mile ..................... 28 Figure 4. Census Blocks with Population Density Exceeding 2,000 People per Square Mile (Filter 1 Applied) ....................................................................................................................................................... 29 Figure 5. Applying Filter ito Eliminate Isolated Neighborhoods from High Population Density Consideration .............................................................................................................................................. 30 Figure 6. Final Census Blocks with Population Density Exceeding 2,000 People per Square Mile after Applying Filters ............................................................................................................................................ 31 Figure 7. Siren Coverage Map for the ANO EPZ .......................................................................................... 32 Figure 8. Siren System Within the ANO EPZ ................................................................................................ 33 Figure 9. Control System Layout for the ANO ANS Siren System ............................................................... 34 Figure 10. Sound Transmission in Temperature Lapse Conditions ............................................................. 35 Figure 11. Sound Transmission in Temperature Inversion Conditions ....................................................... 35 Figure 12. Outdoor Sound Propagation near the Ground .......................................................................... 35 Figure 13. Upwind Sound Propagation ....................................................................................................... 36 Figure 14. Downwind Sound Propagation with Terrain and Vegetation Effects ........................................ 36 Figure 15. Near-Field and Far-Field Test Locations ..................................................................................... 37 LIST OF TABLES Table 1. EPZ Population by Decennial Census ............................................................................................ 19 Table 2. Population Density Computed using Different Geographic Areas ................................................ 20 Table 3. Siren Details for the ANO EPZ ....................................................................................................... 21 Table 4. SWS Activation Points for ANO Site .............................................................................................. 25 Table 5. Siren System Reliabiiity ................................................................................................................. 25 Table 6. Summary of Near-Field Acoustical Test Results ............................................................................ 25 Table A-1. Regulations Crosswalk ............................................................................................................. A-2 Arkansas Nuclear One ii ANS Design Report- Rev. 4

EXECUTIVE

SUMMARY

I The Arkansas Nuclear One (ANO) is located on a peninsula near the Town of Russellville in southwestern Pope County, Arkansas. The Emergency Planning Zone (EPZ) for ANO includes parts of Johnson, Logan, Pope, and Yell Counties. The permanent resident population for the EPZ is 52,871 people as per the 2010 U.S. Census.

The Alert and Notification System (ANS) for the ANO relies on the Siren Warning System (SWS) and the National Oceanic and Atmospheric Administration (NOAA) Tone Alert System as the primary means of alerting the public. Route alerting is used as the backup means to alert the residents around the failed or inoperable siren(s). Public information materials are distributed to the EPZ populace to inform people what to do if they hear sirens sounding or a loud tone from the activated NOAA Tone Alert Radios, and what radio stations to tune into for additional information.

The SWS consists of 50 omni-directional electronic sirens (21 Whelen WPS2807 sirens and 29 Whelen WPS2907 sirens). The location, model type and mounted height of ea_ch siren were input to SoundPLAN acoustic modeling software to estimate the audible level of the sirens throughout the 10-mile EPZ surrounding ANO. The SWS provides 60dBC coverage to 92.6% of the population within the EPZ and 70dBC coverage to the areas with popu1ation density exceeding 2,000 people per square mile. NOAA Tone Alert Radios are provided to residents of the 10-mil~ EPZ who live outside the 60dBC coverage or who have special needs. The radios are also provided to facilities within the 10-mile EPZ with significant population. The ANO tests the ANS routinely and has an extensive maintenance program in place to I

ensure continuous, reliable operation of the ANS. The ANS for ANO has had a reliability performance indicator of 100% for 2019. The reliability of the ANS has not dropped below 99% during the last decade of operatlon. Operators of the ANS are offered training as needed to ensure continued reliable operation ofthe system.

All siren batteries and control boxes are locked and mounted on the siren pole to prevent tampering.

The siren activation equipment is installed at secure locations (the Arkansas Department of Health offices). The ANS system includes a DTMF encoder that requires key-lock activation to make it resistant to cyber-attack.

This ANS design report is an update to the last ANS report (Rev. 3 dated 2/2017) to update the siren coverage map using outputs from the detailed SoundPLAN acoustic model and field testing of siren sound levels, and to address the new guidance on ANS design report formatting and content documented in the December 2019 FEMA REP Program Manual.

Arkansas Nuclear One ANS Design Report- Rev. 4

1 Licensing Obligations ntle 10 of the Code of Federal Regulations (CFR) §50.47(b), item (5) and Title 44 of the CFR §350.S(a),

rtem (5) state:

"Procedures have been established for notification, by the licensee, of State and local Fesponse organizations and for notification of emergency personnel by all organizations; the content of initial and follow-up m*essages to response organiiations and the public has been established; and means to provide early notification and clear instruction to the populace within the plume exposure pathway Emergency Planning Zone [EPZ] have been established."

The December 2019 FEMA Radiological Emergency Preparedness (REP) Program Manual states, "the alerting and notification of the public is a function of the state, local, tribal and territorial governments' emergency plans. An NPP [Nuclear Power Plant] applicant/licensee is required to demonstrate that the administrative and physical means are established for alerting the public and providing instructions, regardless of who implements the ANS [Alert and Notification System] capability. An applicant/licensee may install and maintain the ANS but the responsibility for the alerting and notifying the public, as well as the activation of the ANS, remains with the state, local, tribal and territorial governments."

This ANS design report describes the physical and administrative means established by Entergy to assist the states and counties in alerting and notifying the public in an emergency. Detail of the state and county actions can be found in the state a11d county radiological emergency plans.

As discussed in the December 2019 version of the FEMA REP Program Manual, the initial federal guidance on ANS provided in NUREG-0654/FEMA-REP-1, Rev. 11, Appendix 3 (1980) and FEMA-REP-10 ("Guidance for the Evaluation of Alert and Notification Systems for Nuclear Power Plants") (1985) "predated technology many citizens now take for granted (e.g., smartphones, social media, etc.)." As such, the FEMA REP Program Manual is now the recognized federal ANS guidance document as it "allows evaluators to account for new technologies, consider updated NRC/FEMA guidance, and incorporate REP lessons learned." This ANS design report adheres to the guidance of the latest FEMA REP Program Manual (December 2019), but does rely on data and information from the following additional guidance documents:

  • NUREG-0654/FEMA-REP-1, Rev. 11 (1980) including Supplement 4 (2011)
  • FEMA CPG 1-17, "Outdoor Warning Systems Guide" (1980)
  • FEMA-REP-10 (1985)
  • . FEMA Technical Bulletin (Version 2.0) "Outdoor Warning Systems" (2006)
  • NEI 13-01, R~vision 0, "Reportable Action Levels for Loss of Emergency Preparedness Capabilities" Part V, Section B of the 2019 FEMA REP Program Manual discuss ANS design objectives. The minimum acceptable design objectives for coverage by an ANS - what the system must be able to do when speed is critical - include:

1 This document IS outdated, being replaced wrth Rev 2 In December 2019 One of the goals of Rev 2 of thls document and of the December 2019 revIs10n of the FEMA REP Program Manual was to not mention specific technologies (1 e, sirens) in reference to ANS Nonetheless, Rev 1 of ttus document does Include valuable guidance on outdoor warning sirens

  • The capability to provide both an alert signal and an informational or. instructional message to the population in the EPZ within 15 minutes.
  • The initial notification system will ensure direct coverage of essentially 100 percent of the population within 5 miles of the NPP site.
  • Notification methods will be established to ensure coverage within 45 minutes of essentially 100 percent of the population in the EPZ who may not have received the initial notification including any special requirement exceptions (e.g., large water areas with transient boats or remote hiking trails).
  • The capability of the ANS to cover essentially 100 percent of the population within the EPZ, regardless of failures. The corrective means/measures will be conducted within a reasonable time, with a recommended goal of 45 minutes. The use of a sequential failure model or "primary and backup" ANS model is acceptable. Other models, such as simultaneous or concurrent activation models, could be used.

All of these criteria are met by the ANS system in the Arkansas Nuclear One (ANO) EPZ, as discussed in the sections below.-

2 Requirements 2.1 System Coverage 2.1.1 P-epulation The ANO site is located near the Town of Russellville in southwestern Pope County, Arkansas. The EPZ is located entirely within the State of Arkansas and consists of portions of four counties - Johnson, Logan, Pope, and Yell Counties. Figure 1 shows the location of ANO as well as the approximate 10-mile EPZ.

The permanent resident population in the EPZ is 52,871 people according to the 2010 Census. Table 1 summarizes the permanent resident population and population density in the EPZ, by Zone, for the last two decennial censuses conducted by the U.S. Census Bureau. As the data indicate, population in the EPZ has increased since 2000, with an' increase of +3.8% for the 2-mile radius of the plant, +12.8% for those Zones within the 5-mile radius, and +13.6% for the EPZ as a whole.

A common method for displaying population around a nuclear power plant is by sector. The EPZ is divided up into one-mile increments and the sixteen cardinal and inter-cardinal wind directions, for a total of 160 sectors. The 2010 EPZ permanent resident population, by sector, is shown in Figure 2.

The federal guidance, FEMA-REP-10, "Guide for the Evaluation of Alert and Notification Systems for Nuclear Power.Plants," indicates that sirens are in compliance with federal guidance if they meet either of the following conditions: "

  • The expected siren sound pressure level generally exceeds 70dBC where the population exceeds 2,000 persons per square mile and 60dBC in other inhabited areas; or
  • The expected siren sound pressure level generally exceeds the average measured summer daytime ambient sound pressure levels by 10dB (geographical areas with less than 2,000 persons per square mile)."

FEMA CPG 1-17, "Outdoor Warning Systems Guide" indicates that people typically mentally block out sounds that are not pertinent to what they are doing. In order to break the mental block, a warning sound Arkansas Nuclear One 2 ANS Design Report- Rev. 4

must be about 9dBC greater than ambient noise to capture the attention of the listener. This is the basis of the conservative 10dBC above ambient noise guidance. Ambient noise levels were not measured in the ANO EPZ; thus, 60dBC and 70dBC will be used as the criteria for siren sound levels in this report, depending on the population density in a given area.

In order to determine whether 60dBC or 70dBC coverage is needed, population density was computed.

There are many different methods for computing population density:

  • Population density by radial distance mile radius, 5-mile radius, or the full approximate 10-mile EPZ
  • Population density by county
  • Population density by municipality As shown in Table 2, these population densities differ significantly, underscoring the uneven distribution of population in the EPZ. Higher sound pressure levels are required in densely populated areas to overcome the higher ambient noise levels associated with a larger number of people and increased activity. Computing the population density by a large radial distance, or by county can distort population density by incorporating large land areas that are unpopulated or sparsely populated. This could result in the failure to adequately identify areas that need 70dBC coverage. For example, Table 2 indicates that the municipalities in the EPZ have population densities ranging from 211 to 1,303 people per square mile.

However, when considering the population density for each county as a whole, it is considerably lower (ranging from 24 to 76 people per square mile).

The most refined method for computing population density is by census block. The U.S. Census Bureau divides the U.S. into census tracts. These census tracts are in turn divided into block groups, and block groups are comprised of multiple blocks. The census block is the finest level at which the U.S. Census Bureau aggregates detailed population data.

Census blocks vary in size from as small as a single city block to as large as an- entire county. Given the variance in block size, there is the potential to have abnormally high population density for a block with a very small area. Similarly, a small neighborhood can have a population density exceeding 2,000 people per square mile but it _may be the only community for miles. Assuming this neighborhood has 100 people living in an area of about 0.04 square miles (approximately 26 acres - 50 homes on 1/2 acre plots), the population density would exceed 2,000 people per square mile. However, if there are no surrounding neighborhoods, 100 people are not likely to generate enough background noise to warrant 70dBC coverage.

The last physical census in the United States was conducted in 2010 (the 2020 Census is ongoing, but data will not be released until March 31, 2021). Thus, the 2010 Census serves as the basis for all population estimates in this document. Each year in May, the U.S. Census Bureau releases projected populations for each state, county and municipality in the U.S. The latest available census popui'ation estimates, as of July 1, 2019, which were released in May 2020 (when this analysis documented in this report was started),

from the U.S. Census Bureau were used to compute annual growth rates by county and municipality.

These growth rates were then used to extrapolate the 2010 census population in the EPZ to 2020 at the Arkansas Nuclear One 3 ANS Design Report - Rev. 4

block level. For more infom,ation, please refer to the 2020 Evacuation lime Estimate {ETE} update2 for ANO.

The following methodology was used to compute population density within the EPZ, by census block.

Population block data was overlaid on the EPZ boundary usirig Geographic Information Systems {GIS}

mapping software. The population density was computed by dividing the 2020 extrapolated population by the area of the block in square miles. Any block with a density exceeding 2,000 peqple per square mile was flagged (block color coded red} as high density as shown in Figure 3.

As discussed above, there is a possibility of isolated neighborhoods or extremely small census blocks being flagged with abnormally high population densities. While mathematically the population densities are correct, these anomalous census blocks do not represent densely populated areas that would have significant background noise warranting_ 70dB siren sound levels. Two steps were taken to remove these anomalous census blocks from the actual high population density areas:

1. A filter was applied which eliminates all flagged bloc!<5 that have a population less than 100 people or an area less than 0.02 square miles. This filter eliminates sparsely populated census blocks which are abnorrnally small and result in unrealistically high population densities. Figure 4 displays those blocks which are still flagged after applying this filter.
2. Each flagged census block with a population density exceeding 2,000 people per square mile was converted into a circle with an area of 1 square mile, centered at the center of the block. These 1 square mile circles were then overlaid with the census block data once again and the population density of the 1 square mile circle was recalculated. If the density exceeded 2,000 people per square mile, the block which the circle was .centered at remained flagged as having a high population density. If the density of the circle fell below the threshold, the block the circle was centered at was removed from consideration. This filter eliminates isolated high population density neighborhoods that are surrounded by areas of low population density. Figure 5 shows an example of this filter applied to three census blocks in the EPZ. Both blocks shown in Step 1 are flagged as high population density blocks after applying Filter 1. However, when drawing the 1 square mile circles (Step 2.1} centered at the blocks, the population density (Step 2.2) is well below the 2,000 people per square mile threshold. As a result, both blocks are eliminated as high population density blocks (Step 2.3). Figure 6 shows the final blocks flagged as having population density exceeding 2,000 people per square mile in the EPZ after the two filters were applied.

2.1.2 Geographic Area The ANO site is situated on a peninsula fom,ed by Lake Dardanelle, which includes the Arkansas River and the fomier Illinois Bayou. The land within 5 miles of the plant is gently rolling and contains a number of ridge-valley configurations. The Arkansas River and Lake Dardanelle roughly bisect the ANO EPZ.

The meteorological information for each of the EPZ counties is described below.

Johnson County3 is characterized by hot summers and cold winters, with an average high temperature of 90 degrees Fahrenheit (°F) in July and an average low.temperature of 27°F in January. The average rainfall 2

"Arkansas Nuclear One 2020 Populallon Update Analysis", KLD TR-1167, dated September 19, 2020

'https*//www bestpjaces net/clunate/coUntv/arkansashohnson Arkansas Nuclear One 4- ANS Design Report - Rev. 4

and snowfall in the county is 50 inches and 4 inches, respectively. The number of days with any measurable precipitation is 96. Johnson County is at an average elevation of 1,017 feet.

Logan County4 is also characterized by hot summers and cold winters, with an average high temperature of 92°F in July and an average low temperature of 28°F in January. The average rainfall and snowfall in the county is 49 inches and 2 inches, respectively. The number of days with any measurable precipitation is

\

95. Logan County is at an average elevation of 678 feet.

Pope County5 is also characterized by hot summers and cold winters, with an average high temperature of 91 °Fin July and an average low temperature of 28°F in January. The average rainfall and snowfall in the county is 50 inches and 4 inches, respectively. The number of days with any measurable precipitation is 101. Pope County is at an average elevation of 835 feet.

Yell County6 is also characterized by hot summers and cold winters, with an average high temperature of 93°F in July and an average low temperature of 29°F in January. The average rainfall and snowfall in the county is 51 inches and 3 inches, respectively. The number of days with any measurable precipitation is

95. Yell County is at an average elevation of 626 feet.

Figure 1 identifies the municipal areas and major roads in the area, as well as the 15 Zones that comprise the approximate 10-mile EPZ. The Zones are color-coded based on the county they are in.

The National Oceanic and Atmospheric Administration (NOAA) commissioned a study 7 to summarize historical wind data from 1930 to 1996 in the United States. Wind data was aggregated for Fort Smith Regional Airport, which is the closest airport to ANO. The average wind speed at Fort Smith Regional Airport, based on the data gathered, ranges from a low of 6 miles per hour (mph) in July to a high of 8mph in January.

As shown in Figure 1 and listed in Table 2, there are 6 municipalities within the EPZ. Most of the municipalities are located adjacent to the Arkansas River and Lake D_ardanelle. Beyond the population centers is sparsely populated rural farmland or undeveloped land.

The population centers in the ANO EPZ are connected by an extensive highway network. Interstate 40 and US Route 64 travel northwest-southeast through the EPZ. The major state highways servicing the EPZ include Arkansas State Routes 7, 22, 27, 28, 124, 164, 247, 315, 326, 331, 333 and 359. The primary railroads within the EPZ include Dardanelle and Russellville Railroad and Missouri Pacific Railroad .

2.1.3 Means The physical means of alerting and notifying the public within the ANO 10-mile EPZ is the Emergency Warning System (EWS) that consists of a mixture of the Siren Warning System (SWS) and the NOAA Tone Alert System. The ANS is essentially designed to notify the individuals in the 10-mile EPZ within 15 minutes of the issuance of recommendations by the State of Arkansas for radiological emergencies at ANO. Local fire departments in the EPZ and route alerting are used as the backup method to alert the public to receive instructions, information, and necessary actions to be taken.

4 https IIWHW bestplaces nettd1mate/county/arkansas/logan e https*lfwww bestplaces netlchmate/county/arkansas/pope e https 1

ttwww bestplaces nevchmate1county1ar1gmsastyell https*/Jwww ncdc noaa qov/srtes/defaull/ffies/attachments/wmdl 996,pdf Arkansas Nuclear One 5 ANS Design Report - Rev. 4

2.1.4 Primary Methods The primary ANS for ANO is the EWS as discussed above. The SWS is used to alert the more densely populated areas shown in Figure 7. Based on the population estimates discussed in Section 2.1.1, the SWS covers 92.6% of the population within the EPZ at 60dBC or higher. Those residents of the 10-mile EPZ who live outside the siren coverage area or who have special needs are alerted by NOAA Tone Alert Radios (TAR). NOAA TARs are also provided to the facilities within the 10-mile EPZ with significant population.

These individuals and facilities are further discussed in Section 2.2.

The SWS relies on 50 Whelen omni-directional electronic sirens (21 WPS2807 sirens and 29 WPS2907 sirens). Of the 50 sirens, there are 2 sirens in Johnson County, 3 sirens in Logan County, 33 sirens in Pope County and 12 sirens in Yell County. All sirens ;:ire mounted at pole top, approximately 50 feet above the ground. The location, h~ight and ID for each siren are presented in Table 3.

All of the sirens are radio-controlled and a DTMF (Dual Tone Multiple Frequency) encoder is required for activation. Sirens include a National Nuclear Attack signal that insists of an up-and-down scale tone. This three-minute continuous tone signal will be used to alert the populace to tune into NOAA TARs and local radio stations for emergency information (primary notification). Sirens also include a warning signal. This signal is used to alert the populace of not only a radiological incident, but also of natural disasters, especially tornado warnings.

The Arkansas Department of Health (ADH) maintains a database of addresses that are outside of the 60dBC siren coverage area. Each year a letter is sent to those addresses to verify if they have a NOAA TAR and if it is functioning. If they do not have a TAR or if the TAR is not functioning, they can request that ADH provide a TAR. The ADH also mails batteries to the TAR holders annually.

The NOAA Tone Alert System is operated in cooperation with the National Weather Service (NWS). When activated, a loud tone is emitted from the radio to alert the user. Following activation of the receivers, live or pre-recorded emergency messages are broadcast to instruct/notify the public. Section 3.1 below provides additional details of the EWS.

2.1.5 Backup Methods Supplemental notification to the EPZ population is provided by local fire departments in the EPZ. In the event of siren or NOAA Tone Alert System failures, route alerting is implemented in the affected fire district(s) using truck sirens and Public Address (PA) systems for notification of r~sidents around the failed or inoperable siren(s). The truck sirens serve as the backup alert method, while the announcements being made over the PA system serve as the backup notification method.

2.2 Population/Demographics In addition to the pennanent resident population detailed in Section 2.1.1, there are transients who may be visiting the EPZ for recreational purposes. Those people who live and recreate in the EPZ have already been considered as permanent residents to avoid double counting population.

According to the latest ETE study done for ANO (KLD TR-517, "Arkansas Nuclear One - Development of Evacuation Time Estimates," Rev. 1, dated December 2012), there could be as many as 11,745 transients in the EPZ at peak times. The transient estimate is based on data provided by county emergency management agencies.

Arkansas Nuclear One 6 ANS Design Report- Rev. 4

There are 69 special facilities identified In the EPZ. These facilities include schools, universities, parks, campgrounds, golf courses, marinas, recreational areas, lodging facilities, major employers, medical facilities, and correctional facilities. The EWS is capable of alerting and notifying each of these special facilities. Nonetheless, the State has plans in place to notify each of these facilities individually as discussed below.

As per the Arkansas Comprehensive Emergency Management Plan (ARCEMP), Rev. 39, dated September 30, 2019, the State Department of Parks and Tourism will provide notification of the public within the park system; the State Game and Fish Commission and State Forestry Division will provide backup communications and personnel for notification purposes in remote forest areas, and on rivers and lakes; the ADH repeater system will alert the emergency response agencies and schools within the 10-mile EPZ through the Early Notification System (ENS) component of the EWS; and information contained in the Emergency Instruction Booklet8 (EIB) is posted and/or placed in public locations within the 10-mile EPZ such-as public buildings, state and national parks, recreational areas, tourist information centers and rest areas located on major highways, which are routinely visited by transient populations. Postings will be checked periodically and updated as needed. In addition, letters of agreement formalizing the emergency notification interfaces between Entergy and Arkansas Tech University in *Russellville are kept on file in Entergy's offices.

None of the areas discussed above are considered exception areas. They can all be alerted and notified in a timely fashion.

Special provisions have been developed by ADH Nuclear Planning & Response Program (NP&RP) and Entergy for the alerting of identified handicapped individuals. A postage-prepaid, detachable postcard is

. provided in the annual mailing of the EIB for use by persons who may have special needs. This form is to be completed and then mailed to the ADH NP&RP office, and the information is subsequently provided to the appropriate local government. The individuals with special needs, depending upon their handicap, are notified appropriately. The notification may include door-to-door notification by law enforcement officers, neighbors, telephones, or tone activated NOAA TARs. Persons who are hearing impaired, or who require special notification are- provided NOAA TARs free of charge. These receivers are also made available to the large businesses, hospitals, nursing homes, schools, day reception centers, and other applicable groups within the 10-mile EPZ.

According to American Community Survey 2014 - 2018 data 9, the percent of non-English speakers within the EPZ is approximately 0.56%. Given the small size of non-English speaking population, English is the only language used for notification.

2.3 Interoperability The SWS is divided into 5 siren activation zones of relatively higher population density covering parts of the 10-mile EPZ, specifically: Yell County (lZ as Zone 1), the Russellville/Dover area and the Village of London in Pope County (2Z and 3Z), Johnson County (4Z), and Logan County (SZ). Each of these zones can be activated Independently or in conjunction with other zones. All zones would be activated in the event of emergency at the ANO site.

8 httpsJ/www healthy arkansas gov/imaqes/uok>ads/pdf/AR Nuc0ne20 ENGweb.pdf e AddrtJonal details about language spoken at home can be found at the following website https /lfactfinder census.aov/facestafthelphsf/oageslmetadata xhtml'-'1anQ:'en&typectable&d--table en ACS 17 5YR s 16004 Arkansas Nuclear One 7 ANS Design Report - Rev. 4

The ADH has the sole ability to activate the SWS. There are three activation points - one primary and two backup points, as discussed in Section 3.1.3 and Section 3.3.1. The locations of the activation points are outlin~d in Table 4. All the activation points have backup power and two independent paths for activat,ion signals to reach the sites. The SWS is activated by .radio signal. in the UHF (Ultra High Frequency) band which is transmitted by the primary/backup siren radio transmitter. The architecture of the SWS activation is discussed in detail in Section 3.1.3. The SWS activation is also made available to local governments for use in severe weather and other emergencies. Authorized officials may request siren.activation for various zones in their jurisdictions.

The sirens are battery operated and are powered by four high -capacity batteries. Battery charge is maintained by AC power through "smart" chargers to avoid overcharging. Sirens, depending on use, can keep operating up to 10 days without AC power. The ADH has mobile generator units that can be used in the event an AC power outage exceeds that length of time.

The NOAA TARs are activated by the NWS through a 300-watt transmitter with a 300-watt backup transmitter. The NWS is contacted by the ADH staff and informed of the intent to activate the EWS. The NWS is notified in advance of the sirens being activated such that, in conjunction-with the siren activation, the NWS activates the NOAA tone which automatically turns the receivers on.

2.4 Operations ,

ANO maintains the capabilities to assess, classify, and declare an emergency conditi~n within 15 minutes of the availability of indications to plant operators that an emergency action level has been exceeded.

Emergency persqnnel are trained to promptly declare the emergency condition as soon as possible following identification of the appropriate emergency classification level. There are four emergency classification levels - Notification of Unusual Event, Alert, Site Area Emergency and General Emergency.

The EWS within the 10-mile EPZ might be activated by ADH for a Site Area Emergency and will be activated for a General Emergency.

The final decisions to alert and notify the public by the EWS are the decisions of governmental officials.

Initial notifi~ation is made to the state. and local authorities within 15 minutes after declaring an emergency. An Emergency Action Authenticator is used to verify messages that are received over a non-

, ' ' J secure system, such_ as commercial telephone system. The NRC is notified immediately following notification of s_tate and local authorities and within 1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br /> of the declared emergency.

The EWS can be fully activated from the ADH Emergency Communication Center (ECC), the alternate State Emergency Operations Facility (SEOF) or the ADH NP&RP office. Anytime the SWS is to be activated to notify the public, ADH NP&RP will take over operation of radio station-KXRJ, 91.9 FM at Arkansas Tech University.*ADH NP&RP has the capability to remotely take over broadcast of this station and provide the public with any emergency communications or protective actions that might become necessary. The detailed ~ctivation process is included in Appendix B.

2:5 Management/Administration It is the responsibility of ADH to manage and oversee the EWS network. The NOAA radio program is administrated by ADH NP.&RP and operated by NWS. The NWS is responsible for managing the weather radio transmitters nationwide.

Arkansas Nuclear One 8 ANS Design Report - Rev. 4

2.6 Security and Privacy 2.6.1 Physical Security All siren batteries and control boxes are pad locked and mounted on the siren pole to prevent tampering, and both AC and battery voltage can be monitored remotely. The siren activation equipment is installed at secure locations that are manned 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> per day. Entry into all activation points is limited to authorized personnel only. Additionally, all activation consoles are equipped with a physical keyed lock to prevent access to the activation keys.

2.6.2 Logical Security To prevent cyber-attack, the actual activation of the EWS is accomplished by use of a DTMF encoder requiring key-lock activation. Details of either activation procedure are limited to a "Need-to-Know" basis for security reasons.

2.7 Maintenance/Repair 2.7.1 Preventative Maintenance It is the responsibility of ADH NP&RP to perform the Preventive Maintenance (PM) on the SWS. On a quarterly basis, the PM is performed following the instructions listed in the ANO SWS Maintenance Plan (see Appendix C). During the scheduled PM, each siren may experience brief periods when it is not able to sound, but it is not taken out of service for more than a few minutes and could be returned to service immediately, if needed. As noted in the*maintenance plan, a wide variety of inspections are performed at each siren site including verification that there is no vegetation growth that can obstruct sound propagation near the siren head; visual inspection of the p'ole, the antenna, the siren head, the cabinet and associated connections; verifying acceptable condition of the batteries and chargers; and running a silent test. In addition, the ADH performs the maintenance with contractor assisted items, such as crane rental for upper driver maintenance.

The ADH NP&RP also checks the operation of the control points and transceivers associated with the activation system on a routine basis. The operability of key components, for instance, is verified every weekday. Additionally, a contractor is used to measure the transceiver perimeters.

The ADH NP&RP mails information annually to every address within the lQ-mile EPZ to provide the contact information for the request of the NOAA TARs. On a monthly basis, the ADH mails letters to the new residents within the 10-mile EPZ to notify them of the same information. Recipients of the NOAA TARs are tracked in a master database by the NP&RP staff as discussed in Section 2.1.4. Needed repair and/or replacement of the receivers identified as defective is also carried out by the NP&RP staff. Alrthe holders of the NOAA TARs receive new batteries and instructions from the ADH annually.

2.7.2 Corrective Maintenance Upon notification of a siren malfunction, the ADH determines if the failure(s) is reportable in accordance with 10CFR 50.72, and the noted siren malfunction is immediately serviced by an ADH NP&RP Electronics Technician and every attempt is made to return the unit to operation. If the siren is unavailable, the appropriate county is notified that the backup alert method - route alerting - will be required in the affected area until the unit is returned to service.

A siren that did not fully respond to the activation command signal during a valid test is considered as an activation failure and would not have provided adequate public alert. It would be reported as a siren Arkansas Nuclear One 9 ANS Design Report- Rev. 4

failure to FEMA and to ANO Emergency Planning (EP) personnel. A siren is considered out of service when it cannot receive, process, or sound the appropriate audible warning tone through the driver section.

When determination has been made that a SWS component is not responding appropriately to polling, such as low battery, AC voltage or related issues; or reports or concerns from the public indicating siren abnormal behavior, an on-site inspection and repair will be performed by an ADH NP&RP Electronics Technician. The Electronics Technician will follow the guidelines recommended in the manufacturer's operating and troubleshooting manuals (see Appendix D) to restore component functionality. The Electronics Technicians also meet routinely with the ADH Section Chief to identify any maintenance and/or perform.ance trends. Trends are noted and corrective actions are implemented, if needed.

In addition, the ADH tests the siren control transmitters and consoles every weekday morning, when the state offices are open. If a problem is identified, the corresponding corrective action is immediately undertaken. The use of redundant transmitters and activation points minimizes the risk of a failure of the activation system.

  • 2.8 Availability/Reliability Appendix 4 of FEMA REP-10 specifies that the operability of a siren system is considered acceptable "when an average of 90% of the sirens (as determined by a simple average of all regularly conducted tests) can be demonstrated functional over the 12-month period immediately preceding the submittal of the design report."

The Nuclear Energy Institute (NEI) Regulatory Assessment Performance Indicator Guideline, NEI 99-02 Revision 7, specifies a minimum performance indicator threshold of 94% for ANS Reliability during the previous four quarters for plants operating in the normal regulatory response band.

The ANO SWS reliability data is reported to FEMA for review on a quarterly basis. According to the ADH, the ANO siren system has been operational since 1981. A review was completed over the past 10 years and it was determined that the successful siren performance has not dropped below 99% during that time. Table 5 shows the results of siren tests at ANO for the last 4 quarters. As shown, the siren performance in each quarter of 2019 was 100%.

2.9 Testing The EWS is tested by ADH and NWS periodically to ensure its readiness. The testing includes functionality of sirens and of NOAA TARs.

The entire SWS is sounded weekly to reinforce public awareness of the system. This is not a silent or growl test, but either a 15-second or 1-minute audible test each Wednesday at 12:00 pm. Testing will not be performed if severe weather is present in the area or the state offices are closed. Under a verbal agreement with FEMA, the 1-minute audible test is perfonned on the 4 th Wednesday ofthe month. The operation of each siren is verified once per month and the results are reported to FEMA. Due to the fact that the weekly audible test far exceeds the annual federal operability requirement, other types of audible tests are not conducted at the ANO.

In addition to the weekly audible test, sirens are polled for health maintenance at least once per month.

The health of siren batteries is assessed by the ADH NP&RP Electronics Technician on a quarterly basis (see Section 2.7.1). Batteries are replaced at a frequency that exceeds the battery manufacturer's recommendations. The siren activation equipment is tested frequently (see Section 2.7.2). Special Arkansas Nuclear One 10 ANS Design Report - Rev. 4

observations may be conducted in the event of severe weather or high winds which might result in physical damage, such as identifying loose feed lines or pole damage. If any issues are identified during these observations, repairs will be undertaken using the ANO SWS Maintenance Plan in Appendix C.

The NOAA TAR activation is tested by the NWS and monitored by ADH NP&RP. The testing is performed each Wednesday between 11:00 am and 12:00 pm. If inclement weather persists, the testing will be performed the next clear day.

The current testing conducted by ADH exceeds the annual maintenance recpmmended by the NRC. This includes actions specifically designed for the ANO EWS. The testing records are kept in the ADH NP&RP office.

2.10 Responsibility It is the responsibility of ADH NP&RP to perform or supervise maintenance on the entire EWS network (except for the NOAA radio system and local broadcast stations and radios) and to ensure that it is functioning properly. In general, the electronic component control and radio parts are maintained and repaired by ADH. The items requiring the use of a crane or other specialized equipment are maintained and repaired by contractors. The NOAA radio system is tested by the NWS and monitored by ADH NP&RP and by ANO EP personnel (see Section 2.9 and Section 4.3). A local contractor is responsible for maintenance and repair ofthe NOAA weather radio transmitters.

2.11 Training It is the responsibilities of ADH NP&RP to identify organizations with a need for training and provide training and refresher training on a continuing basis. Refresher training shall be made available to emergency personnel at least annually. At a minimum, these emergency workers will have attended the FEMA REP Planning course. The training required for emergency personnel is discussed in Section 7.

2.12 Quality Assurance The ADH maintains several procedures pertaining to the ANS, including procedures on activation, testing, maintenance, repair and reportability. These procedures are included in Appendices Band C. The records regarding the SWS testing and maintenance are ,maintained by ADH and routinely reviewed by ANO.

Copies of the quarterly reports detailing siren system performance are also provided to ANO. Additionally, the ANO is provided the results of activation verification on a monthly basis.

In addition to these procedures above, the EWS is tested on a weekly basis as discussed in Section 2.9.

Hence, the essential elements of the SWS activation are "practiced" weekly. These extensive exercises help to reduce errors during the operation.

The NOAA weather radio test data is not reported as the weekly test is not guaranteed due to the weather conditions. The records of the NOAA radio system performance are not maintained as it is outside ADH's area of responsibility. However, the ADH notifies the NWS of service interruptions monitored (see Section 4.3) and provides assistance in resolving problems. As noted in Section 2.10, a local contractor is responsible for the maintenance and repair of the NOAA weather radio transmitters.

Arkansas Nuclear One 11 ANS Design Report - Rev. 4

3 Description/Performance 3.1 Physical requirements 3.1.1 System Components As discussed in Section 2.1.4, the siren system is comprised of 50 omni-directional electronic sirens. Figure 8 maps the sirens in the EPZ. The sirens are labeled with their identification number and are symbolized by siren model type. Table 3 lists each of the 50 sirens in the ANO EPZ. The table includes the siren identification number, the latitude and longitude ofthe siren, the siren model, the mounted height of the siren and location description.

WPS2807 and WPS2907 sirens can produce approximately 115.ldBC and 115.5dBC, r~spectively, at 100 feet along their centerline with operating frequencies between 500 and 630 Hz, based on the results of the near-field tests discussed in Section 4.1.

A WPS2807 or WPS2907 siren consists of a power supply {batteries), a control board, seven 400-watt audio drivers, seven audio amplifiers, and a radio transceiver for reception of control signals. The batteries, control board, amplifiers and transceiver <!re located in a sealed and locked enclosure. The siren drivers are pole mounted at approximately 50 feet above the ground. All sirens have multiple ground points and surge protection, incl~ding antenna feed lines.

Over the past 30 years, the ADH has issued numerous NOAA TARs of various models and manufacturers.

Nevertheless, all the radio receivers must respond to the 1050 Hz alert tone and feature an audible warning. The ADH also provides models with a visual signal to alert deaf or hearing-impaired individuals.

The NOAA TAR have a battery backup feature which allows the user to install batteries, such that the radio will work during a power outage. New batteries are issued annually to each of the NOAA TAR holders as discussed in Section 2.1.4 and Section 2.7.1.

3.1.2 User Interfaces The WPS2800 and WPS2900 series sirens*can be remotely activated by using an encoder and siren radio transmitter. The logical connection between the siren control components is further discussed in Section 3.1.3. The NOAA TARs are activated by a primary 300-watt transmitter. A secondary 300-watt backup transmitter would be used following a failure of the primary transmitter. Both primary and secondary backup transmitter sites are located on Mount Nebo, which is approximately 6 miles SSW of the ANO site.

Entergy has provided backup generator capability for the transmitter site. Hot standby switching for auto-start of the backup transmitter and a backup generator with auto-start capability is also available and tested frequently.

3.1.3 Functional Block Diagrams Figure 9 shows the logical connection of the components of the siren control system. As shown in the diagram, there are three different locations that can communicate with the primary and backup siren radio transmitters which in turn communicate with the siren sites via a utility microwave link or a leased line which is a circuit rented from a public carrier-AT&T in this case. The ADH Mobile Command Post can communicate with the primary and backup radio transmitters via radio line. The primary/backup siren radio transmitters activate sirens by UHF-FM radio signal. Section 2.3 further discusses the physical connections of the system and the interoperability.

Arkansas Nuclear One 12 ANS Design Report- Rev. 4

3.2 Administrative Components 3.2.1 Organizational Responsibilities The ADH ECC is the official 24-hours-per-day point of contact between the State and ANO for the initial notification of a radiological incident. In the event of an emergency, the operator of ANO is responsible for notifying the ADH ECC, Arkansas Department of Emergency Management (ADEM), and the warning points in Conway, Johnson, Logan, Pope and Yell Counties. The final decisions to alert and notify the public by the EWS are the decisions of governmental officials.

The responsibilities of ADH NP&RP include off-site emergency planning and response to emergencies involving ANO; the development and update of emergency response plans; the maintenance and operation of the EWS and the communication system used to notify state agencies and local governments of emergencies; the maintenance of eguipment and supplies necessary to support emergency operations for state and local agencies; the development and training of emergency personnel who would respond to an emergency; and the distribution of emergency instructions to the public.

The primary means of notification and communication between ANO and the state and local governments will be via the ANO Dedicated Emergency Facsimile/Voice System (DEF/VS). In the event that the ANO DEF/VS is not operating properly, the operator of ANO will notify the ADH ECC directly by commercial telefax or by commercial telephone; and ADH, in tum, will notify the county warning points and ADEM using various means, such as the DEF/VS, ENS radio, ADEM radio, and/or commercial telephone. If both communication procedures outlined above fail, the operator of ANO will use commercial telephone to notify the ADEM which will, in turn, notify the ADH ECC. The communications link between the state and federal emergency response organizations is via the commercial telephone system, with the National Warning System (NAWAS) serving as the backup system.

3.2.2 Management As noted in Section 2.6, the activation consoles are key locked and kept at secure locations to prevent the inadvertent systemwide activation, and the siren control system is configured in such a way that a systemwide inadvertent activation is very unlikely to occur. There are limited failure paths which will result in an inadvertent activation, such as included high voltage that shorts a control cable. In the event of an inadvertent siren activation, the ADH sends the notification to _area broadcast stations and to appropriate 911 Centers to assure the public there is no emergency involving ANO. In an emergency involving ANO, this responsibility falls on which of the State's centers have "Command and Control". For other situations, it depends on the time of day. After hours notification falls to the ADH ECC if the radiological emergency response team is not activated.

If siren(s) are inadvertently sounded, the cancellation tones are not automatically sent to the siren(s) due to the time factor. In most cases, reports of spurious siren sounding come in the form of calls from the public to the appropriate 911 Center which then notifies the ADH. It is noted that the sirens in Arkansas are hard coded to sound for 3 minutes before shutting off. As such, the siren has most likely "timed out" when the incident is reported. When the ADH receives a report of inadvertent siren sounding, the first step is to gather the information of the inadvertent sounding reported, including the number of calls receive*d, the generation location of the sound reported, the caller names and call back numbers. The ADH then will verify the existence of a siren in the reported activation area. If a siren is identified in the reported area, a repair technician will visit the site to ascertain the status of the siren, and attempt to determine if Arkansas Nuclear One 13 ANS Design Report- Rev. 4

there was an actual activation or if there were other noise sources that imitate a siren. Most reported siren sounds are in fact from other sources, for instance, emergency vehicle sirens.

3.3 Operational Components 3.3.1 Activation As discussed previously in Section 2.3, the SWS is activated by ADH through the primary or secondary activation points. As shown in Table 4, the primary activation point for the SWS is located at the ADH ECC office that is manned 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> per day to accommodate day or night activation. One secondary activation point for the SWS is located in the SEOF which is co-located at the ANO site; another secondary activation point is located in the ADH NP&RP office. All the activation points have the ability to activate the entire SWS, but for events where ANO is not involved, such as severe weather, activation is usually conducted by ADH ECC or by ADH NP&RP.

The NWS is notified by the ADH staff in advance ofthe sirens being activated. The NWS in turn utilizes the primary/backup weather radio transmitter to transmit the NOAA tone which automatically turns the receivers on. Both primary and secondary backup transmitter sites are located on Mount Nebo, which is approximately 6 miles SSW of the ANO site.

3.3.2 Timing According to ADH, when an emergency is declared at ANO, the ANO operator must notify state officials within 15 minutes. State officials can then notify the public of an emergency within 15 minutes by use of the EWS. The EWS activation will be conducted with a sense of urgency without undue delay. The sirens activate within seconds of the signal being sent from the controller. The NOAA tone is activated in conjunction with the siren activation. The backup method - route alerting - is capable of alerting and notifying the 10-mile, EPZ population within 45 minutes (see Section 4.3 and Section 5).

There are no exception areas (rural, low popul!'ltion areas) in the EPZ that would require additional time to be alerted and notified.

3.3.3 Geo-Targeting Individual sirens within the siren system can be activated to pinpoint a geographic location for alerts; however, this is not part of the standard alert procedure. NOAA radios cannot be individually sounded.

4 Verification 4.1 Coverage ANO recently conducted an extensive acoustical study of the.siren system, including detailed acoustical modeling and field testing of siren sound levels. The results of this study are summarized below.

Section 2.0 of FEMA Technical Bulletin (Version 2.0) "Outdoor Warning Systems" dated January 12, 2006 provides an extensive discussion of sound propagation. Below are some key points on sound taken from this guidance document:

  • Sound travels in waves
  • Sound decreases in loudness at greater distances from its source
  • Refraction: Sound waves can refract or bend with differences in temperature and wind speed. The specific heat of the gro1,1nd is higher than that of the air above it. Thus, during the day, the ground Arkansas Nuclear One 14 ANS Design Report - Rev. 4

is warm and temperature decreases as you move higher above the ground. This difference in temperature impacts the speed of sound waves as shown in Figure 10. The resulting shadow zone causes the audible level of the siren to be lower at the ground. The opposite happens in the evening when the ground releases its heat to the atmosphere resulting in higher temperatures the farther you get from the ground, as shown in Figure 11. This explains why sounds from the same source are louder at night than they are in the daytime.

  • Ground Absorption: Soft ground such as grass covered soil or dense foliage can cause significant absorption of sound, thereby reducing perceived loudness of sound. Hard surfaces such as concrete, ice, or water can cause sound waves to reflect upwards and be perceived as louder as shown in Figure 12.
  • Wind: Wind speed either adds or subtracts to the velocity of sound waves depending on whether the sound is moving upwind or downwind, resulting in refraction of sound waves. Wind speed also increases with height above the ground causing further refraction. The additive refraction of these two phenomena can result in a significant acoustical shadow zone in the upwind direction as shown in Figure 13.
  • Diffraction: Sound waves can also be diffracted (bent upward or downward) by objects (buildings, trees) in the path between the source and the listener resulting in lower perceived loudness.

Figure 14 shows multiple potential factors that could Impact the sound heard by a receiver from a source.

One way to deal with the complications that can impact the audible level of outdoor sirens is to use a sophisticated acoustic model that accounts for terrain and atmospheric conditions. Such a model, Sound PLAN, was used to predict the siren coverage in the ANO EPZ. The SoundPLAN software is a state-of-the-art acoustic model written by SoundPLAN, LLC (a German company) and distributed in the U.S. by Navcon Engineering Network in California. This software has been used to model the siren coverage for more than a dozen U.S. nuclear plants, including the Diablo Canyon Power Plant in California, which has one of the most difficult terrains of any U.S. plant in terms of siren coverage.

Modeling Inputs and Assumptions The following inputs/assumptions were used in the acoustic modeling:

  • Digital elevation data was provided by the United States Geological Survey (USGS) National Map Viewer10
  • A standard DEM 11 was downloaded with a resolution of 1/3 arc-second, which is an approximate grid spacing of 10 meters. This is more than adequate to model the terrain in the EPZ.
  • Ground surface absorption was explicitly modeled. The software default value for ground surface absorption is 1 for all soft grounds such as fields or other grassy areas, and forests. The ground surface value was changed to O for major bodies of water to accurately depict the reflective properties of the hard surface.
  • The siren locations and model type documented in Table 3 were Input to the model.

10 http /tV!e'Wer nattooaknap.aov/bastc/

11 http //nat1onalmap goy/3DEP/3deo prodserv.html Arkansas Nuclear One 15 ANS Design Report-, Rev. 4

  • Acoustical tests were conducted on June 23 and June 24, 2020 to measure the sound levels output by sirens. The tests included seven near-fieid tests in accordance with ANSI S12.14, wherein a sound meter was aimed at the center of the siren horns from a buckettruck parallel with the siren horns at a distance of 100 feet. In addition to the near-field tests, far-field tests were conducted with siren meters on the ground at varying distances form the siren pole. Five WPS2907 sirens and two WPS2807 sirens were tested. Figure 15 presents the locations of the near-field and far-field test locations. The tests were conducted by acoustical expert - Dr. Bruce lkelheimer - using Larson Davis Model 831 sound level meters - and were supervised by the ADH and Entergy personnel. Weather conditions during the tests were good, with low winds and no precipitation.

The test results were analyzed and reported by Dr. Bruce lkelheimer (see Appendix E). The results of the near-field tests are summarized in Table 6. Based on the overall average results, sound levels of 115.ldBC and 115.SdBC are adopted for WPS2807 and WPS2907 siren models, respectively. The ANSI S12.14 test sheets for the seven near-field tests which provide additional details on the test are included in Appendix E.

  • The acoustical standard International Organization for Standardization (ISO) 9613-2 12 was used.

ISO-9613-2 is a widely used standard for sound modeling and is accurate at predicting total coverage areas at extended distances from the source.

  • The average daytime temperature, pressure and humidity were u~ed to account for atmospheric conditions. These data were estimated as the 3-month average of June, July'and August of 2019.

The historical weather data was obtained from the Weather Underground website 13

  • The location used was Hot Springs, which is located approximately 55 miles southeast of ANO. The atmospheric conditions used were:

o Average temperature= 79.8°F (265°C) o Average relative humidity= 77.2%

o Average air pressure= 29.4 inHg (995.2mbar)

As discussed in Section 3.1.2, the NOAA TARs are activated by the primary/secondary weather radio transmitter located in Mount Nebo. As-per the latest county radiological emergency response plans, the NOAA weather radio primary/backup transmitter at Mount Nebo covers the following counties .

- Conway, Johnson, Perry, Pope and Yell. This has provided adequate coverage to the radio receivers within the 10-mile EPZ.

4.2 Population/Demographics Based on the population density analysis using the 2020 population projections (see Section 2.1.1), the overall population density in the ANO EPZ is low. Only parts of Russellville have a population density exceeding 2,000 persons per square mile, as shown in -Figure 6. As discussed in Section 2.1.1, federal guidance recommends siren coverage of at" least 70dBC in areas where the population density exceeds 2,000 people per square mile, and 60dBC in all other areas. Also, as discussed in Section 1, the ANS should provide direct coverage of essentially 100 percent ofthe population within 5 miles of the NPP site.

Figure 7 maps the predicted siren coverage for the ANO EPZ output by the Sound PLAN software based on the inputs and assumptions discussed above. The map shows the 60dB and 70dB contours, as well as the high population density areas discussed In Section 2.1.1.

12 https /fw.Nw lSO org/standard/20649,html 13 https*l!y.,ww.wunderground com/

Arkansas Nuclear One 16 - ANS Design Report - Rev. 4

As shown in the map, the G0dBC coverage covers the majority of the 10-mile EPZ. All the high population density areas flagged red in Figure 7 have adequate 70dB coverage. As discussed in Section 2.1.4, the ADH maintains a database of addresses that are outside the G0dBC siren coverage area. Letters are sent to those addresses annually to ensure NOAA TARs are available to those addresses to ensure completed coverage of the EPZ by the EWS.

4.3 Metrics Sound levels during siren activation were measured in many locations as discussed in Section 4.1 and shown in Figure 15. These sound level measurements were used to calibrate the acoustical model and predict G0dBC and 70dBC of the siren system in the EPZ.

As discussed in Section 4.1, the NOAA TAR receivers within the 10-mile EPZ are fully covered by the NOAA weather radio primary/backup transmitter at Mount Nebo. According to the ADH, the NOAA radio signal strength has not been reported as an issue by any NOAA TAR holders. As discussed in Section 2.5, the NOAA radio program is operated by the NWS and administrated by the ADH NP&RP staff. The ADH retains several radio receivers in the ADH NP&RP office for constant monitoring. The NOAA radio system is also monitored by ANO EP personnel.

As per federal guidance, the primary ANS means should be capable of alerting and notifying the EPZ population within 15 minutes, and the backup means should be capable of alerting and notifying the EPZ population within 45 minutes. According to the ADH, the time for the EWS (primary method) activation and route alerting (backup method) process has been evalua~ed by FEMA several times during the bi-annual evaluated exercises, and the timeline has been acceptable. The time for actual physical activation of the ENS by pushing the button is a matter of seconds.

5 Availability/Reliability As discussed in Section 2.12, the ADH maintains several procedures to provide detailed information of performing testing, maintenance, and record keeping for system maintenance/repair activities. The system testing, maintenance and siren malfunctions have been discussed in detail in Section 2.7 and in Section 2.9. Appendices B and C details the Quality Assurance procedures that are in place which have resulted in a 100% reliability score for the ANS in *2019 and reliability scores in excess of 99% for the past decade (see Section 2.8). The inadvertent activation of the SWS and the actions taken thereafter are discussed in Section 3.2.2.

As discussed in Section 4.3, the ability to meet the minimum activation time of 15 minutes has been successfully*demonstrated in the bi-annual evaluated exercises, including the latest one on July 17, 2018.

The evaluation details are reported in the After-Action Report/Improvement Plan published by FEMA.

6 Security and Privacy The applications used to activate the SWS can only be accessed by authorized personnel with unique user IDs and passwords. Section 2.6 provides additional detail on the physical and cyber security ofthe ANS.

Arkansas Nuclear One 17 ANS Design Report- Rev. 4

7 Training and Public Outreach The ADH NP&RP is responsible for arranging the initial and continuing training for all staff members who are assigned to the ANO radiological emergency planning effort. The elements of training required for emergency personnel include the review of emergency classification levels, protective action advisories, methods of notification, ,notification procedures, procedures for dissemination of public information during a nuclear generating plant emergency, emergency notification forms, emergency staff positions and responsibilities, facility set-up, layout and equipment.

The public is instructed by the EIB to tune to NOAA TARs and local radio stations for emergency instructions when the sirens are activated. The local radio stations have the capability to broadcast emergency messages on a 24-hour basis to the general public. The EIB is available in both English and Spanish and can be accessed through the ADH website 14

  • The booklet also includes contact information for emergency planning agencies should additional information on alert and notification or other emergency planning issues be needed.

In addition to the EIB, emergency information regarding notification procedures and those steps that should be taken in an emergency is included in the official telephone directory distributed within the 10-mile EPZ and is updated annually. Education and informational programs are offered annually to area civic and service organizations, including public and private schools. These programs include information on the EWS, evacuation routes, and designated care \

centers. An annual media workshop is conducted by ADH NP&RP to provide pre-incident information to the representatives of the Arkansas news media. The workshop provides information on notification, evacuation and planning efforts. The ADH NP&RP will also provide the news media with periodic releases containing information on any changes in notification, evacuation or planning efforts.

14 httos 11www healthy.arkansas.goy/programs-serv1ces1tomcs/nuclear-olan1na-and--resoonse Arkansas Nuclear One 18 ANS Design Report- Rev. 4

Table 1. EPZ Population by Decenntal Census 2000 Population 2010 Population 2000 2010 Zone Density (people Density (people Population Population per sq. mi) per sq. mi)

G 1,278 1,327 58 60 Total for Zones intersecting 2- 1,278 1,327 58 60 mile Radius:

H 12,861 *'14,653 '*' 899 1,024*

K 1,798 2,185 80 97 N 4'92 579 53 62 -

0 146 141 72 70 R 502 431 27 24 u 1,277 1,387 80 87 Total for Zones intersecting *5. 18I 354. -~ 20)03 '1

, 176 198

  • , mile Radius:

I 10,618 12,262 541 625 J 4,426 5,445, 232 285 L 4,074 4,484 175 192 M 763 936 '21 25 p 1,931 2,022 80 84 Q 398 464 , 12 14 s 1,739 2,133 47 58 T 4,228 4,422 1,*371 1,434 EPZTOTAL: 46,531 52,871 155 176 Arkansas Nuclear One 19 ANS Design ReJ;>ort - Rev. 4

Table 2. Popu/atlan Density Computed USJfl/J Different Geograph,c Areas Population 2010 Geographic Area Arca {sq. mi) Density (people Population per sq. mi)

~

Radial Distance 2-n:iile-  ; 1,003 12.S-7 -- 80 5-mlle 11,553 78.54 147 10-mlle 5;1.,869 314.16 168 Full EPZ 52,871 300.97 176

; County  ; ,,

Johnso*n 25,540 _ 659.80 39 Logan 22,361 708.13 32 Pope 61,754 812.55 76 ' -

Yell 22,185 929.98 24

-~ '*. -*

.. Munici'pality* - '

Dardanelle 4,747 3.64 1,303 Dover 1,379 2.83 488 Knoxville ,733 3'.19 230' London

  • 1,040 3.18 327 Pottsvlile 2,783 13.19 - _

Table 3. Siren Detalls for the ANO EPZ Mounting Description Siren Siren ID U Location Latitude Longitude Zone County Pole from ADH Model

-* - - .. .... .... ______ . ,_ .... *----*--*--*-..*-*----- ..-. _..____ . _____ **-****-.....___ -~-~ig_~t.Jr~) ..

1Z1 1001 Whelen 29 WPS2907 Corner of Front St. and Market St. 35.21924 -93.15294 T Yell 15.2 Intersection of Hwy 28 and Arcadia Rd.

1Z2 1002 Whelen 28 WPS2807 Approx. 100 yds down Arcadia Rd.

35.18017 -93.18961 s Yell 15.2 1.9 miles south of Hwy 7 and Hwy 27 1Z3 1003 Whelen 28 WPS2807 intersection on south side of Hwy 27.

35.21265 -93.19426 s Yell 15.2 3.7 miles south of Hwy 27 intersection on 1Z4 1004 Whelen 28 WPS2807 Hwy 27 north side of Hwy 35.19644 -93.21616 s Yell 15.2 Just off Hwy 27 at the intersection of Alpha lZS 1005 Whelen 29 WPS2907 Rd. (CR 40 and Hwy 27) 35.18037 -93.25319 s Yell 15.2 South side of Hwy 155, 2.6 miles west of 1Z6 1006 Whelen 29 WPS2907 intersection with Hwy 22.

35.22657 -93.21175 s Yell 15.2 Turn North off of Hwy 155 on Bethel Rd.

(CR 64), then turn West on Haney Hollow 1Z7 1007 Whelen 29 WPS2907 35.24049 -93.22641 u- Yell 15.2 Rd. (CR 913). Siren is at second driveway on right.

Mt. Nebo State Park at the intersection of 1Z8 1008 Whelen 28 WPS2807 Hwy :1,55 and Kentucky Rd.

35.22163 -93.25236 s Yell 15.2 At Bay Ridge Country Club, take Bay Ridge 1Z9 1009 Whelen 28 WPS2807 DR 1.2 miles from Hwy 22.

35.25855 -93.21677 u Yell 15.2 Located 2.8 miles from the intersection of 1Z10 - 1010 Whelen 28 WPS2807 Hwy 7 and Hwy 22 on the north side of 35.24641 -93.19587 u Yell 15.2 Hwy 22.

Located at 2nd St. and Hwy 22 in south 1Z11 1011 Whelen 29 WPS2907 35.236 -93.17313 T Yell 15.2 Dardanelle right of 2nd St.

South side of Lower Danville Rd., 320 feet 1Z12 1012 Whelen 29 WPS2907 35.20859 -93.15462 T Yell 15.2 south of the intersection with S 5th St.

North Side of East 2nd St. 150 feet west of 2Z1 2001 Whelen 28 WPS2807 35.27698 -93.10901 I Pope 15.2 intersection of East 2nd St. and Verona.

Arkansas Nuclear One 21 ANS Design Report- Rev. 4

Mounting Description Siren Siren ID tt Location Latitude Longitude Zone County Pole from ADH Model Height (m)

At intersection of Elmira and Jimmy Lile 2l.l. 2002 Whelen 28 WPS2807 Rd., siren is 0.1 miles south on Jimmy Lile 35.25449 -93.10342 I Pope 15.2 Rd.

South of Hwy 7T 0.1 miles at corner of 2Z3 2003 Whelen 28 WPS2807 35.24936 -93.12127 I Pope 15.2 Bernice Cemetery.

Corner of Ea~ 16th and South Detroit on 2Z4 2004 Whelen 29 WPS2907 35.26415 -93.12967 I Pope 15.2 Oakland Heights School Grounds.

North side of Hwy 247 near New Hope 1.6 2Z6 2006 Whelen 29 WPS2907 miles east of intersection with Hwy 7 35.22414 -93.11605 I Pope 15.2 South.

East side of Sheppa Rd. St. 0.3 miles north 2Z7 2007 Whelen 28 WPS2807 35.25344 -93.16099 H Pope 15.2 of intersection with Old Post Rd.

On Sequoyah Elementary School Grounds 2Z8 2008 Whelen 29 WPS2907 35.26758 -93.14869 H Pope 15.2 off 12th St. in Russellville.

In parking lot off Hwy 64 West1/4 block from 2Z9 2009 Whelen 29 WPS2907 35.28552 -93.15919 H Pope 15.2 intersection with South Cumberland.

North Side of Hwy 326 - 0.8 miles west of 2Z10 2010 Whelen 28 WPS2807 35.27955 -93.18061 H Pope 15.2 intersection with Skyline Drive.

At entrance to Lake Dardanelle State park 2Z11 2011 Whelen 29 WPS2907 on west side of Hwy 326, 2.3 miles 35.29323 -93.2017 H Pope 15.2 southwest of intersection with U.S. Hwy 64.

West side of Hwy 326, 0.9 miles southeast 2Z12 2012 Whelen 28 WPS2807 35.30352 -93.18168 H Pope 15.2 of intersection with U.S. Hwy 64.

On Reasoner Ave. just off Hwy 7 North, 0.8 2Z13 2013 Whelen 29 WPS2907 miles North of intersection of Hwy 124 and 35.30037 -93.13682 I Pope 15.2 Hwy 7.

Take Shiloh Rd. East off Hwy 7, 0.4 miles, 2Z14 2014 Whelen 29 WPS2907 turn south on paved road and proceed 0.3 35.31757 , -93.12815 J Pope 15.2

' miles; siren is on east side of road.

Arkansas Nuclear One 22 ANS Design Report- Rev. 4

Mounting Description Siren Siren ID# Location Latitude Longitude Zone County Pole from ADH Model Height (m) 0.1 miles north of Baker's Creek Bridge on 2Z15 2015 Whelen 29 WPS2907 35.34038 -93.13262 L Pope 15.2 west side of Hwy 7 at Country Club.

Just north of intersection of Hwy 7 and Hwy 2Z16 2016 Whelen 29 WPS2907 35.40276 -93.11462 L Pope 15.2 27 in Dover.

North side of Morgan Rd. 0.7 miles east of 2Z17 2017 Whelen 29 WPS2907 35.36554 -93.10677 L Pope 15.2 intersection with Hwy 27.

East side of Roy Taylor Rd. 0.7 miles South 2Z18 2018 Whelen 29 WPS2907 35.34533 -93.08753 J Pope 15.2 of intersection with Morgan Rd.

East side of Hwy 124, 0.9 miles north of 2Z20 2020 Whelen 28 WPS2807 35.32504 -93.09692 J Pope 15.2 Shiloh Creek Bridge.

Proceed 0.6 miles east on Crow Mountain Rd. 1.8 miles south of intersection with 2Z21 2021 Whelen 29 WPS2907 35.30396 -93.08957 J Pope 15.2 Hwy 124, turn on Yukon Rd. for 0.3 miles; siren is on west side of road.

Proceed 2.3 miles east on Crow mountain Rd. from intersection with Hwy 124, turn north on Sherman Acres Rd. and proceed 2Z22 2022 Whelen 29 WPS2907 35.30726 -93.06265 J Pope 15.2 0.2 miles and turn east on Gravel Rd. and go 0.2 miles. Siren is on south side of Gravel Rd.

North side of Hwy 124 in curve 0.4 miles 2Z23 2023 Whelen 29 WPS2907 35.30136 -93.11459 J Pope 15.2 north of 1-40 overpass.

South side of Hwy 64 East at Hagan's 2Z24 2024 Whelen 29 WPS2907 Datsun 0.8 miles east of 1-40 interchange or 35.27466 -93.08059 I Pope 15.2 intersection of Hwy 64 and Hwy 331.

At Dare's Car Wash corner of North Boston 2Z25 2025 Whelen 29 WPS2907 35.2817 -93.13209 I Pope 15.2 and East "E" St. in Russellville North side of Hwy 64, 0.5 mile east of 3Z1 3001 Whelen 29 WPS2907 35.32245 -93.20183 G Pope 15.2

~ intersection with Hwy 333.

Arkansas Nuclear One 23 ANS Design Report- Rev. 4

Mounting Description Siren Siren ID tt Location Latitude Longitude Zone County Pole from ADH Model

.. Height (m)

North side of Hwy 333 in curve 1 mile from 3U 3002 Whelen 29 WPS2907 35.31349 -93.21891 G Pope 15.2 intersection with Hwy 64.

South of Arkansas Nuclear One, 1 mile from 323 3003 Whelen 29 WPS2907 35.30193 -93.23453 G Pope 15.2 intersection of Bunker Hill Rd.

East side of Flatwood Ln 0.5 mile from 3Z4 3004 Whelen 29 WPS2907 35.31901 -93.24541 G Pope 15.2 intersection of Hwy 333.

On south side of Hwy 64 in London 0.2 mile 3ZS 3005 Whelen 29 WPS2907 35.33134 -93.2582 G Pope 15.2 west of Hwy 333 intersection.

On south side of U.S. Hwy 64, 1.0 mile west 3Z6 3006 Whelen 29 WPS2907 of intersection with Robertson ~n. and Hwy 35.32721 -93.2284 G Pope 15.2 333.

East side of Mill Creek Rd. 1.3 miles north 3Z7 3007 Whelen 28 WPS2807 35.33982 -93.21062 K Pope 15.2 of intersection with Hwy 64.

North side of Mill Creek Rd. 2.9 miles from 3Z8 3008 Whelen 28 WPS2807 35.35714 -93.21851 K Pope 15.2 intersection of Hwy 64.

North side of Pleasant View Rd. 1.5 miles 329 3_009 Whelen 29 WPS2907 35.33402 -93.18326 K Pope 15.2 east of intersection with Mill Creek Rd.

North side of Pleasant View Rd. 1.0 miles 3Z10 3010 Whelen 28 WPS2807 35.32197 -93.15181 K Pope 15.2 west of intersection with Hwy 7.

In Piney Community 4 miles west of London 4Zl 4001 Whelen 28 WPS2807 35.34428 -93.32532 p Johnson 15.2 on U.S. Hwy 64.

Knoxville City Limits in front of Knoxville 4Z2 4002 Whelen 28 WPS2807 35.38404 -93.36616 p Johnson 15.2 Elementary School.

South side of Hwy 22 at Yell-Logan County SZl 5001 Whelen 28 WPS2807 Line, 0.1 mile east of intersection of Hwy 22 35.28161 -93.29453 R Logan 15.2 and Hwy 393.

Right off Hwy 22 on Hwy 393, 1.5 miles SU 5002 Whelen 28 WPS2807 35.29633 -93.28739 R Logan 15.2 toward Delaware Park.

Four miles west of Delaware on Hwy 22 on SZ3 5003 Whelen 28 WPS2807 35.28272 -93.37439 Q Logan 15.2 the right side of the road.

Arkansas Nuclear One 24 ANS Design Report - Rev. 4

Table 4. SWS Activation Points for ANO Site ACTIVATION POINT PHYSICAL ADDRESS Primary Point -ADH 4815 West. Markham, ECC Little Rock, AR 72205 Secondary Backup Point 1448 AR-333,

-SEOF Russellville, AR 72802 Secondary Backup Point 305 S Knoxville Ave,

-ADH NP&RP Russellville, AR 72801 Table 5. S1ren System Reliability Quarter - Year Total Siren Tests Successful Siren Tests  % Successful Test Q4- 2019 147 147 100.00%

Q3- 2019 147 147 100.00%

Q2- 2019 147 147 100.00%

Ql- 2019 147 147 100.00%

Table 6 Summary of Near-Fteld Acoustical Test Results WPS2807 l (,'

115.1

. Overall* Average .*115.1 2Z14 113.1 116.6 1Z11 114.3 118.5 WPS2907

  • 3Z4 116.9 t-----t---------t--------1 120.3 3ZS 116.1 119.2 2Z13 117.2 120.3
  • * *
  • Overall Average.*. 115.5. *. * * *
  • 119:0
  • According to Entergy, the siren head of Siren 1Z9 was damaged before the near-field test was performed It was repaired after the acoustical test Arkansas Nuclear One 25 ANS Design Report - Rev. 4

Pope H<<tor Co1mt.v Arkansas RNer Shoal Cteelc lo Co11 Legend ti' ANO Population Center Urban Area GJ Zone

~ Zones In Johnson County G Zones In Logan County tf} Zones In Pope County GJ i:;?

Zone in Pope & Yell Counties Zones in Yell County Do1te: 1/17/2020 /

JV I'"::; 2, 5, 10 Mile Rings Cc,:,yri11ht* ESRl Oo1U ;md Map~ 2018, -w.~nsus:cO¥ KU>tn1meerm1, Enter¥Y /

Figure 1. Site location Arka nsas Nuclear One 26 ANS Design Report- Rev. 4

N NNW NNE

[ill]

~ I1,0411 0

NW NE I1,938 I I2,358 I I

WNW ENE 11,155 I I3,312 I

,- - ....I w E

~* o o I

I6,854 I I i WSW ESE O§I]' 122 ,0591 I

SW ' ' SE

[ill] !4,474 I

- _, 10 M iles t o EPZ Boundary SSW --

I 0 SSE

[ill] s I4,7561 N I1,206 I Resident Population Mi les Subtotal by Ring Cumulative Total 0 -1 209 209 1 -2 794 1,003 2- 3 2,199 3,202 3- 4 3,366 6,568 w E 4-5 5,013 11,581 5-6 10,494 22,075 6-7 12,955 35,030 7-8 7,307 42,337 8-9 5,274 47,611 9 - 10 5,258 52,869 10 - EPZ 2 52,871 Total : 52,871 Figure 2. Permanent Resident Population by Sector for the ANO EPZ Arkansas Nuclear One 27 ANS Design Report- Rev. 4

wA ,

'(Cl.irksvll/e Zone: K Zone: L Z1 2 7 Pope County an 5Z3 nty Zone: Q

    • z.a---.-----*- --,-i...,

1Z6 ANO Siren Yell 1Z4 1Z3 GJ

(;SJ Zone Shadow Rqlon County Zone: S lZS c] County Boundary

(' ::: 10 Mile Rin1 1Z2 Cenlus Blocks

- >* 2,000 People/ SqMlle Figure 3. Census Blocks with Population Density Exceeding 2,000 People per Square Mile Arkansas Nuclear One 28 ANS Design Report- Rev. 4

a11 5Z3 nty Zone:Q 1Z6

. *zs--...---**--l-Z -3.a. ""\..I

~ Shadow Resion County Zone: 5 1Z5 c:'.J I"::

County Boundary 10 Mlle Ring Census Blocks

- >= 2,000 People/ SqMlle Figure 4. Census Blocks with Population Density Exceeding 2,000 People per Square Mile {Filter 1 Applied)

Arka nsas Nuclear One 29 ANS Design Report - Rev. 4

Flagged blocks from Step 1 that have Creation of 1 square mile buffer a density higher than 2,000 ppl/sqmlle arou nd each block centroid 2Z14

  • Block 2:

z J 2020 Population - 172

- Al'@a -0.039 sqm,le

  • Density - 4,208 ppl/sqm1le Block 3:

2020 Population - 102 Area

  • 0.023 sqmile Density - 4,244 ppl/sqmile 0 0.25 0.5 Miles 0.25 0.5 Mlle locks by each 1 square mile buffer d census data within 1 square mile Lecend ANO e S.ren 0 Mock Centroid

,Q _

EPZ lDMllelllflc 1U IZ5

  • Cemus Blocb

~-----

0 1l2 i);ate:7/9120'20 People/SquaN MMe

<2,000 0 0.25 0.5 Mile 0 2.5 5Miles Copvr*cht £SRI Oau ind M.iip,11011. ~.census.cov wit hin 1 sqm ile l(LOEP1f"lt4m,c.fnterrv - >=2,000 Figure 5. Applying Filter 2 to Eliminate Isolated Neighborhoods from High Population Density Consideration Arkansas Nuclear One 30 ANS Design Report - Rev. 4

wA ,

-yc,11rksville I

Zone: L Z1 2 7 Pope County SZ3 Zone: Q

~ Shadow Rqion County Zone: 5 lZS cJ r:::

County Boundary 10 Mile Rin1 Censu1a*1rs

- >* 2,000 People/ SqMlle Figure 6. Final Census Blocks with Population Density Exceeding 2,000 People per Square Mile after Applying Filters Arkansas Nuclear One 31 ANS Design Report - Rev. 4

Legend

  • WPS2907

<:} Zone Contour Q 70dBC Q 60dBC r:: 10 Mile Ring

~'" 7!,(20"XJ (0Pr'ICl'lt fSIII 0.tt.1 ¥'d "1tPI KlD [l\&l,IW'f'fl"I, [nlfl'f'I' ioa Population Density wrv<<- l""" Crfd,u, ,CUro~ hn. l-lfM. ,., ~ \.

l o / . ~ ~CRfMLNT P NA.Un..h* I UQ.an Mtl l., tM'Chin;a

/Kant iont) h t! ~to, lin (Th;abr,d) NC.CC. It) 0 2.5

- > 2,000 People/Sq, Ml. ()cll'n'il:<etO,bp C'OnU!buto", ar,d ltw ~ UW'f (Gmffl<,fflll'j' Figure 7. Siren Coverage Mop for the ANO EPZ Arka nsas Nuclear One 32 ANS Design Report - Rev. 4

-~*~***.

  • ,~a: *,,~,~ ,

ff-0 ,,

~:,;

~f / ,

, . .~

Legend A

ANO WPS2807

,~
  • WPS2907 GJ Zone 1/~;}> - ;/,

W/4/' //

~ Shadow Region * , I * ~ I ,

'- _, 10 Mile Ring Figure 8. Siren System within the ANO EPZ Arkansas Nuclear One 33 ANS Design Report - Rev. 4

.--;1  !!!!!!II!

Backup Power Primary Siren '.

Radio Transmitter'.

D I Mi Primary Activation Poin

  • -*~..~

\c:;

~

'.t

  • <3:'

24 Hour ADH ECC Little Rock

  • o
  • ~*~..
  • -:)

~

D I Mi Secondary Backup

(<>)

Activation Point ADH NP&RP Siren_ Sites Russe llville I

D I

I I Mt

~.*

§i,'

~.:/,'*

Secondary Backup Activation Point SEOF (ANO Site) ,f,'

~*

~.*, I I

,I I

ADHMobile Command Post Backup Siren Radio Transmitter Figure 9. Control System Layout for the ANO ANS Siren System Arkansas Nuclear One 34 ANS Design Report - Rev. 4

Lt.I a::

~

a::

Lt.I a.

I: SHADOW Lt.I

~ ZONE WARM Figure 10. Sound Transmission in Temperature Lopse Conditions a:

)

!<<a:

....a.

.......::E COOL Figure 11 . Sound Transmission in Temperature Inversion Conditions 3

RECEIVER Figure 12. Outdoor Sound Propagation near the Ground Arkansas Nuclear One 35 ANS Design Report - Rev. 4

WIND DIRECTION SHADOW SOUND PATHS ZONE Figure 13. Upwind Sound Propagation WIND DIRECTION 3

O Figure 14. Downwind Sound Propagation with Terrain and Vegetation Effects Arkansas Nuclear One 36 ANS Design Report - Rev. 4

3Z7 A

Zone: K 3z9 2Z20

,*s-z I~

2Z14 3Z4 3Z2 Zone: J

  • 6-2 2Z21

. 3Z3 2Z23 2Z9 2Z10 A Zone:]

2Zl A

H8 ~ o.: 11*nozo Zone: R . .. St ~ fSlll~U;;indM,l9s2017.KlOfnc1~nnc, fnt~liY Sen,ice L;iyerC *1.  : fw,, HfRE. G:mmn. USGS, lllterm.ip, INCREMENT P.

NAC.ln hn JI n, hri Ch.,JHonc tore) hr, Kor*:.i. hrl fT~<l1ndl. NGC(..

jc! O~Strffl~(Clftlr,t,vt~. *r>d !ht' GIS VWr Commul'lfty Legend

  • A ANO WPS2807 Zone: U 1Z1
  • WPS2907 Siren Test Location
  • Far-Field Test Location Near-Field Test Location 1Z6 GJ Zone c=J County Boundary Zone: s I":: 10 Mile Ring 0 --- 1 2 M Iies Figure 15. Near-Field and Far-Field Test Locations Arkansas Nuclear One 37 ANS Design Report - Rev. 4

REFERENCES

1. American National Standards Institute, Inc. (ANSI) Sl.4-1983, "Specification for Sound Level Meters"
2. ANSI S12.14-1992, "Methods for the Field Measurements of the Sound Output of Audible Publlc Warning Devices Installed at Fixed Locatlo~s Outdoors"
3. ANSI S12.18-1994, "Procedures for Outdoor Measurements of Sound Pressure Level"
4. ANSI Sl.43-1997, "Specifications for Integrating - Averaging Sound Level Meters"
5. ANSI Sl.26-2014, "Method for Calculation of the Absorption of Sound by the Atmosphere"
6. "Arkansas Nuclear One - Upgraded Public Alert and Notification System Design Report Update", May 2016
7. Entergy Operations, Inc., "Supplement to Arkansas Nuclear One - Upgraded Public Alert and Notification System Design Report Update", February 2017
8. Arkansas Department of Health (ADH), "Arkansas Nu dear One Siren Warning System Maintenance Plan",

September 15, 2020

9. Arkansas State Emergency Operations Faclllty (SEOF), "Rapid Warning System Activation Checklist", March 2020
10. Entergy Operations, Inc., "Arkansas Nuclear One Emergency Plan" ~ev. 39, November 2014
11. Arkansas Division of Emergency Management (ADEM), "Arkansas Comprehensive Emergency Management Plan", Revised, September 30, 2019
12. Federal Emergency Management Agency (FEMA) CPG 1-17, "Outdoor Warning Systems Gulde", March 1, 1980
13. FEMA-REP-10, "Guide for the Evaluation of Alert and Not1f1cation Systems for Nuclear Power Plants",

November 1985.

14. FEMA Technical Bulletin (Version 2.0), "Outdoor Warning Systems", January 12, 2006
15. FEMA, "Radiologic:al Emergency Preparedness Program Manual" (FEMA P-1028), December 2019
16. Johnson County Department of Emergency Management, "Johnson c;ounty Radiological Emergency Response Plan", Rev. 5.2, July 2019
17. Logan County Office of Emergency Management, "Logan County Radiological Emergency Response Plan",

Rev. 5.2, July 2019

18. Pope County Office of Emergency Management, "Pope County Radiological Emergency Response Plan",

Rev. 5.2, July 2019

19. Yell County Office of Emergency Management, "Yell County Radiological Emergency Response Plan", Rev.

5.2, July 2019

20. lnterr]at1onal Organization for Standardization (ISO) 9613, "Acoustics - Attenuation of Sound during Propagation Outdoors" 1993
21. KLD Engineering, P.C. (KLD), Technical Report 517, "Arkansas Nuclear One Development of Evacuation TI me Estimates", Rev. 1, December 2012 Arkansas Nuclear One R-1 ANS Design Report - Rev. 4
22. KLD, Technical Report 1167, "Arkansas Nuclear One 2020 Population Update Analysis", September 19, 2020
23. Nuclear Energy Institute (NEI) 99-02 Rev. 7, "Regulatory Assessment Performance Indicator Guideline,

August 31, 2013

24. Nuclear Regulatory Comm1ss1on (NRC), 10 CFR 50.47, "Emergency Plans"
25. NRC, 10 CFR Appendix E to Part 50, "Emergency Planning and Preparedness for Production and Utlllzat1on Facilities" Arkansas Nuclear One R-2 AN~ 1Des1gn Report - Rev. 4

APPENDIX A Compliance with Federal Regulations and Guidance

A. Compliance with Federal Regulations and Guidance Table A-1 is a crosswalk to show compiiance of this design report with federal guidance and regulations.

The criteria in the left column of Table A-1 are taken verbatim from Part V: REP Program Alert and Notification System Guidance, Section C. "ANS Evaluation Report Guidance" of the December 2019 revision of the FEMA REP Program Manual. The references in the right column of Table A-1 are the sections, figures and tables from the design report wherein the criteria from the FEMA REP Program Manual are addressed.

Arkansas Nuclear One A-1 ANS Design Report- Rev. 4

Table A-1. Regulations Crosswalk Section(s) where Criteria Requirement is Met

a. Introduction of the ANS Evaluation Report '.
  • ., +

,_ _\~**

Title Page . '

The Title Page must contain basic infonnatlon about the report such as the name ofthe report and date of the report, name of the nuclear power plant, and applicable revision number. Cover Page Signature Page ,,.

  • ,* *V The Signature Page has signatures of responsible officials attesting to the accuracy, completeness, and concurrence of information included within the ANS evaluation report. Since alert and notification is a key component of offsite planning and is part of the state, local, territorial, or tribal government(s) radiological emergency plan approval under 44 CFR 350, the responsible official from the state, at a minimum, must sign. No ANS design, plan, or revision may be considered by FEMA without the state's concurrence.

Other signatories could include responsible officials or representatives from the utility emergency preparedness, the local or C!JUnty emergency management agency, the state, local, territorial, or tribal

-government(s) emergency management, and the FEMA Region. Signature List Revision History ' '.

The Revision History is a summary of the current version, as well as a history of past revisions. This is typically shown as a table with each past revision number and an associated summary outlining the change in each version. Revision History Table of Contents

-. C The Table of Contents outlines all sections of the report; any ad9itional information should be included as annexes or appendices. Table of Contents

.. ,--- .-(-

Executive Summary ..

The Executive Sumrriary provides a short overview that describes the overall physical and administrative features and functions of the ANS. lfthe ANS evaluation report is an update to a previous version, it should also include a summary ofthe changes from the previous version. Executive Summary Arkansas Nuclear One A-2 ANS Design Report - Rev. 4

b. Body of the ANS Evaluation Report Below are points of review that should be addressed in the body of the ANS evaluation report for each The ANS Plan portion of the type of system used. The ANS evaluation report is divided into two main sections: the ANS plan, where FEMA Evaluation Report will the administrative means and emergency planning aspects of the system is addressed; and the design be completed by FEMA based report, where the physical means and technical components ofthe system are detailed. Depending on on their review of the county the type of system, some headings may be more relevant or need more information than others. and state plans. This report is the Design Report. This appendix will help FEMA review the Design Report ensuring that all necessary criteria have been addressed.

-~~ J .,_*. .. -

Ucenslng obligations (if any)  : ,.....; : 'f

  • *  ! *-~ **

NRC licensing agreements address having a functional ANS and can include specific requirements unique to a particular licensee and/or state, local, territory, and/or tribal government organization. Any obligations or concessions contained within the licensing agreement should be included. Section 1 Requirements Section 2

  • System Coverage Section 2.1 0

Population'- Description or characterization of the population required to be alerted across a Section 2.1.1, Figure 1 through geographical area. Figure 6, Table 1, and Table 2 Section 2.1.2, Figure 1 and 0

Geographical Area - Description of the geographical area intended for each systems' coverage. Table 2 0

Means - Description of the type of system to be used. Section 2.1.3 0

Primary Methods - Description of the methods to be used to alert and notify the population in the geographic area, both described above. Sections 2.1.4 and 3.1, Table 3 0

Backup Methods - Description of the methods to correct or compensate for failures (including total failure) for any segment of the population that did not receive the alert and/or notification. Sections 2.1.5 and 3.3.3

  • Population/Demographics- Description of population groups (e.g., transient populations, those with access/functional needs, non-English speakers, etc.), including any special requirements. Section 2.2
  • Interoperability- Description of how the system interfaces with other systems and how that interface is accomplished, if applicable. Section 2.3, Figure 9, Table 4
  • Operation - Description of all operational requirements. Section 2.4 and Appendix B
  • Management/Administration - Identify and describe the organizations and/or individuals responsible for management and oversight of the system, or the administration of third party agreements with Section 2.5 Arkansas Nuclear One A-3 ANS Design Report- Rev. 4

vendors.

  • Security/Privacy Section 2.6 0

Physical Security- Description of physicaJ security requirements, such as prevention of unauthorized access to systems and the components necessary to operate it .- . Section 2.6.1 0

Logical Security - Description of logical security (cyber-security) requirements, such as prevention of unauthorized or malicious access to the system, or accidental or malicious actions resulting in denial of service and other cyber-security. Section 2.6.2

  • Maintenance/Repair Section 2.7 0

Preventative maintenance - Identify and describe routine and periodic maintenance

,'-),' '

requirements. Section 2.7.1 and Appendix C

° Corrective maintenanc*e ~ 1.de_ntify and describe procedures and resources for correcting areas requiring improvement. - Section 2.7.2 and Appendix b

  • Availability/Reliability- Identify and describe reliability and availability requirements. The NRC requires greater than 94 percent availability, or the elimination of all critical*single-poinf failure modes.

These requirements may include system operation in all weather conditions typical for local climate. Section 2.8 and Table 5

  • Testing - Identify and describe how system performance, availability and reliability is tested and verified on a periodic basis, including how often and the frequency and method of testing, and what-aspects of the system are actually tested. Not all systems ler:,d themselves to full operational testing. In those instances, -passive testing, actual event verification, and inspection may be* considered. Identify how the results of periodic and a_s-needed testing are recorded, preserved, and made available for inspection. Section 2.9 and Appendix C
  • Responsibility O Identify the individual(s) responsible for system maintenance, testing, and repair. Sections 2.9, 2.10 and 3.2.1
  • Training - Identify and describe initial aod ongoing training requirements for all associated personnel. Sections 2.11 and 7 Sections 2.7, 2.8, 2.9, 2.12, 4.3
  • Quality Assurance - Identify and describe a comprehensive, ongoing quality assurance program that and 5, Table 5, Appendices B may include testing; record-keeping, internal and external inspections, and exercises. and C Desaipt/on/Performance Section 3
  • Physical components Section 3.1 0

System com~onents*- Description of the major part~ of each system being employed. Section 3.1.1, Figure 8, Table 3 0

User interfaces - Tbe device, system, or physical ~quipment used to activate or control the ANS Sections 2.3, 3.1.2 and 3.3.1, and its locations. Figure 9, Table 4

° Functional block diagrams-A diagram used to describe each logical and physical connection of Sections 2.3 and 3'.1.3,

-components and systems. Figure 9

    • Administrative components Section 3.2 0

Organizational res~onsibilities - Description of established roles and responsibilities for operation, Sections 2.9, 2.10, a_nd 3.2.1 Arkansas Nuclear One A-4 ANS Design Report - Rev. 4

planning, maintenance, and testing of the ANS under discussion.

0 Management - Description of the controls used to ensure the proper use of ANS and implementation of any corrective actions. Section 3.2.2

  • Operational components Section 3.3 Sections 2.3, 3.1.2 and 3.3.1, 0

Activation.:.. Description of location(s), access, and processes for activating ANS. Figure 9, Table 4 0

nming - D_escription of how long it takes to activate the system-after determining the need to activate ANS-and length of time between initiation*ofthe system and when the alert and notification is received by the public. Sections 3.3.2 and 4.3 0

Geo-Targeting - Description of the system limits in its ability to a select a geographic location. Section 3.3.3 Verification ' ~1£:~&;4;<~-~?:!_'-t,/1~, *~,:*.~~~; l°i' ::::~~.~* ,::

Documents that the system .or approach meets the design report requirements identified above. The need to verify applies to implementation of both new and modified systems and approaches. Information provided here should objectively_demonstrate that the system or approach meets the stated requirements, which can be verified by tests, inspections, demonstrations, analyses, studies, or any other applicable method. Each of the requirem~nts identified should have a description of the corresponding verification process. Section 4

  • Coverage - The coverage (extent or reach) of the ANS can be verified through modeling of the ANS medium (e.g., radio, tone alerts, visual alerts, etc.) using e~istfng accepted* sources and databases, Section 4.1, Figure 10 through empirical data through testing, or other recognized means of verification. ~ Figure 15, Table 6, Appendix E Sections 2.1.1 and 4;.2 - 2010 Census data ext~polated to

~

2020 for permanent residents

.- and employees, transient data

  • Population/Demographics- Population and demographics inform_ation may be verified by identifying provided by .county and state credible sources used for the population data. Credible sources may include census data, city or county emergency management records,* local/tribal organization. records, etc. agencies, Figure 7
  • Metrics - Identification ofthe method(s), standard(s), or precedent(s) used to determine success or failure to meet the design objectives. Section 4.3 Availability/Rellablllty ~*~i\ r' *;~; :,':"-~ .--t,~_.:. ~*.~:::~- ::.-.ft~\.\:~)~*:~

Description of how failures are detected and traGked/trended, how the system is tested ~ind maintained, Sections 2.7, 2.8, 2.9, 4.3 and and how v~lner:abilities are identified, mitigated, and reported. 5 Arkansas Nuclear One A-5 ANS Design Report- Rev. 4

Security and Privacy

~:~t:~/>~~: ):~:~*:. ;; .<.~;.:r~~i?\/ . ,_* t< ; .. ;

ir*.;.;_,-,::.,,->{*1..>1;;_:, ~-,,--.,?,~':c,:~, :-Y.;:i;._,,;

Description of the supporting information and data. Sections 2.6 and 6

  • \...\ * .-_: , . !, ......... "t;:..,- * '-.~ ,-~ *.;.. i.:. .,., ).<'\'.Jo.' *~i' ~

Training and Public Outreach \~__i--,~ ~._.;*'!*< *.., :.,.;:..~ -.,~;?~ '--.~if,:_, ...i:'";1,~:,t~<.

Description of the training required for applicable stakeholders oft:he ANS, including training for personnel who operate and maintain the ANS; also a description of the public education and outreach activities. An informed population is far more likely to understand and respond appropriately to notifications and take action in emergency situations. Section 7

c. Attachments

'<.,.1_.'t- ~,.t+.; ..--1--~:*'- * . {"'.~~~C'i: ,.,.., .._,

~ ~

~::..'"',~- ,:: ~i-.~-~ *; '~/ ~\, ..:..f(#~tTJ,.~7':t:, "-~.._

~

Additional infonnation, such as maps, d*iagrams, and/or references, which support the efficient evaluation of an ANS, should be included. Not applicable Arkansas Nuclear One A-6 ANS Design Report - Rev. 4

APPENDIX B ANO EWS Activation Procedures

RAPID WARNING SYSTEM ACT/VAT/ON (Pre-Activation ofSEOF)

CHECKLIST THIS CHECKLIST IS FOR USE FOR IMMEDIATE ACTIVATION OF THE EMERGENCY WARNING SYSTEM FOR GENERAL EMERGENCY CLASSIFICATIONS PRIOR TO ACTIVATION OF THE RADIOLOGICAL EMERGENCY RESPONSE TEAM.

TIME: DATE: EC#:

OPERATOR/SDO:

l. [ ] (ANP ONLY) IF A STAFF DUTY OFFICER IS PRESENTl.CONTACT ADH COMCENTER VIA HOT LINE OR DEV /VS AND INFORM THE COMCENTER OPERATOR THAT ANP IS ASSUMING OPERATION CONTROL OF ACTIVATION OF THE WARNING SYSTEM.

NOTE: THE ADH COMCENTER OPERATOR WILL BE RESPONSIBLE FOR THE ACTIONS IN THIS CHECKLIST UNLESS NOTIFIED TO THE CONTRARY BY ANP SDO)

ACTIVATION OF SIRENS AND TONE ALERT RADIOS MUST OCCUR WITHIN 1 5 MINUTES OF NOTIFICATION - DO NOT DELAY

2. [ ] USING THE "RECOMMENDED PROTECTIVE ACTIONS - EVACUATION" INFORMATION FROM THE "EC" FORM, TRANSFER THE ZONES TO BE EVACUATED TO THE "GOLD" EVACUATION MESSAGE FORM (S)

J

3. [ ] USING THE "RECOMMENDED PROTECTIVE ACTIONS - SHELTER" INFORMATION FROM THE "EC" FORMR TRANSFER THE ZONES TO BE SHELTERED TO THE "GREEN" SHELTE ING MESSAGE FORM (S)
4. ~USING THE DEF/VS FAXA TRANSMIT ALL APPROPRIATE MESSAGE ORMS TO THE NATION L WEATHER SERVICE.
5. [ \\,VERIFY RECEPTION OF THE MESSAGE FORMS BY THE NATIONAL EATHER SERVICE VIA NAWAS.

TIME THIS SECTION COMPLETE,._,.,*_ _ _ _ _ _ _ _ _ __

6. ] USING THE ZETRON CONSOLE:

A. ARM CONSOLE USING KEY B. SELECT "SIREN" NET C. SELECT "KXRJ ON" D. PRESS "PAGr-SAFETY

Fonn 11001 03/2020 PAGE I

RAPID WARNING SYSTEM ACT/VA TION (Pre-Activation ofSEOF)

CHECKLIST THIS CHECKLIST IS FOR USE FOR IMMEDIATE ACTIVATION OF THE EMERGENCY WARNING SYSTEM FOR GENERAL EMERGENCY CLASSIFICATIONS PRIOR TO ACTIVATION OF THE RADIOLOGICAL EMERGENCY RESPONSE TEAM.

7. [ ] USING ENS, TRANSMIT (IN A FILL-IN-THE-BLANK METHOD) ALL APPROPRIATE MESSAGE'.S TO RUSSELLVILLE AREA BROADCAST STATIONS.

AFTER HOURS SEE ATTACHMENT #1.

8. ] USING THE ZETRON CONSOLE:

A. ARM CONSOLE USING KEY B. SELECT "SIREN NET Fl" C. SELECT "ENS RADIO" D. PRESS "PAGE SAFETY

E. WAIT 10 SECONDS F. PRESS THE "TRANSMlr BUTTON AND READ THE FOLLOWING MESSAGE

'THIS IS THE ARKANSAS DEPARTMENT OF HEALTH .... ATTENTION ALL BROADCAST STATIONS .... PLEASE LOCATE YOUR GOLD AND GREEN MESSAGE FORMS AND STAND BY FOR AN EMERGENCY MESSAG~ .. REPEATING ... ALL BROADCAST STATIONS, PLEASE LuCATE YOUR GOLD AND GREEN MESSAGE FORMS AND STANDBY FOR AN EMERGENCY MESSAGE"

9. ] WAIT 1 MINUTE FOR STATIONS TO LOCATE FORMS
10. ] USING THE ZETRON CONSOLE:

A. SELECT "SIREN NET Fl" B. SELECT "ENS RADIO" C. PRESS "PAGE SAFETY" D. WAIT 10 SECONDS E. PRESS THE "TRANSMIT' BUTTON AND READ THE FOLLOWING MESSAGE "THIS IS THE ARKANSAS DEPARTMENT OF HEALTH ....

ATTENTION ALL BROADCAST STATIONS PLEASE FILL OUT AND CHECK THE NOTED INFORMAtlON ON YOUR "GOLD" EVACUATION MESSAGE." (READ SLOWLY AND CLEARLY EACH APPROPRIATE BLANK THEN REPEAT FOR THE GREEN MESSAGE) "PLEASE ALL OUT AND CHECK THE NOTED INFORMATION ON YOUR "GREEN" SHELTERING FORM. EAS TONE ACTIVATION IS REQUESTED, THE SIREN WARNING SYSTEM WILL SOUND MOMENTARILY" Form 11001 03/2020 PAG E2

RAPID WARNING SYSTEM ACT/VA noN (Pre-Activation ofSEOF)

CHECKLIST THIS CHECKLIST IS FOR USE FOR IMMEDIATE ACTIVATION OF THE EMERGENCY WARNING SYSTEM FOR GENERAL EMERGENCY CLASSIFICATIONS PRIOR TO ACTIVATION OF THE RADIOLOGICAL EMERGENCY RESPONSE TEAM.

TIME THIS SECTION COMPLETED - - - - - - - = - - - - - - - - - -

11. [ ] ACTIVATE THE SIREN WARNING SYSTEM IN ALL ZONES 1 2. ] USING THE ZETRON CONSOLE:

A. SELECT "SIREN" NET B. SELECT "ALERT ALL ZONES" C. PRESS "PAGE SAFETY" D. DO NOT CANCEL, SIRENS WILL SOUND FOR 3 MINUTES!

TIME THIS SECTION COMPLETED: - - - - - - - - - - - -

1 3. [ ] CONFIRM RECEPTION OF MESSAGES BY THE FOLLOWING RADIO STATIONS: *

! j KOC KMTC RUSSELLVILLE RUSSELLVILLE KXRJ (ATU) RUSSELLVILLE (479) 968-6816 (478) 968-7400 (4 79) 968-0222 Or (479) 317-7127 or (479) 968-0583 NOTE: IF ANY STATION(S) FAILED TO RECEIVE MESSAGE(S) VIA ENS, READ THEM IN A FILL-IN-THE-BLANK METHOD.

14. [ LITTLE ROCK ECC ONLY) NOTIFY ANY COUNTY WARNING POINTS W HICH FAILED TO RESPOND TO THE ROLL CALL CONDUCTED BY ANO (ANO WILL NOTIFY ADH OF ANY STATIONS WHICH FAIL TO RESPOND TO THE NOTIFICATION ROLL CALL)

POPE COUNTY 1479! 890-6914 JOHNSON COUNTY 479 754-2200 lOGAN COUNTY 479 963-6800 YELL COUNTY 479 495-4881 CONWAY COUNTY ( 01) 215-4911 ADEM (STATE EOC) (501) 683-6705 1 5. [ ] (LITTLE ROCK ECC ONLY) COMMENCE CHECKLIST FOR NOTIFICATION AND ACTIVATION OF RADIOLOGICAL EMERGENCY RESPONSE TEAM

16. [ ] (ANP ONLY) COMMENCE CHECKLIST FOR SDO / LGL SEOF PRE-ACTIVATION.

Form 11001 03/2020 PAO E3

RAPID WARNING SYSTEM ACT/VA TION (Pre-Activation ofSEOF)

CHECKLIST THIS CHECKLIST IS FOR USE FOR IMMEDIATE ACTIVATION OF THE EMERGENCY WARNING SYSTEM FOR GENERAL EMERGENCY CLASSIFICATiqNS PRIOR TO ACTIVATION OF THE RADIOLOGICAL EMERGENCY RESPONSE TEAM.

TIME THIS SECTION COMPLETED

  • END*

Foll!l 11001 03/2020 PAG E4

LOCAL BROADCAST STATIONS AFTER HOURS RECALL Radio stations in the Russellville area may not be manned after normal business hours or on weekends. These stations have agreed to recall their staff upon notification. This notification will be done by calling until ONE person from each station has been reached.

  • EAB Radi 0 Group Name & Numbers Attempt Attempt Attempt Result 1 2 3 Aaron Elmore Home(479)890-0508 Studio Numbers (479) 968-6816 .

(479) 968-6821 Johnny Story Studio Numbers (479) 968-6816 (479) 968-6821 KMTC Radio Mellssa Krueger Studio Number (479) 968-7400 KXKJ A I u Radio (May Not Re~ond Jf No One is here)

(479)-968-0222 Or (47~)-317-7127 Or (479)-968-0583 Form 11001 03/2020 PAG E5

1 APPENDIXC ANO SWS Testing and Maintenance Procedures

Arkansas Nuclear One Siren Warning System Maintenance Plan Siren Site Maintenance Plan Pqe1~f1 Siren#: Tech: Date:

Perfonn the following Inspections/tests and record condition/results:

NOTE: Ensure the use of er PPE NOTE: Take photo (s) of siren damage as needed.

Check the Followlng: Compl~ COMMENTS/REPAIRS PERFORMED Record slren--number. Technician's name 1 & date In spa~~ provided above.

Check Trees and Vegetation around Ca bl net. Antenna and Homs. So as not to damage or affect sirens function, e.g. trees 2 near horns, cannot access controls.

Check Pole for damage, e.g. leaning, sinking, severe oxidation, ground rods 3 missing, loose or cut Check Radio Antenna for damage, e.g.

4 missing, elements missing.

s Check for upper horn damage.

Check Cabinet for damage, e.g. door seals, severe dents or ~lstortlon, lock broken, 6 water or l_nsect Intrusion.

Check Electronics for damage, e.g. loose connections, corrosion, chafing of wlf'es, 7 heat dlscoloratlon & surge suppressor.

Check Ba_tterles for damage, e.g. termlnal r corrosion, casing distortion, heat 8 dlscoloratlon .PERFORM LOAD TEST-Oleck the Power Drop for damage, e.g.

weather head not sealed, splices ex~.

cables frayed, cable Insulation damaged, 9 disconnect malfunction.

10 ~ and record battery voltage. Voltage= voe Monitor Battery volta8:e while running a silent test. Ensure batterv voltage goes no 11 lower than 21 VDC.

Plug In charger - watch for chafBel' to 12 COfTl8 on & current meter to r1se.

Run SIient Test. Check that all amplifier

':£D's are on and all components are med on.

NOTE: ADDmONAL COM_MENTS ON BACK

i'

  • Arkansas Nuclear One Siren Warning System Maintenance Plan NOTE NATURE OF REPAIR: (Parts replaced, Possible c;ause of the problem)

.i NOTE IF ADDmONAL ACTION(S) IS REQUIRED: (Driver replacement, Battery change)

.MELE:M ENGINEERING COMPANY INC.

51 Winthrop Road Chaster, Connecticut 06412-0684 Phone. (800) 63SIREN Phone: (860) 526-9504 Fax: (860) 526-4784 Internet: www.whelen.com Sales e-mail: iowsales@whelen.com Customer Service e-mail: iowserv@whelen.com WPS-2800 SERIES HIGH POWER VOICE

& SIREN SYSTEM Operating and Troubleshooting Manual For warranty information regarding this product, visit www.whelen.com/warranty 02001 Whelen Eng1neenng Company Inc Form No 13580C (100710)

Table Of Contents Section I: Overview of System Components

'a) Station Component Locations ..................... - .................................................. page 4 b) Station Components Defined ............................................................................ page 5 Section II: System Operations a) Remote Operations ..........................................*-****....................................... page 8 b) Local Operations ............................................................................................... page 8 Section ill: Understanding Station Addressing Central Point Source ........................................... - ............................................... page 10 Governmental ......................................................................................................... page 16 Section IV: Troubleshooting Audio Loss .............................................................................................................. page 17 Solar Regnlator ...................................................................................................... page 18 AC Battery Charger............................................................................................... page 18 Digital Voice .................................................. - ...................................................... page 20 Partial or Full Diagnostic Failure ............... - ................... ~***** ............................. page 20

  • , Section V: System Maintenance Frequency of Testing and Activation .................................................................... page 21 Quarterly Maintenance ......................................................................................... page 22 Visual Siren Station Inspection ...................._ ..................................................... page 23 Siren Cabinet and Components ............................................................................ page 23 Speaker Assembly and Pole Top Equipment ....................................................... page 23 Station Performance Testing ................................................................................. page 24 Maintenance Check List ........................................................................................ page 26 Illustrations Fig. 1: Station Wiring Diagram ....................................................................................................... page 3 Fig. 2: Siren Cabinet Door Components ........................................................................................ page 4 Fig. 3: Station Control Panel ........................................................................................:.................. page 9 Fig. 17: System LED Diagnostic Indicators ................................................................................... page 28 Page~

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Section I: Overview of System Components a) Station Component ~ocations The WPS-2800 High-Power Voice and Siren System is comprised of 10 basic models:

Model Driver Info Cabinet

, WPS-2800-1 One (1 ), 400 Watt Driver Type II WPS-2800-2 Two (2), 400 Watt Drivers Type II WPS-2800-3 Three (3), 400 Watt Drivers TypeII WPS-2800-4 Four (4), 400 W~tt Drivers Type II WPS-2800-5 Five (5), 400 Watt Drivers Type II WPS-2800-6 Six (6), 400 Watt Drivers Type II WPS-2800-6A Six (6), 400 Watt Drivers Typeill WPS-2800-7 Seven (7), 400 Watt Drivers Typem WPS-2800-8 Eight (8), 400 Watt Drivers Type ill WPS-2800-9 Nine (9), 400 Watt Drivers Typeill WPS-2800-10 Ten (10), 400 Watt Drivers Type ill Each system ess~ntially functions in the same manner as do the others. This manual will provide the necessary information to properly operate, program and diagnose this system regardless of specific model. If information relevant to a specific model is required, it shall be presented and noted as such.

T~e 2800 series systems are comprised of several major components common to all models, although quantities of some components will vary from model to model.

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b) Station Components Defined Control Board - This component (located on the inside of the upper cabinet door) controls the key functions of the WPS4000 system including:

Tone Generation Remote Activation Event Timing Rotor Control Remote Station Status Reporting* (encoding) Local Control System Diagnostics (incl. SI TEST)*

  • optional equipment The control board contains a microphone jack for public address and a serial port to allow connection of a palm computer (hereafter referred to as a PalmPC) to the remote station.

The control board is also the location of the diagnostic LED's.

Siren Amps - These components (located on the inside of the upper cabinet door) receive the desired tone or message generated by the control board, amplify it and deliver it to the siren driver.

Siren Driver - This component (located in the speaker a~mbly) produces the desired audible tone or voice message.

Radio or Landline Board (Optional) - This component (located on the inside of the upper cabinet door) receives signals from either the antenna or landline and delivers them to the control_ board for processing. Through the use of the included radio, the station is also capable of transmitting status information back to the control center.

Motherboard - This component (located on the inside of the upper cabinet door) distributes Battery Voltage and signals to all system components that require this voltage. The motherboard is fused @10 Amps to protect all connected components EXCEPT for the siren amplifiers and the rotor (they contain their own fuse). The 2nd motherboard (WPS4000-8 only) is also fused @10 Amps. The Motherboard also distributes signals between the amplifiers and the control board.

AC Battery Charger-This component {located on the inside of the lower cabinet door) uses 110 VAC (or 220 VAC) single-phase service to maintain the stations batteries at their proper voltages.

Page5

Solar Regulator (optional) - This component (located on the inside of the lower cabinet door) uses electrical energy collected by a pole-mounted solar panel to maintain the station batteries at their proper voltages.

Ammeter - This component (located on the inside of the lower cabinet door) provides a visual indication for the charge current flowing into the batteries from the charger or regulator.

Voltmeter - This component (located on the inside of the lower cabinet door) provides a visual indication of the DC voltage across the ~atteries.

Auxiliary Control Status Board (optional) - This component (located on the right inside wall of the upper cabinet) is wired to remote switches to facilitate remote operation of a specific siren station.

Batteries - These components (located on the inside of the lower cabinet) provide the 28VDC necessary for the system to operate.

Battery Disconnect Switch - This component (located on the rear inside wall of the upper cabinet) allows all system batteries to be completely disconnected from the system. NOTE:

This switch does not disconnect the batteries from the battery charger or regulator.

Antenna Poly Phaser (optional) - This component suppresses high-voltage (static) charges that could be present on the antenna.

Antenna (optional) - This component (located on the utility poie) is capable of either receiving signals broadcast from the control center (one-way) or can both transmit and receive signals to and from the control center (two-way), depending how the system was ordered.

Solar Panel (optional) - This component (located *on the utility po*e) collects solar energy, converts it to electrical energy and delivers it to the Solar Regul!ltor to maintain the station batteries at their proper voltage.

Page6

Strobe Control Board (optional) - This component (located on the rear inside wall of the upper cabinet) is a user-defined device that controls a pole-mounted strobe light. This light can be configured to activate during specific conditions (example: when any tone or message is generated).

Intrusion Alarm (optional) - This sensor (located on the door jam of the upper cabinet door) detects the opening of the cabinet door. If the station is equipped with this option, the alarm is configured to transmit a signal back to the control center.

Page7

Section II: System Operations a) ~emote Operations Remote operation of a WPS-l800 series siren involves transmitting signals from the_ control center to the desired station. This is accomplished by using either an encoder and transmitter or, if the station is so equipped, using an auxiliary control status board- that has been wired to switches/controls at the control ~nter. Remote operation is beyond_ the ~pe of this document and will therefore not be addressed. IT your system is equipped with an encoder, please ~fer to the encoder* operating manual for information regarding remote operation. If your station has been wired to use the auxiliary control status board, refer to the reference materials provided by the electrical e~gineer Qr installer.

b) Local Operations Local operation is accomplished thry>ugh the control panel on the front of the station cabinet. The functions of these controls are as .follows:

Cancel Abruptly stops siren tones without the normal "ramp down" found in several tones. Helpful in the event of an accidental tone activation.

Wail Pl'.()duces a slow rise and fall tone.

Attack Produces a faster rise and fall tone (used for designated Civil Defense National Attack tone).

Alert A steady tone (Civil Defense alert).

Whoop A repetitive rise-only to~e:

Hi-Low An alternating two-tone sound.

Air Horn* A pulsing air horn sound.

I SI TEST Initiates SI TEST@ tone and th*e* optional diagnostic SI TEST. r:outine.

Xmit Carrier Actuates ~mot~ station radio transmitter PTT circuit.

When tone squelch is used with ithe transmitter, the transmit function is used when adjusting tone squelch modulation.

Page8

Xmit Audio For use with remote station radio transceiver, causes transmission of DTMF tone via RF link for tone modulation adjustment. The transmit tone level is adjusted with the transmit audio potentiometer located on the controller board (see "Fig. 4: System LED Diagnostic Indicators" page 28).

Xmit Status Transmits stati9n status information and battery voltage to the control center.

DVMTest Activates the Digital Voice Message (DVM) assigned to the test procedure in the configuration software.

Rotor CW No function with 2800-series equipment.

RotorCCW No function with 2800-series equipment.

Keypad Arm Enables local station operation* via keypad. Once pressed, the keypad remains active until either a) another keypad button is pressed, or b) 60 seconds have elapsed, whichever comes first. The Keypad Arm button must be pressed each time a keypad button is to be pressed. Note that the Cancel button is always enabled and does not require Keypad Arm to be pressed.

Fig. 3: Station Control Panel Page9

Section III: Understanding Station Addressing Every Siren Station in a given area code has its own, unique "Station Address". This address allows the user to select an individual or a group of stations. As stated elsewhere in this manual, a valid station address can be any number from 00()0 to 9999. This allow~ for 10,000 unique addresses; a staggering number of stations to keep track of. Although it is logistically impossible to have that ma~y stations in a single area code, it does illustrate the importance of a sensible, intuitive numbering convention for station addresses. This section will outline two types of conventions Central Point Source: Quadrant, Sector, Radial & Station Frequently, warning systems are used to notify the public of emergency situations that may occur from a single, centralized location. Typically, siren stations. , would be located throughout a 360° area surrounding this location for a specified distance from the source. In this scenario, the Central Point Source convention would be well suited.

For illustration purposes, assume the siren stations are installed within a 5 mile radius of the Central Point. As such, a Quadrant, Sector, Radial & Station numbering convention would allow the selection of any of the followin~:

  • any one of four sectors
  • any one of 5 radii within the sectors The area of coverage 'in this system, a circle, is divided.into 4 quadrants. Each quadrant is then divided into 4 sectors. Each sector is further divided into 5 segments or radii emanating from the center of this siren system.

4 1 4 3 2 3 QUADRANTS 1-4 QUADRANT SECTORS 4 1 3

© RADII INDIVIDUAL STATIONS Page 10

In this system, a stations address is structured as follows:

l!.w1 Allocation 1 Quadrant (1 to 4) 2 Sector (1 to 4) 3 Radii (1 to 5) 4 Individual station within a radian Here are some sample activations to further illustrate this concept.

Sample 1:

A station with address 1354 would be located in:

Quadrant: 1 Sector: 3 of Quadrant 1 Radial: 5 Station: 4 If an operator selects station 1-3-5-4, only that station will be selected, as shown.

SINGLE STATION SELECTION STATION 1354 Page 11

Sample 2:

lf the activation of a group of remote stations within a whole segment of a radius within a quadrant and sector is desired, the fourth digit address is substituted with a "Wild Card",

the "#" pound sign.

An address selection of 1 4 - # would activate the system as follows:

Quadrant: 1 Sector: 3 of Quadrant 1 Radial: 4 Station: # All stations defined by above This selection is shown below.

\

GROUP SELECTION-RADIAL SECTOR GROUP 134#

Page 12

Sample 3:

Selection of an entire sector can be accomplished by using the following address:

Quadrant: 1 Sector: 3 of Quadrant 1 Radial: # All radial 1 - 3 Station: # All stations defined by above In selecting a sector, the first two digits of the address are set for the sector address, for example 1 - 3 (Quadrant 1 - Sector 3). The third and fourth digits are substituted with a #

(Wild Card). Therefore, the address to select all stations in sector 1-3 is 1 # - #. This selection is represented below.

  • GROUP SELECTION-SUB-SECTOR GROUP13##

Page 13

Sample 4:

The selection of a complete quadrant can be achieved by using the following address:

Quadrant: 1 Sector: # All sectors of Quadrant 1 Radial: # All radials in all sectors of Quadrant 1 Station: # All stations defined by above When selecting a quadrant, the first digit designates the Quadrant (1). the second, third and fourth digits are replaced with Wild Cards (#,#,#). Therefore, the address for selecting all stations in quadrant 1 is 1 - # - # - # as illustrated below.

/ /

I GROUP SELECTION-QUADRANT GROUP###

Page 14

Sample 5:

All stations in a system may be accessed by using the Wild Card(#) for all address numbers.

The address would be# - # - # - #.

Quadrant: # All Quadrants Sector: # All sectors of all Quadrant Radial: # All radials of all sectors of all Quadrants Station: # All stations defined by above This "All Call" is illustrated as shown.

GROUP SELECTION-"ALL-CALL" GROUP####

Page 15

Governmental: County, City & Station For this next type of address structure, assume that the siren system in question is used primarily for tornado warnings throughout a major population center. This center encompas~es three counties with each county having no more than ten cities. Two cities contain more than 50 high-power voice and siren stations.

The following represents a Governmental System 4-digit address configuration, allowing activation by." All Call", county group activations, city group activations an<J indi".idual station activations:

X X X X

. _. ......... : ........... Individual Siren Station (0 .: 9)
........ ; .................. ~ ....... City (0 - 9)*
..................................*.....*..... . County (0 - 9)
  • One digit could also be reserved for unincorporated areas.

An address of 2 4 - 5 would indicate the following individual station:

Siren Station 45, in City 5, in County 2.

The Wild Card (#) permits the use of several different types of group activations. Three samples follow:

Sample 1: County Activation (1 - # - # - #)

All Siren Stations in all Cities in County 1 will be activated by this transmission.

Sample 2: City Activation (1 # - #)

All Siren Stations in City 5 of County 1 will be activated by this transmission.

Sample 3: System All Call(# - #- #- #)*

All Siren Stations in all Cities in all Counties will be activated by this transmission.

Page 16

Section IV: Troubleshootin,:

Audio Loss If after activating the siren there is no audio output, perform the following procedure step by step. This procedure will require a digitai multimeter.

1. Locate the Audio Presence LED on the controller board (see "Fig. 4: System LED Diagnostic Indicators" on page 28). When audio is present on the board, this* LED will be on.
2. Activate the WAIL siren tone from the control panel on the siren cabinet. Confirm that the Audio Presence LED is on. H this LED is not on or if it turns off quickly, measure the battery voltage. The siren will not activate if battery voltage drops below 19 VDC. Be sure to measure the battery voltage at the same time you activate the siren. The batteries may show a good float voltage while they are not under load, but upon activation, the battery voltage may drop below 19 VDC if their capacity is low.

Note that when the siren shuts down and the load is removed from the batteries, the voltage may rapidly return to 25 VDC or more. If this condition is occurring, the batteries will need to be replaced. If the voltages are in the normal range, proceed to step 3.

3. Locate connector J2 on the control board. With your multimeter set to AC volts, measure across pins 6 and 7 {White with Orange stripe and White with Brown stripe). With the siren tone running, 5 VAC should be present. If no voltage is present, the controller board is probably at fault _

NOTE: Confirm that the audio presence LED is on while performing these measurements. It indicates that the siren controller is still activated. If the specified voltages are present, proceed to step 4.

4. With the siren tone still active, ~easure across pin 1 (Blue wire) and pin 2 (Black w/

White trace) on each of the siren amplifiers. 5 VAC' should be present at each amplifier. If so, proceed to step 5. If no voltage is measured, this is indicitive of a wiring problem between the controller board and the siren amplifiers. Check the wiring between these components

5. Remove the Red siren driver lead from each siren amplifier. Press "Cancel" on the control panel and then press "Wail". Measure across the output of each amplifier (White Weco connector) with the siren driver disconnected. 70 YAC should be measured. If this voltage Ieve is measured, proceed to step 6. If this voltage level is not found and 5 VAC was measured at the input, proceed to step 7.
6. Set your meter to measure resistance at its lowest scale. Measure across each of the speaker drivers, making sure that at least one wire of each driver is removed from the power amplifier (or else the transformer in the amp is being measured as well).

EachI driver should have a DC resistance of approximately 3 Ohms +/- .3 Ohms. If a resistance value outside of this range is found, contact factory.

Page 17

7. Set your meter to measure DC Volts. Connect the negative lead of your meter to ground (one of the solid black wires in the multi-position connector on the amplifier is a good ground source). With a siren tone activated, measure the following wires for the following voltages (approximately):

Grey 6 VDC Brown SVDC Solid White (all) 24VDC AC Battery Charger The AC-powered battery charger has two charging modes: Equalization Mode and FloJlt ChaFge Mode. The charger is in equalization mode when AC power is first applied; the charger will stay in equalization mode until the battery voltage reaches approximately 31.5 VDC. Once the battery voltage reaches that point, the charger will switch to float voltage mode. In that mode it will charge the batteries to the appropriate voltage relative to the temperature or the batteries (25 to 29 VDC).

The AC battery charger contains two circuit boards positioned on either side of the large transformer. One of these boards contains a single, green LED, while the other board con-tains a pair of LED's, one green and one yellow. This pair *or LED's provides diagnostic information for the battery charger. The following chart defines their various diagnostic states.

Solar Regulator The following procedure can be perfonned to confirm proper operation of the solar regulator: *

1. Disconnec.t the solar panel from the charger. With a DC voltmeter, measure the voltage across the wires coming from the solar panel The voltage should be greater than 32 VDC (NOTE: The solar panel must be in direct sunlight).
2. Reconnect the solar panel to th~* charger. Monitor the battery voltage with the cabinet voltmeter. The float v~ltage will vary between 25 to 30 VDC, depending on battery temperature. When the solar regulator is charging, the DC LED on the circuit board will be on. During normal operation the charger will cycle on and off.

The float voltage will vary with battery temperature. The following is a brief description of the normal charging cycle:

Page 18

If the float voltage for the current temperature of the batteries is 26 VDC, the regulator will turn on at 26 VDC (LED will come on) and it will charge the batteries to 28 VDC. Once the battery voltage reaches 28 VDC, the regulator will turn off (LED will go oft), and the battery voltage will be ~llowed to drop to 26 VDC.-The cycle would then repeat itself. If the float voltage was 27 VDC, it would cycle from 27 VDC to 29 VDC.

Green LED Yellow LED OFF Not Working Normal Condition FLASHING Serial Communications Failed No Thermistor or Thermistor is bad ON Charger Operating Properly Equalization voltage mode When AC power is applied to the battery charger, the following voltag~ should be measured on the wires coming off the charger:

Note: Refer to "Fig. 1: Station Wiring Diagram" page 3.

Pin 2 (Black)

~I g::== (BC-1 )Two-Position Connector -

Pin 1 Charger output wires (25 to 32 VDC)

(White)

Pin 2 (Grey) Q[J I b= (BC-2)Three-Position Connector -

19 VDC from Grey to Ground Pin 1 (Black wire in BC-1)

(Orange)

Socket 1 (Red)

=i.==:i-p~1 [JeJ (BC-3)Two-PosrtJon Connector -

Battery Voltage to ground (Black wire in BC-1) Note:On/y when the siren is powered up.;

this is sourced from the siren motherboard.

Pin 2 (Black/White)

(BC-4)Two-Position Connector -

Pin1 (Blue) go No Connection I Not Used Page 19

Digital Voice

1. Remove all amplifier fuses.
2. Install an 8 ohm speaker at amplifier audio input connector pins 1 and 2 (Blue ap.d Black w/White wires) in the 16 position connector.
3. Select a siren tone by pressing one of the controls on the front panel.
4. If the tone can be heard through the s~ker, press the DVM-Test control to play the predesignated message.

Partial or Full Diagnostic Failure This procedure is to be used if the Partial or Full diagnostic LED (located on the controller board) indicates that a problem_ has been detected. A Partial indication means that at least one speaker and/or*amplifier is operational. A Full indication means that all speakers and amplifiers are operational; NOTE: In order for a good Full indicator to be valid, a good Partial indicator must also be present).

1. Connect the PalmPC to the siren station via the com port on the front of the siren cabinet control panel.
2. Display the "Status" screen on the PalmPC.
3. Press the SI TEST *control on the front control panel.
4. Each amplifier contains a red LED that is visible on the front of the control panel.

Note if all the LED's are on. '.fap the "Update Status" button on the PalinPC and note wh;ch amp is displaying an error.

5. Open the front panel and swap the speaker driver wires from the amplifier that indicated a failure, with an amplifier with a lit LED. For example: if the L_ED for amplifier 1 is the only LE~ not on, install amplifier 1 speaker'wires onto amplifier 2 and install amplifier 2 speaker wires onto amplifier 1. This will diagnose if it is the speaker or the amplifier that has failed. You may also measure the DC resistance of the speaker driver with your ohm meter. Be sure that the*speaker driver wires are disconnected from the amp prior to measuring. A good driver will read 3 ohms +/- .3 ohms.
  • Page 20

Section V: Maintenance Although The WPS-2800 is of a dependab.le, solid-state design, periodic activation, field inspection and preventive maintenance is recommended to insure the maximum performan~e of each station.

Frequency of Testing and Activation A system of twice-monthly activation and *confirmation, combined with a quarte~ly service and preventive maintenance is recommended to help insure the successful performance of a station. Increasing the frequency of testing will support and improve a station's test record.

Stations located in environmentally adverse locations will require inspection and preventive maintenance at more frequent intervals than just discussed. Stations should always be inspected following severe storms.

If a station is activated by remote control (landline or radio), the twice-monthly activation should be performed using the remote control link.

The twice-monthly activation of a station can be confirmed by several different methods, depending upon the options selected with each Whelen System.

Local Site Confirmation For a basic station activated at the cabinet, or by landline' or radio, -have an' observer confirm that the station activated audibly. The observer should report successful as well as failed station tests. Station Performance Logs should be maintained. It is important to understand that audible_*confirmation alone is not assurance that the station is operating at 100% power. This requires inspecting the station in greater detail.

Stations '1}ay be optionally equipped with counters that advance upon radio or tone generator activation. These counters do not confirm total operation or the fmal expected output of an outdoor warning device.

If a station is equipped with SI TEST diagnostics (optional), the station's activation may be confirmed using SI TEST or full power siren mode. Following an activation, SI TEST displays its informatjon OQ control board mounted LED's or through a LED display board visible on the right side of the cabinet. Fig. 17 shows the location and function of the LED's on the control board. The cabinet mounted display board LED's will confirm the following (from Left to Right):

Red AC Power 1

Yellow DC Power at minimum proper operating level Red Partial Amplifier and Speaker Driver Operation Green Full 'Amplifier and Speaker Driver Operation

?Red Rotor Operation Page 21

Following activation and observation the results should be noted in the performance log.

Any indication of incomplete operation presented by the LED indicators should prompt Il\rnEDIATE service attention.

The SI TEST system retains information until cleared by a specific command.

The SI TEST information stored at the station, if not cleared, will update itself automatically with subsequent SI TEST activations.

Remote Monitoring and Confirmation Stations equipped with the optional Whelen COMM/STAT' Command and Status Monitoring control, allow remote monitoring 'of status as well as confirmation of system activation. COMM/STATJ'M returns the results of a remote station activation (both SI TEST and siren warning mode) in a DTMF en~oded format via radio link.

Remote monitoring by RF link eliminates the necessity of physically visiting a station to confirm an activation.

Following the activation of a station, a "Status Request" may be sent to that station by DTMF encoded radio command. Diagnostic SI TEST information is then presented to the status encoder at the station, cop.verted into DTMF code and transmitted back to the control center, where one of several COMM/STA'fTM base station products will convert the DTMF code into meaningful information.

Quarterly Maintenance Developing a quarterly inspection and preventive maintenance program for an outdoor warning station requires a thorough µnderstanding of all the elements and expectations of the system. The following section provides an overview and basic guideline for quarterly station inspection and prevenfr~1e maintenance program for the sample station.

Page 22

Visual Siren Station Physical Inspection

  • Observe the spea~er cluster, siren cabinet and AC Service for any signs of damage or loose mounting hardware (Some shrinkage of a newly treated utility pole may occur in the first several years foJlowing installation, requiring the tightening of mounting hardware.
  • Check all conduit for watertight connection and entrance into the siren cabinet.
  • Inspect the AC Service for damage, blown fuses, degraded (corroded) power connections and integrity of the lightning arrestor.
  • Inspect the grounding system for AC Service, Siren Cabinet and pole top equipment.

Verify connections and acceptability of earth ground.

  • Observe the pole for any shifting and/or leaning. Poles that are not plumb will not properly direct alerting sounds.
  • Examine entire station for any signs of vandalism or forced entry.

Siren Cabinet and ~omponents

  • Inspect AC Outlet, fuse and surge suppression equipment. Examine system for infiltration of foreign material(s), rodents or other pests.
  • Inspect and, if necessary, clean all drain holes and vent screens.
  • Inspect battery terminal connections and clean if necessary. Re-apply silicone coating to battery terminals if necessary. Observe battery voltage with siren in inactive state (AC power must be on to station, otherwise station must be powered up to observe meter).
  • Examin,e all wiring harnesses for chafing. Verify wiring terminations for tightness and wiring connections for proper electrical connections. Replace and correct any corroded or marginal connections. Inspect antenna for proper connection.

Speaker Assembly and Pole Top Equipment NOTE: Any examination of Pole Top equipment should be performed with the station audibly disabled.

  • *Inspect speaker for blockage by rodents, pests or other foreign material. Clean if necessary. Inspect any wiring cables or harnesses for chafing. Inspect the siren driver compartment for infiltration of foreign materials, rodents or pests. Clean if necessary.

Confirm that the driver compartment will allow for water or moisture drainage. Inspect speaker wiring connections for any sign of corrosion.

Page 23

  • Verify tightness of all mounting hardware.
  • Check all wiring term"inations and connections.
  • Verify lubrication of the rotor gear train. The recommended inspection interval is initially 6 months. Following the initial two ins-pections, the owner may determine if a longer inspection- interval is acceptable. Varying weath_er conditions will affect this interval. Many stations are located in areas of the country where an annual inspection/

lubrication interval is acceptable.

Station Performance Testing NOTE: Depending on loc:al conditions and station options selected, the station may be tested on or off line. Off line testing of the station involves disconnecting the ~peaker drivers from the siren amplifiers, so as not to disturb the public when verifying tone,gen*erator operation. A co~lete test must, however, indude the testing of the siren amplifier operation. Th'/s can be accomplished inaudibly on units equipped with SI TEST.

Other units must be audibly tested.

  • A basic routine, verifying the performance and operation of the sample statjon previously described, would be as follows:
1. Local and Remote Activation -

Activation of each remote station function by local control and remote control. W~th amplifiers on and off line as needed. An examination of each activation function will also facilitate a verification of re~ted and subsequent system module activations and

.electrical connections that would be caused by an activation_ command. Also confirm function time outs (ex.: does the Alert signal time out at three minutes as per user specification?)._ *

2. Resp<<;>nse to Station Address and All Call address programming -

Control *Center reception and activation on SI TEST or non-tone activation, for individual station address and All Call address selection.

3. Public Address -

With the station on line, activation of PA for both local and remote control, verifying PA Audio path and proper set up level of volume. Verify AC drop out on PA.

4. Siren Amplifiers -:

Inspect for complete operation with speaker drivers (observe LED's).

Page 24

5. SI TEST Station Analysis -

Observe and confirm diagnostic status of:

AC DC Partial Amplifier & Speaker Driver Operation (disable one amplifier to confirm this test).

Full Amplifier & Speaker Driver Operation NOTE: Verify AC drop out during SI TEST mode.

6. Battery Charger Operation -

Observe for proper charging operation.

Verify AC drop out in PA or SI TEST mode.

7. Batteries -

Verify voltage stability under load.

Perform. a load test.

8. Status Encoder -

Perform a diagnostic SI TEST of the station.

Compare status information with observations made locally at the station.

Disable one speaker and verify that the "Full" LED indicator is off.

Disable AC and verify that the "AC" LED indicator is' off.

Compare battery voltage return status with observed and measured battery voltage.

9. Transmitter -

Check status encoder DTMF tone level modulation with transmitter.

Check transmitter set up.

Verify power output and SWR.

NOTE:On concluding any examination of a station where connectors have be~n opened and closed , a final rad.io test by either SI TEST or full power should be performed and the results observed for a complete successful tesl The PA audio path should also be audibly verified by sending PA and broadcast a voice message.

The following is a sample form that may be used for quarterly inspection and maintenance.

Page 25

MAINTENANCE CHECK LIST Station#: _ _ _ __ Siren Address: _ _ _ _ _ _ _ _ _ _ _ __

Installation Date: _ _.,___....___ Inspection Date: _ _ _ _ _ _ _ _ _ _ __

Inspector: _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ __

PHYSICAL INSPECTION:

QK NOT OK COMMENT Mounting Hardware Speaker Assembly AC Service Proper Grounding Solar Panels*

Antenna*

Conduit Connections Siren Case Assembly Batteries Components Secure Harnesses LOCAL OPERATIONAL TESTING Battery Voltage Manual Test:

Clear Wail Attack AJert Airhorn Hi-Lo Whoop Clockwise Counter Clockwise (SI TEST):*

ACLED DC LED Partial LED Full LED Rotor LED _

Timer Set LED Audio Present LED Microphone Mic Volume Page 26

MAINTENANCE CHECK LIST (continued)

Radio*:

.QK NOTOK COMMENT Squelch Control Sensitivity Antenna Toned*

Transmit LED Remote Activation:

Clear Wail Attack Alert Public Address Airhorn Hi-Lo Whoop Wail/ 5 Sec.

All Call Speaker LEDs:

1 2

3 4

5 6

7 8

9 10 SI TEST:

AC DC Partial Full Status Request Intrusion*

  • Optional Page 27

Fig. 4: System LED Diagnostic Indicators 0

0 P1 9 POS "D" 0 0 J9 0

MIC. JACK

,~

0 DO NOT ADJUST

@) 0 Transmit Audio D Remote Audio Adjust (FOR USE ONLY WITH MOSCAD)

Adjust "'~

m

o iii U)

D Local PA D OI.II NOT -

Adjust ADJUST j GJ Audio Presence (RED) - Normally off. This LED will light when an audio signal is present on the board .

<ID Partial - Normally on . If all siren amplifiers do not operate properly during a lone activation or SI TEST, this LED will (D

be off. If at least one amplifier operates

12) PTT - Normally off. This LED will light when properly, ii will remain on .

the station transmitter is active.

I[} Full - Normally on . If a siren amplifier does not operate properly during a tone activation

@ Squelch - Normally off. This LED will light or SI T EST, this LED will be off.

when the station is receiving a radio broadcast . If equipped with the optional 1'[ Rotator - This LED will light during siren receive tone/squelch tone , the LED will activation if the rotor oscillates properly.

only light when the receive frequency and sub-audible tone squelch frequency tone is detected. ~- Active - This LED normally flashes at a rate of once every half seconds. When a problem has been detected , this LED (1) AC - Normally on . If no DC voltage was will stop flashing or be off. Also indicates detected during a siren tone or SI TEST, receipt of DTMF data by flashing at a this LED will be off. faster rate for about 1 second .

(i ) DC - Normally on . If no DC voltage was j_g) Fault (R ED) - Normally off. When a detected during a siren tone or SI TEST, problem has been detected , this LED this LED will be off. will be on.

NOTE: In some instances, optional circuit boards may be located directly above these LED's.

0

~ - - -- 15,r'-'-

1 _ _ _ _ _ _ _ __.,,

AUXCS SPARE STROBE 0

Page 28

YlltELEM ENGINEERING COMPANY INC.

51 Winthrop Road Chester, Connecticut 06412-0684 Phone: (860) 526-9504 Internet: www.whelen.com Sales e-mail: lowsales@whelen.com Customer Service e-mail: iowserv@whelen.com Lt. WARNING : This product can expose you to chemicals including Methylene Chloride which is known to the State of California to cause cancer, and Bisphenol A, which is known to the State of California to cause birth defects or other reproductive harm. For more information go to www.P65Warnings.ca.gov.

WPS-2900 SERIES HIGH POWER VOICE

& SIREN SYSTEM OPERATING & TROUBLESHOOTING MANUAL

©2005 Whelen Eng ineering Compa ny Inc.

For warranty information regarding this product, visit www.whelen.com/warranty Form No.13948F (050911)

Table Of Contents Section I: Overview of System Components a) Station Component Locations .......................................................................... page 5 b) Station Components Defined ............................................................................ page 6 Section II: System Operations a) Remote Operations ............................................................................................ page 9 b) Local Operations ............................................................................................... page 9 Section III: Understanding Station Addressing Central Point Source .............................................................................................. page 11 Governmental ......................................................................................................... page 17 Section IV: Troubleshooting Audio Loss .............................................................................................................. page 18 Solar Regulator ....................................................................................................... page 19 AC Battery Charger ............................................................................................... page 19 Digital Voice ............................................................................................................ page 21 Partial or Full Diagnostic Failure ......................................................................... page 21 Section V: System Maintenance Frequency of Testing and Activation .................................................................... page 22 Quarterly Maintenance ......................................................................................... page 23 Visual Siren Station Inspection ............................................................................. page 24 Siren Cabinet and Components ............................................................................ page 24 Speaker Assembly and Pole Top Equipment ....................................................... page 24 Station Performance Testing ................................................................................. page 25 Maintenance Check List ........................................................................................ page 27 Illustrations Fig. la: Station Wiring Diagram (designations) ............................................................................ page 3 Fig. lb: Station Wiring Diagram (voltages) ................................................................................... page 4 Fig. 2: Siren Cabinet Door Components ........................................................................................ page 5 Fig. 3: Station Control Panel ........................................................................................................... page 10 Fig. 4: Central Point Source Divisions ........................................................................................... page 11 Fig. 5: Single Station Selection ........................................................................................................ page 12 Fig. 6: Group Selection - Radial Sector .......................................................................................... page 13 Fig. 7: Group Selection - Sub Sector............................................................................................... page 14 Fig. 8: Group Selection - Quadrant ................................................................................................ page 15 Fig. 9: Group Selection - All-Call .................................................................................................... page 16 Fig. 10: Solar Regulator Connector Pin-Outs ................................................................................ page 20 Fig. 11: System LED Diagnostic Indicators ................................................................................... page 29 Fig. 12: Control Board Wire Colors ............................................................................................... page 30 IMPORTANT! THIS MANUAL ASSUMES THE READER/TECHNICIAN HAS AN INTERMEDIATE TO ADVANCED LEVEL OF PROFESSIONAL TRAINING IN THE FIELD OF ELECTRONICS.

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Section I: Overview of System Components a) Station Component Locations The WPS-2900 High-Power Voice and Siren System is comprised of 10 basic models:

Model Driver Info Cabinet WPS-2900-1 One (1), 400 Watt Driver Type II WPS-2900-2 Two (2), 400 Watt Drivers Type II WPS-2900-3 Three (3), 400 Watt Drivers Type II WPS-2900-4 Four (4), 400 Watt Drivers Type II WPS-2900-5 Five (5), 400 Watt Drivers Type II WPS-2900-6 Six (6), 400 Watt Drivers Type II WPS-2900-6A Six (6), 400 Watt Drivers Type III WPS-2900-7 Seven (7), 400 Watt Drivers Type III WPS-2900-8 Eight (8), 400 Watt Drivers Type III WPS-2900-9 Nine (9), 400 Watt Drivers Type III WPS-2900-10 Ten (10), 400 Watt Drivers Type III Each system essentially functions in the same manner as do the others. This manual will provide the necessary information to properly operate, program and diagnose this system regardless of specific model. If information relevant to a specific model is required, it shall be presented and noted as such.

The 2900 series systems are comprised of several major components common to all models, although quantities of some components will vary from model to model.

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Page5

b) Station Components Defined Control Board - This component (located on the inside of the upper cabinet door) controls the key functions of the WPS2900 system including:

Tone Generation Remote Activation Event Timing Rotor Control Remote Station Status Reporting* (encoding) Local Control System Diagnostics (incl. SI TEST)

The control board contains a microphone jack for public address and a serial port to allow connection of our Siren Diagnostic Programming Tool Software (hereafter referred to as SDPTS) to the remote station. The control board is also the location of the diagnostic LED's.

Siren Amps - These components (located on the inside of the upper cabinet door) receive the desired tone or message generated by the control board, amplify it and deliver it to the siren driver.

Siren Driver - This component (located in the speaker assembly) produces the desired audible tone or voice message.

Radio or Landline Board (Optional) - This component (located on the inside of the upper cabinet door) receives signals from either the antenna or landline and delivers them to the control board for processing. Through the use of the included radio, the station is also capable of transmitting status information back to the control center.

Motherboard - This component (located on the inside of the upper cabinet door) distributes Battery Voltage and signals to all system components that require this voltage. The motherboard is fused @10 Amps to protect all connected components EXCEPT for the siren amplifiers and the rotor (they contain their own fuse). The 2nd motherboard (WPS2900-6 thru WPS2900-10) is also fused @10 Amps. The Motherboard also distributes signals between the amplifiers and the control board.

AC Battery Charger - This component (located on the inside of the lower cabinet door) uses 110 VAC (or 220 VAC) single-phase service to maintain the stations batteries at their proper voltages.

Page 6

Solar Regulator (optional) - This component (located on the inside of the lower cabinet door) uses electrical energy collected by a pole-mounted solar panel to maintain the station batteries at their proper voltages.

Ammeter - This component (located on the inside of the lower cabinet door) provides a visual indication for the charge current flowing into the batteries from the charger or regulator.

Voltmeter - This component (located on the inside of the lower cabinet door) provides a visual indication of the DC voltage across the batteries.

Auxiliary Control Status Board (optional) - This component (located on the right inside wall of the upper cabinet) is wired to remote switches to facilitate remote operation of a specific siren station.

Auxiliary Input Control (optional) - This component (located below the " Radio/Landline Board" on the rear inside wall of the upper cabinet) is wired to remote switches to facilitate limited remote operation of a siren station. In contrast to the Auxiliary Control Status Board, the Auxiliary Input Control Board does not offer feedback capabilities and is limited to the following remote activation commands:

  • Cancel
  • Digital Voice Messages 1 thru 4 Batteries - These components (located on the inside of the lower cabinet) provide the 28VDC necessary for the system to operate.

Battery Disconnect Switch - This component (located on the rear inside wall of the upper cabinet) allows all system batteries to be completely disconnected from the system. NOTE:

This switch does not disconnect the batteries from the battery charger or regulator.

Antenna Poly Phaser (optional) - This component suppresses high-voltage (static) charges that could be present on the antenna.

Page7

Antenna (optional) - This component (located on the utility pole) is capable of either receiving signals broadcast from the control center (one-way) or can both transmit and receive signals to and from the control center (two-way), depending how the system was ordered.

Solar Panel (optional) - This component (located on the utility pole) collects solar energy, converts it to electrical energy and delivers it to the Solar Regulator to maintain the station batteries at their proper voltage.

Strobe Control Board (optional) - This component (located on the rear inside wall of the upper cabinet) is a user-defined device that controls a pole-mounted strobe light. This light can be configured to activate during specific conditions (example: when any tone or message is generated).

Intrusion Alarm (optional) - This sensor (located on the door jam of the upper cabinet door) detects the opening of the cabinet door. If the station is equipped with this option , the alarm is configured to transmit a signal back to the control center.

Paging Interface (optional) - This component (located below the " Strobe Control Board" on the rear inside wall of the upper cabinet) is a user-defined device that serves as an interface between the siren cabinet and an existing, in-house public address system. This board has an output relay with a 1 Amp rated closure that can be used for a " Push To Talk" function.

Page 8

Section II: System Operations a) Remote Operations Remote operation of a WPS-2900 series siren involves transmitting signals from the control center to the desired station. This is accomplished by using either an encoder and transmitter or, if the station is so equipped, using an auxiliary control status board that has been wired to switches/con trols at the control center. Remote operation is beyon d the scope of this document and will therefore not be addressed. If your system is equipped with an encoder, please refer to the encoder operating manual for information regarding remote operation. If your station has been wired to use the auxiliary control status board , refer to the reference materials provided by the electrical engineer or installer.

b) Local Operations Local operation is accomplished through the control panel on the front of the station cabinet. The functions of these controls are as follows:

Cancel Abruptly stops siren tones without the normal "ramp down" found in several tones. Helpful in the event of an accidental tone activation.

Wail Produces a slow rise and fall tone.

Attack Produces a faster rise and fall tone (used for designated Civil Defense National Attack tone).

Alert A steady tone (Civil Defense alert).

Whoop A repetitive rise-only tone.

Hi-Low An alternating two-tone sound.

Air Horn A pulsing air horn sound.

SI TEST Initiates SI TEST tone and the optional diagnostic SI TEST routine.

Xmit Carrier Actuates remote station radio transmitter PTT circuit.

When tone squelch is used with the transmitter, the transmit function is used when adjusting tone squelch modulation.

Page 9

XmitAudio For use with remote station radio transceiver, causes transmission of DTMF tone via RF link for tone modulation adjustment.

Xmit Status Transmits station status information and battery voltage to the control center.

DVMTest Activates the Digital Voice Message (DVM) assigned to the test procedure in the configuration software.

Rotor CW No function with 2900-series equipment.

RotorCCW No function with 2900-series equipment.

Keypad Arm Enables local station operation via keypad. Once pressed, the keypad remains active until either a) another keypad button is pressed, orb) 60 seconds have elapsed, whichever comes first. The Keypad Arm button must be pressed each time a keypad button is to be pressed. Note that the Cancel button is always enabled and does not require Keypad Arm to be pressed.

Fig. 3: Station Control Panel Page 10

Section III: Understanding Station Addressing Every Siren Station in a given area code has its own, unique "Station Address". This address allows the user to select an individual or a group of stations. As stated elsewhere in this manual, a valid station address can be any number from 0000 to 9999. This allows for 10,000 unique addresses; a staggering number of stations to keep track of. Although it is logistically impossible to have that many stations in a single area code, it does illustrate the importance of a sensible, intuitive numbering convention for station addresses. This section will outline two types of conventions Central Point Source: Quadrant, Sector, Radial & Station Frequently, warning systems are used to notify the public of emergency situations that may occur from a single, centralized location. Typically, siren stations would be located throughout a 360° area surrounding this location for a specified distance from the source. In this scenario, the Central Point Source convention would be well suited.

For illustration purposes, assume the siren stations are installed within a 5 mile radius of the Central Point. As such, a Quadrant, Sector, Radial & Station numbering convention would allow the selection of any of the following:

  • any one of four sectors
  • any one of 5 radii within the sectors The area of coverage in this system , a circle, is divided into 4 quadrants. Each quadrant is then divided into 4 sectors. Each sector is further divided into 5 segments or radii emanating from the center of this siren system.

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3 2 3 2 QUADRANTS 1-4 QUADRANT SECTORS 4 ~ 1

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3~ 2 RADI I rND IVIDUAL STATIONS Page 11

In this system, a stations address is structured as follows:

Di2it Allocation 1 Quadrant (1 to 4) 2 Sector (1 to 4) 3 Radii (1 to 5) 4 Individual station within a radian Here are some sample activations to further illustrate this concept.

Sample 1:

A station with address 1354 would be located in:

Quadrant: 1 Sector: 3 of Quadrant 1 Radial: 5 Station: 4 If an operator selects station 1-3-5-4, only that station will be selected, as shown.

Fig. 5:

Single Station Selection SINGLE STATION SELECTION STATION 1354 Page 12

Sample 2:

If the activation of a group of remote stations within a whole segment of a radius within a quadrant and sector is desired, the fourth digit address is substituted with a " Wild Card",

the "#" pound sign.

An address selection of 1 4 - # would activate the system as follows:

Quadrant: 1 Sector: 3 of Quadrant 1 Radial: 4 Station: # All stations defined by above This selection is shown below.

Fig. 6:

Group Selection -

Radial Sector GROUP SELECTION-RADIAL SECTOR GROUP 134#

Page 13

Sample 3:

Selection of an entire sector can be accomplished by using the following address:

Quadrant: 1 Sector: 3 of Quadrant 1 Radial: # All radial 1 - 3 Station: # All stations defined by above In selecting a sector, the first two digits of the address are set for the sector address, for example 1 - 3 (Quadrant 1 - Sector 3). The third and fourth digits are substituted with a #

(Wild Card). Therefore, the address to select all stations in sector 1-3 is 1 # - #. This selection is represented below.

Fig. 7:

Group Selection -

Sub Sector I

GROUP SELECTION-SUB-SECTOR GROUP13##

Page 14

Sample 4:

The selection of a complete quadrant can be achieved by using the following address:

Quadrant: 1 Sector: # All sectors of Quadrant 1 Radial: # All radials in all sectors of Quadrant 1 Station: # All stations defined by above When selecting a quadrant, the first digit designates the Quadrant (1). the second, third and fourth digits are replaced with Wild Cards (#,#,#). Therefore, the address for selecting all stations in quadrant 1 is 1 - # - # - # as illustrated below.

Fig. 8:

Group Selection -

Quadrant GROUP SELECTION-QUADRANT GROUP###

Page 15

Sample 5:

All stations in a system may be accessed by using the Wild Card (#) for all address numbers.

The address would be# - # - # - #.

Quadrant: # All Quadrants Sector: # All sectors of all Quadrant Radial: # All radials of all sectors of all Quadrants Station: # All stations defined by above This "All Call" is illustrated as shown.

Fig. 9:

Group Selection -

All-Call GROUP SELECTION-"ALL-CALL" GROUP mt-##

Page 16

Governmental: County, City & Station For this next type of address structure, assume that the siren system in question is used primarily for tornado warnings throughout a major population center. This center encompasses three counties with each county having no more than ten cities. Two cities contain more than 50 high-power voice and siren stations.

The following represents a Governmental System 4-digit address configuration, allowing activation by " All Call", county group activations, city group activations and individual station activations:

X X X X

........... : ........... Individual Siren Station (00 - 99)
................................... City (0 - 9)*
............................................... County (0 - 9)
  • One digit could also be reserved for unincorporated areas.

An address of 2 4 - 5 would indicate the following individual station:

Siren Station 45, in City 5, in County 2.

The Wild Card (#) permits the use of several different types of group activations. Three samples follow:

Sample 1: County Activation (1 - # - # - #)

All Siren Stations in all Cities in County 1 will be activated by this transmission.

Sample 2: City Activation (1 # - #)

All Siren Stations in City 5 of County 1 will be activated by this transmission.

Sample 3: System All Call (# - # - # - #)

All Siren Stations in all Cities in all Counties will be activated by this transmission.

Page 17

Section IV: Troubleshooting Audio Loss If after activating the siren there is no audi~ output, perform the following procedure step by step. This procedure will require a digital multimeter.

I

1. Locate the Audio Presence LED on the controller board (see "Fig. 11: System LED Diagnostic Indicators" on page 29). When audio is present on the board, this LED will be on.
2. Activate the WAIL siren tone from the control panel on the siren cabinet. Confirm that the Audio Presence LED is on. If this LED is not on or if it turns off quickly, measure the battery voltage. The siren will not activate if battery voltage drops below 19 VDC. Be sure to measure the battery voltage at the same time you activate the siren. The batteries may show a good float roltage while they are not under load, but upon activation, the battery voltage may drop below 19 VDC if their capacity is low.

Note that when the siren shuts down and the load is removed from the batteries, the voltage may rapidly return to 25 VDC or more. If this condition is occurring, the batteries will need to be replaced. If the voltages are in the normal range, proceed to step 3.

3. Locate connector J2 on the control board. With your multimeter set to AC volts, measure across pins 6 and 7 (White with Oran*ge stripe and White with Brown stripe). With the siren tone running, 5 VAC should be present. I/no voltage is present, the controller hoard is probably at fault NOTE: Confirm that the au.dio presence LEI) is on whi.I_e performing these measurements. It indicates that the siren controller is still a~tivated. If the specified voltages are present, proceed to step 4.
4. With the siren tone still active, measure across pin 1 (Blue wire) and pin 2 (Black w/

White trace) on each of the siren amplifiers. 5 VAC should be present at each amplifier. If so, proceed to step 5. If no voltage is measured, this is indicitive of a wiring problem between the controller board and the siren amplifiers. Check the wiring between these components

5. Remove the Red siren driver lead frc>m each siren amplifier. Press "Cancel" on the control panel and then press "Wail". Measure across the output of each amplifier (White Weco connector) with the siren driver disconnected. 70 VAC should be measured. If this voltage level is measured, proceed to step 6. If this voltage level is not found and 5 VAC was measured at the input, proceed to step 7.
6. Set your meter to measure resistance at its lowest scale. Measure across each of the speaker drivers, making sure that at least one wire of each driver is removed from the power amplifier (or else the transformer in the amp is being measured as well).

Each driver should have a DC resistance of approximately 3 Ohms +/- .3 Ohms. If a resistance value outside of this range is found, contact factory.

Page 1~

7. Set your meter to measure DC Volts. Connect the negative lead of your meter to ground (one of the solid black wires in the multi-position connector on the amplifier is a good ground source). With a siren tone activated, measure the following wires for the following voltages (approximately):

Grey 6VDC Brown 5VDC Solid White (all) 24VDC AC Battery Charger The AC-powered battery charger has two charging modes: Equalization Mode and Float Charge Mode. The charger is in equalization mode when AC power is first applied; the charger will stay in equalization mode until the battery voltage reaches approximately 30VDC. Once the battery voltage reaches that point, the charger will switch to float voltage mode. In that mode it will charge the batteries to the appropriate voltage relative to the temperature of the batteries (25 to 29VDC).

The AC battery charger contains three circuit boards. The filter board contains a single, green LED, while two charging boards each contain a pair of LED's, one green and one yellow. This pair of LED's provides diagnostic information for the battery charger. The following chart defines their various diagnostic states.

Green LED Yellow LED Not Working Nonnal Condition Charger Operating Properly Equalization voltage mode OFF No AC voltage present Not Applicable ON AC voltage Is present Not Applicable Solar Regulator The following procedure can be performed to confirm proper operation of the solar regulator:

1. Disconnect the solar panel from the charger. With a DC voltmeter, measure the voltage across the wires coming from the solar panel. The voltage should be greater than 32 VDC (NOTE: The solar panel must be in direct sunlight).
2. Reconnect the solar panel to the charger. Monitor the battery voltage with the cabinet voltmeter. The float voltage will vary between 25 to 30 VDC, depending on battery temperature. When the solar regulator is charging, the DC LED on the circuit board will be on. During normal operation the charger will cycle on and off.

Page 19

The float voltage will vary with battery temperature. The following is a brief description of the nQrmal charging cycle:

If the float voltage for the current temperature of the batteries is 26 VDC, the regulator will turn on at 26 VDC (LED will come on) and it will charge the batteries to 28 VDC. Once the battery voltage reaches 28 VDC, the regulator will turn off (LED will go off), "and the battery voltage will be allowed to drop to 26 VDC. The cycle would then repeat itself. If the float voltage was 27 VDC, it would cycle from 27 VDC to 29 VDC.

  • When AC power is applied to the battery charger, the following voltages should ,be
  • measured on the wires coming off the charger:

Note: Refer to "Fig. la: Station Wiring Diagram (designations)" page 3.

Fig. 10:

Solar Regulator Connector GREY -+-+------ RED Pin-outs ORANGE -----+-+--+-++- -+-+---+--+----- WHITE

-++-----BLACK REAR VIEW OF PIN HOUSING Pin Position 1 RED - Battery Voltage to Ground (BLK wire in BC-1)

Note: Voltage present only when siren is powered up.; this is sourced from the siren motherboard Pin Position 2 WHITE - Charger output wires (25 to 31 VDC)

Pin Position 3 BLAGK - Charger output wires (25 to 31 VDC)

Pin Position 4 GREY - 19VDC from GREY to Ground (BLK wire in BC-1)

Pin Position 5 ORANGE - 5VDC from ORANGE to Ground (BLK wire in BC-1)

Pin Position 6 Not Used Page 20

Digital Voice

1. Remove all amplifier fuses.
2. Install an 8 ohm speaker at amplifier audio input connector pins 1 and 2 (Blue and Black w/White wires) in the 16 position connector.
3. Select a siren tone by pressing one of the controls on the front panel.
4. If the tone can be heard through the speaker, press the DVM-Test control to play the predesignated message.

Partial or Full Diagnostic Failure This procedure is to be used if the Partial or Full diagnostic LED (located on the controller board) indicates that a problem has been detected. A Partial indication means that at least one speaker and/or amplifier is operational. A Full indication means that all speakers and amplifiers are operational. NOTE: In order for a good Full indicator to be valid, a good Partial indicator must also be present).

1. Connect the SDPTS to the siren station via the com port on the front of the siren cabinet control panel.
2. Display the "Status" screen on the SDPTS.
3. Press the SI TEST control on the front control panel.
4. Each amplifier contains a red LED that is visible on the front of the control panel.

Note if all the LED's are on. Tap the "Update Status" button on the SDPTS and note which amp is displaying an error.

5. Open the front panel and swap the speaker driver wires from the amplifier that indicated a failure, with an amplifier with a lit LED. For example: if the LED for amplifier 1 is the only LED not on, install amplifier 1 speaker wires onto amplifier 2 and install amplifier 2 speaker wires onto amplifier 1. This will diagnose if it is the speaker or the amplifier that has failed. You may also measure the DC resistance of the speaker driver with your ohm meter. Be sure that the speaker driver wires are disconnected from the amp prior to measuring. A good driver will read 3 ohms+/.:. .3 ohms.

Page 21

Section V: Maintenance Although The WPS-2900 is of a dependable, solid-state design, periodic activation, field inspection and preventive maintenance is recommended to insure the maximum performance of each station.

Frequency of Testing and Activation A system of twice-monthly activation and confirmation, combined with a quarterly service and preventive maintenance is recommended to help insure the successful performance of a station. Increasing the frequency of testing will support and improve a station's test record.

Stations located in environ~entally adverse locations will require inspectio~ and preventive maintenance at more frequent intervals than just discussed.

IMPORTANT! STATIONS SHOULD ALWAYS BE INSPECTED IMMEDIATELY FOLLOWING SEVERE STORMS.

If a station is activated by remote control (landline or radio), the twice-monthly activation should be performed using_ the remote control link.

The twice-mon(hly activation of a station can be confirmed by several different methods, depending upon the options selected with each Whelen System.

Local Site Confirmation For a basic station activated at the cabinet, or by landline or radio, have, an observer confirm that the station activated audibly. The observer should report successful _as well as failed station tests. Station Performance Logs should be maintained. It is important to understand that audible confirmation alone is not assurance that the station is operating at 100% power. This requires inspecting the station in greater detail.

Stations 'may be optionally equipped with counters that advance upon radio or tone generator activation. These counters do not confirm 'total operation or the final expected output of an outdoor warning device. * '

If a* station is equipped with the "Status Display" option, full power station activation can be visually confirmed from outside the siren cabinet. This diagnostic display, located on the right side of the cabinet, will indicate the following:

(from left to right)

Red indicates the presence of AC power (if equipped with an AC Battery Charger)

Yellow indicates the presence of DC power at minimum operating level (at least 19VDC)

Red indicates partial amplifier/driver function G~n indicates full amplifier/driver function Red indicates rotor operation (WPS-4000 systems only)

Page 22

This diagnostic function is enabled by either a full power siren tone activation or by performing a SI TEST.

The same information is available on the control board LED numbers 4 - 8. The "Status" option is not required for the on-board LED's to function.

Following activation and observation, the results should be noted in the performance log.

Any indication of incomplete operation presented by the LED indicators should prompt IMMEDIATE service attention.

The system retains diagnostic information until cleared by a specific command.

The diagnostic information stored at the station, if not cleared, will update itself automatically with subsequent SI TEST or siren tone activations.

Remote Monitoring and Confirmation Stations equipped with the optional Whelen COMM/STATTM Command and Status Monitoring control, allow remote monitoring of status as well as confirmation of system activation. COMM/STAP:M returns the results of a remote station activation (both SI TEST@ and siren warning mode) in a DTMF encoded format via radio link.

Remote monitoring by RF link eliminates the necessity of physically visiting a station to confirm an activation.

Following the activation of a station, a "Status Request" may be sent to that station by DTMF encoded radio command. Diagnostic information is then presented to the status encoder at the station, converted into DTMF code and transmitted back to the control center, where one of several COMM/STATTM base station products will convert the DTMF code into meaning.fol inform~tion.

Quarterly Maintenance Devel9ping a quarterly inspection and preventive maintenance program for an outdoor warning station requires a thorough understanding of all the elements and .expectations of the system. The following section provides an overview and basic guideline for quarterly station inspection and preventive maintenance program for the sample station.

Page 23

Visual Siren Station Physical Inspection

  • Obsenre the speaker cluster, siren cabinet and AC Sernce for any signs of damage or loose mounting hardware (Some shrinkage of a newly treated utility pole may occur in the first several years following installation, requiring the tightening of mounting hardware.
  • Check all conduit for :watertight connection and entrance into the siren cabinet.
  • Inspect the AC Service for damage, blown fuses, degraded (corroded) power connections and integrity of the lightning arrestor.
  • Inspect the grounding system for AC Service, Siren Cabinet and pole top equipment.

Verify connections and acceptability of earth ground.

  • Observe the pole for any shifting and/or leaning. Poles that are not plumb will not properly direct alerting sounds.
  • Examine entire station for any signs of vandalism or forced entry.

Siren Cabinet and Components

  • Inspect AC Outlet, fuse and surge suppression equipment. Examine system for infiltration of foreign material(s), rodents, insects or other pests.
  • Inspect and, if necessary, clean all drain holes and vent screens.
  • Inspect battery terminal connections and clean if necessary. Re-apply silicone coating to battery terminals if necessary. Observe battery voltage with siren in inactive state (AC power must be on to s~ation, otherwise station must be powered up to obsenre meter).
  • Examine all wiring harnesses for chafing. Verify wiring terminations for tightness and wiring connections for proper electrical connections. Replace and correct any corroded or marginal connections. Inspect antenna for proper connection.

Speaker Assembly and Pole Top Equipment NOTE: Any examination of Pole Top equipment should be performed with the station audibly disabled.

  • Inspect speaker for blockage by rodents, pests, insects or other foreign material. Clean if necessary. Inspect any wiring cables or harnesses for chafing. Inspect the siren driver compartment for infiltration of foreign materials, rodents or pests. Clean if necessary.

Confirm that the driver compartment will allow for water or moisture drainage. Inspect speaker wiring connections for any sign of corrosion.

Page 24

  • Verify tightness of all mounting hardware.
  • Check all wiring terminations and connections.

Station Performance Testing NOTE: Depending on local conditions and station options selected, the station may be tested on or off line. Off line testing of the station involves disconnecting the speaker drivers from the siren amplifiers, so as not to disturb the public when verifying tone generator operation. A complete test must, however, include the testing of the siren amplifier operation. This can be accomplished inaudibly using the SI TEST command.

A basic routine, verifying the performance and operation of the sample station previously described, would be as follows:

1. Local and Remote Activation -

Activation of each remote station function by local control and remote control. With amplifiers on and off line as needed. An examination of each activation function will also facilitate a verification of related and subsequent system module activations and electrical connections that would be caused by an activation command. Also confirm function time outs (ex.: does the Alert signal time out at three minutes as per user

~pecification ?).

2. Response to Station Address and All Call address programming -

Control Center reception and activation on SI TEST or non-tone activation, for individual station address and All Call address selection.

3. Public Address -

With the station on line, activation of PA for both local and remote control, verifying PA Audio path and proper set up level of volume.

4. Siren Amplifiers -

Inspect for complete operation with speaker drivers (observe LED's).

5. SI TEST Station Analysis -

Observe and confirm diagnostic status of:

AC DC Partial Amplifier & Speaker Driver Operation {disable one amplifier to confirm this test). ,

Full Amplifier & Speaker Driver Operation NOTE: Verify AC drop out during SI TEST mode.

6. Battery Charger Operation -

Observe for proper charging operation.

Verify AC drop out in PA or SI TEST mode.

Page25

7. Batteries -

Verify voltage stability under load.

Perform a load test.

8. Status Encoder -

Perform a diagnostic SI TEST of the station.

Compare sta~s information with observations made locally at the station.

Disable one speaker and verify that the "Full" LED indicator is off.

Disable AC and verify that the "AC" LED indicator is off. _

Compare battery voltage return status with observed and measured battery voltage.

9. Transmitter-Check status encoder DTMF tone level modulation with transmitter.

Wide Band Narrow Band Wrth CTCSS 3.1 kHz dev1abon Wrth CTCSS 1 8 kHz deviation

' Without CTCSS 2.5 kHz deviation Without CTCSS 1.5 kHz deviation Check transmitter set up.

Verify power output and SWR.

NOTE:On concluding any examination of a station where connectors have been opened and closed, a final radio test by either SI TEST or full power should be performed and the results observed for a complete successful test. The PA audio path should alsf! be audibly verified by sending PA and broadcast a voice message.

The following is a sample form that may be used for quarterly inspection and maintenance.

Page 26

MAINTENANCE CHECK LIST Station #: _ _ _ __ Siren Address: _ _ _ _ _ _ _ _ _ _ _ _ __

Installation Date: ______ __

/ ....._ Inspection Date: _ _ _ _ _ _ _ _ _ _ _ __

Inspector: _ _ _ _ _ _ _ __

PHYSICAL INSPECTION:

OK NOTOK COMMENT Mounting Hardware Speaker Assembly AC Service Proper Grounding Solar Panels*

Antenna*

Conduit Connections Siren Case Assembly Batteries Components Secure Harnesses LOCAL OPERATIONAL TESTING:

Battery Voltage (Stand-by)

Battery Voltage (Under Load)

Manual Test:

Clear Wail Attack Alert Airhorn Hi/Low Whoop Clockwise Counter-Cloc),rnise SI TEST AC LED DC LED Partial LED Full LED Rotor LED Timer Set LED Audio Present LED Microphone Mic Volume

  • Optional Page 27

MAINTENANCE CHECK LIST (continued)

Radio*:

.QK NOTOK COMMENT Squelch Control Sensitivity Antenna Tuned*

Transmit LED Remote Activation:

Clear Wail Attack Alert Public Address Airhorn Hi/Low Whoop Wail/ 5 Sec.

All Call Speaker LEDs:

1 2

3 4

5 6

7 8

9 10 Status:

AC DC Partial Full Status Request Intrusion*

  • Optional Page28

Fig. 11: System LED Diagnostic Indicators, 0 P1 J6 0 j<ID <ID <ID[ 9POS 'O" 0

RJ45.JACK 0 0 0 JT J1 REMOTEAl..010 MIC JACK (FOR USE ONLY (POR USE ONLY l',f11f /IIOSCAD) wrTH lfOSCAD} 0 J21 RS232 / RJ45 J2 Front Panel Swrtch Membrane Audra Presence (RED)- Normally off This G)

CD LED WIii lrght when an audro SJgnai IS Parbal - Normally ori. If all siren amphfiers do not operate property dunng present on the board a tone actJval!on or SI TEST, thlS LED wrll be off If at least one amplrfler operates PTT - Normally off Tors LED will lrght when proper1y, rt wiU remarn on.

the stabon transmrtter IS active Full - Normally on If a siren amplifier does not operate properly dunng a tone aciJvatlon Squelch - Normally off. Ths LED wrll lrght or SI TEST, thrs LED will be off.

when the stabori is reC8!Vfng a radro broadcast If equrpped with the optional rece1ve tone/squelch tone, the LED WIii

@ Rotator - Tors LED wtll llght dunng srren actlvatlon tf the rotor osaliates properly only bght when the r9C8lve frequency and sub-audrble torie squelch frequency tone rs detected Acbve - This LED normally flashes at a rate of once every half seconds When a problem has been detected, thrs LED AC - Normally ori. If no DC voltage was will stop flashing or be off Also rndrcates detected during a SJren tone or SI TEST, receipt of DTMF data by flashing at a

!hrs LED will be off. faster rate for about 1 second DC - Normally on If no DC voltage was detected dunng a Siren tone or SI TEST, Fault (RED) - Normally off When a problem has been detected, ttus LED ROTOR thlS LED WIii be off will be on.

NOTE: In some Instances, optional circuit boarm may be located dlract/y above th&Se LED's.

CHARGER REMOTE STATUS INTRUSION AUXCS SPARE L.JGHTS STROBE 0 0 Page 29

Fig. 12: Control Board Wire Colors f>1 J5 0 0 J(]I) (]I) (]I) r BPOS "O" RJ46.JN::Y. 0 0 RADlO 0 0 iT J1 RBIOTE.lJJDIO MIC JN::i<.

0

, BATTERES

~

J21 "I RS232 /RJ45 NOTE: Some older systems 1 WHT/ORN use connectors that wlll not 2WHTIORN J2 properly Interface with the 3WHT/ORN 4WHTIGRN followlng connectors on SWHT/ORN 8WHT/ORN replacement control boards* TWHT/GRN

  • J14 (Batteries) 1 ORO 2Ya
  • J 15 (Charger) 30RN 4BUJ 6V\0 PWRPMPS If the exlsting connector does 1-5 SWHTIBRN TWHT/ORG not connect to the new board 8 WHTIBI.K 9 WHT/YEl.

so that the wires are oriented 10WH17GRN as shown, contact Whelen prior to connecting any wires 0 11WHT/BI.U to the board.

.... ~ 10RG 2Ya 3GRN 4BlU

, I PWR/>Jlf'S 6-10 SVIO 8WHTIBRN

~~~~~i TWHT/ORO 8 WlfT/BU(

.-,:,,jP,;,ranCI OWHTIYEL 1 I.° a a c 1

IJ10 10WHTIGRN 11 WHT/BLU DIGITAL VOICE 1 RED 2BRN 30RG 4YEI..

6GRN 6BW ROTOR TORY

!WHT OWHT/B\.K 10WHT/Rell 11 WHTIORG 12 BU<

00 10RG 2REO a-tARGm 3 BU(

4GRY 00000 REMOTE STATUS 0 00 AUXCS SPARE LIGHTS STROBE 1 0 Page30

APPENDIX E Siren Test Result Report

/

Results from Near and Far-Field Tests of the Outdoor Warning System Near Arkansas Nuclear One 25 Sept 2020 FINAL REPORT Prepared by:

Bruce J. lkelheimer, Ph.D.

Acoustic Analytics Asheville, NC

Project Summary Acoustic Analytics was contracted by KLD Engineering, P.C. (KLD) to help perform near-field and far-field acoustical tests of Arkansas Nuclear One's (ANO) outdoor warning system. Testing was conducted on July 23 rd and July 24 th

  • 2020_. During thclt period two types of tests were conducted.

The first were near-field ANSI 512.14 tests designed to accurately ascertain the output levels of the sirens. The other, far-field tests were conducted simultaneously to the ANSI 512.14 tests and measured the received sound level in the community, thousands of feet away from the siren. For all tests, the sirens were sounded for one minute, with background noise data collected before and after ea~h sounding at all locations. Seven sirens we_re tested in total, with two Whelen Model WPS2807 sirens and five Whelen Model WPS2907 sirens. All sirens have a pure tone alert signa.I with a frequency of about 560 Hz.

The ANSI 512.14 measurements were performed using a microphone raised to the height of the siren (approximately 50 feet above ground) with a bucket truck. The microphone was positioned 100 feet from the siren and moved slowly during the test. Once all seven sirens were tested, data from similar siren types were combined to determine the expected output for each siren type, displayed in Table 1. In this table, the 'Maximum Level' is the single highest one-second sample, and the 'Average Level' is the arithmetic average of all the one-second samples collected during the siren sounding (about 60 in total). All values are reported using C-weighted values as per FEMA guidelines 1 . More details about C-weighting can be found in Appendix A.

Table 1. ANSI S12.14 final test results Maximum Level Average*Lev'el Sire!'!

(dBC) (dBC)

WPS2907 119.0 115.5 WPS2&J7 118.6 115.1 For the far-field tests, sound level meters were set to collect data for at least ten minutes before the sirens sounded and continued collecting data for at least ten minutes after the sirens stopped.

  • Meter placement was selected to provide safe, accessible locations for the testers in positions that were expected to have low background noise levels. They were also located in places that initial modeling (based on manufacturer data) predicted would receive siren levels up to 70 dBC. One meter failed to collect any data for two of the tests and in four instances the tests collected unexpectedly high levels of background noise. The rest of the meters collected valid data. The results showed that, for the fifteen valid data points collected, four reported received maximum siren levels above 70 dBC, with the rest report1ng levels below 70 dBC.

1 FEMAsREP-10, "Guide for the Evaluation of Alert and Notlflcatlon Systems for Nuclear Power PlantsH, November 1985.

Testing Procedure Acoustic Analytics and KLD collected acoustic data from seven sirens around ANO, with two different types of tests. The first was a near-field ANSI S12.14 test to ascertain the output level of the sirens, and the second was a far-field test to confirm received sound levels in the surrounding community.

Near-Field ANSI 512.14 Test Procedure The ANSI S12.14 standard defines the method for testing omni-directional sirens. The siren sound measurements are performed using a microphone raised to the height of the siren, positioned 100 feet from the siren. KLD provided all of the acoustical testing equipment for this test and Entergy provided a lift truck capable of reaching the required height for the test.

All of the acoustical data were collected using Larson Davis 831 Sound Level Meters 2 (SLM). The SLMs were programmed to record acoustical data at one-second intervals, collecting slow C-weighted sound levels and one-third octave band levels. Each SLM had its calibration checked before and after each test, with at least 30 seconds of calibration tone recorded between each test.

The siren sounding lasted for one minute for each test.

In addition to the elevated microphone extended from the bucket truck, an additional microphone was calibrated and used to determine the maximum sound level experienced on the ground. This measurement was conducted by walking an SLM radially outward from the siren pole during the siren test. Distance from the pole was recorded along with the maximum sound level. This measurement is performed to ensure that the sound levels received at the ground do not exceed recommendations from the Committee on Hearing, Bioacoustics, and Biomechanics of the National Academy of Sciences. These recommendations suggest that no person should be subjected to sound levels above 123 dBC 3

  • Weather data were measured locally during the siren tests with a Kestrel Model 4500 Weather Meter. This weather meter is capable of recording wind speed, direction, temperature, and relative humidity. For each siren test, the weather meter was positioned close to the siren, mounted approximately 5 feet above ground level. Results from these measurements are recorded on the ANSI S12.14 datasheets.

Far-Field siren sound test procedure The testing methodology used to measure the far-field siren sound closely follow the ANSI Standard S12.9 Part 34

  • This is the governing standard for collecting data from a specific source such as the sound from an outdoor warning system.

2 Larson Davis, "Model 831 Sound Level Meter Operation Manual", 2006.

3 FEMA CPG 1-17, "Outdoor Warning Systems Guide", 1980 4

ANSI $12.9 Part 3 (R2008), "Quantities and Procedures for Descriptions and Measurement of Environmental Sounds.

Part 3: Short-term measurements with an observer present", 2008

For these tests, Larson Davis 831 SLMs were used to collect the acoustic data and Kestrel 5500 Weather Meters were used to collect the weather data. For each measurement location, the SLM was mounted on a tripod with the r:nicrophone approximately 5 feet above the ground. The SLMs were programmed to record acoustical data at one-second intervals, collecting slow C-weighted .

sound levels and one-third octave band levels. Each SLM had its calibration checked before and after each test, with at least 30 seconds of calibration tone recorded between each test. The weather stations were mounted on a tripod close to the SLM and programmed to collect the wind speed, direction, temperature, and relative humidity during the test. The siren sounding lasted for one minute for each test.

The observers present recorded the position of the meters relative to all major features, including building and changes in the local terrain. The observers also collected notes during the tests, identifying specific noise or weather events that occurred during the testing. Weather conditions during the test were written down, as were the observed sound levels before, during, and after the sirens sounded: Any significant sounds noticed during the test were also written down. The meters were set to begin recording at least ten minutes before the siren sounding and were left running for at least ten minutes after the siren test ended to collect background noise levels. These procedures were h~nded out to all test participants, and a copy is provided in Appendix B.

Frequency Analysis Frequency analysis of the siren signal is a useful tool in the system analysis. One of the SLMs used for the ANSI S12.14 test had the capability of recording high-quality audio file samples. These audio files were then analyzed using the analysis software, Audacity5

  • This software performs a Fast Fourier Tran_sforr:n on the audio signal to determine the frequency content. Figure 1 has a sample frequency spectra for the siren signal as measured from the bucket truck, 100 feet from siren 3~4.

In this plot, the frequency is on a logarithmic scale on the x-axis, and the amplitude is in dB is on the y-axis. Note that they-axes on this plot is not calibrated, but is useful in determining where the maximum frequency occurs. All sirens measured has the same frequency content, with a maximum level at approximately 560 Hz indicative of a pure tone signal.

5 https://www.audac1tyteam.org/

-25dB

-30d8*

-33d8*

-36dB--

-39dB *

-42dB *

-45d8*

-48dB--

-51d8*

-54d8 *

-57d8*

-60dB--

-63dB *

-66d8*

-69d8*

-72dB--

-75dB *

-78d8*

-81dB*

-87d8 *

-90dB 2.00Hz 4.00Hz 6.30Hz 10.00Hz 20.00Hz 40.00Hz 100.00Hz 200.00Hz 400.00Hz 1000.00Hz 2000.00Hz Curso9 560 Hz (05) =-36 dB jPeak:J559 Hz (C-s) =-25.8 dB Figure 1. Frequency spectra of the Federal Signal 2001-130 siren as measured in the field Another method of analyzing the frequency content of the siren sounds is to look at the One-Third Octave Bands collected by the SLMs. One-Third Octave Band analysis divides the sound into individual frequency bands, with three bands to every octave (or doubling of frequency). Since the frequency of these sirens is approximately 560 Hz, that falls between the 500 Hz and 630 Hz One-Third Octave Bands. This can be seen in the plots of the One-Third Octave Band spectra in Figure 2 with the two peaks at the appropriate frequencies. In this figure, the frequency is on the x-axis, plotted logarithmically, and the amplitude of the siren signal is on the y-axis in dB. In this plot they-axis is from calibrated data, so the values are accurate .

120 Siren tone at about 560 Hz - - -~

110 100 90 80 60 50 40

,o 20 IIIIIIIIIIIIIIII One Third Octave Band Figure 2. One third octave band spectra for the Whelen WPS2907 Siren Test Results Seven different sirens were measured over two days, with three sirens measured on June 23 rd ,

2020 and four measured on June 24th, 2020. At each siren, a bucket truck was used to complete the ANSI S12.14 measurement. Results from all of these tests are provided below in Table 2.

Simultaneously, three SLMs were placed in the far-field for each test, identified as ANO 01, ANO 02, and ANO 03. These locations were selected close to the estimated 70 dBC sound contour from each siren (based on initial manufacturer data). The tabulated results from these tests are provided in Table 3. For Table 2 and Table 3, the 'Maximum Level' is the single highest one-second sample collected during the test and the 'Average Level' is the arithmetic average of all one-second samples during a siren sounding (approximately 60 in all). The 'LlO Level' on Table 3 is the top 10th percentile of the data. This means that the received sound level was at that level or higher for 10 percent of the siren sounding, or approximately 6 seconds.

When reporting the data from the far-field meters, Acoustic Analytics has plotted two different acoustic metrics. The first is the C-weighted value. However, because of the way that the (-

weighted levels are computed they often include elements that have nothing to do with the siren signal itself. Therefore, the combined 500 Hz and 630 Hz One-Third Octave Bands were also computed. This will often clearly show the siren signal even when the C-weight does not. The

combined value is much better at accurately representing the received output from the siren at these far-field locations and this is the value reported on Table 3.

To be certain that a measured signal is attributable to a siren (as opposed to just some other background noise), the measured signal must be at least 10 dB above the background noise. If the siren signal is not 10 dB above the background noise, the received siren level can only be estimated. For these situations, the level is denoted by the less-than symbol(<) to show that the siren signal is less than the value provided on the table. Th is happened to 4 measurements as shown in Table 3. More details about each siren test, including data collection sheets, ANSI 512.14 sheets, and graphs of the acoustic time histories for the collected data are provided in the next section.

Table 2. Results from all ANSI S12.14 tests Maximum Level Average Level Siren Model (dBC} (dBC) 2Z14 WPS2907 116.6 113.1 lZll WPS2907 118.5 114.3 1Z9

  • WPS2807 110.7 107.4 SZ2 WPS2807 118.6 115.1 3Z4 WPS2907 120.3 116.9 3ZS WPS2907 119.2 116.1 2Z13 WPS2907 120.3 117.2
  • Siren 1Z9 had lower than expected output levels.

Table 3. Far-field Test Results Siren 2214 Siren 1211 Maximum Level LlO Level Average Level Maximum Level LlO Level Average Level Meter Meter (dB) (dB) (dB) (dB) (dB) (dB)

ANO0l 58.2 55.4 52.1 ANO0l <67 <49 <45 ANO02 73.7 67.4 61.8 ANO02 67.4 64.4 58.6 ANO03 72.7 68.6 61.6 ANO03 < 59 <57 <53 Siren 129 Siren 522 Maximum Level LlOlevel Average Level Maximum Level LlO Level Average Level Meter Meter (dB) (dB) (dB) (dB) (dB) (dB)

ANO0l - - - ANO0l 58.7 57.5 52.7 ANO02 58.6 56.5 52.1 ANO02 77.1 75.5 70.2 ANO 03 70.1 68.8 61.6 ANO03 67.9 66.3 62.3 Siren 324 Siren 325 Maximum Level LlO Level Average Level Maximum Level LlO Level Average Level Meter Meter (dB) (dB) (dB) (dB) (dB) (dB)

ANO0l 69.7 68.1 63.6 ANO0l - - -

ANO02 66.7 65.3 60.6 ANO 02 59.5 54.3 52.1 ANO 03 47.8 46.5 43.9 ANO03 61.0 58.6 55.1 Siren 2213 Maximum Level LlOLevel Average Level Meter (dB) (dB) (dB)

ANO0l <72 <69 <65 ANO02 60.7 59.1 56.3 ANO03 <53 <52 <50 Summary Acoustic Analytics, with the help of KLD and Entergy, conducted a successful acoustical test of the full outdoor warning system for the ANO outdoor warning system over the two day period from June 23 rd to June 24th 2020. Data were collected from seven different sirens representing two different models. Weather conditions during the test were good, with low winds and no precipitation as measured by weather stations used duing the testing. Five SLMs were used for each siren test. Two SLM was used for near-field ANSI S12.14 measurements and three SLMs were used for far-field measurements. Of the 35 different sets of acoustical data collected over the week, two samples were lost due to equipment malfunction and four experienced elevated background noise levels that made it impossible to determinine the siren level.

Bruce lkelheimer, President of Acoustic Analytics

Detailed Data from All Field Measurements This section contains all of the detailed data from the field measurements including graphs, photos, and data sheets. It is useful as a reference for looking at specific siren tests. The data is organized by siren, with the ANSI S12.14 test provided first, followed by the data collected by the far-field SLMs. They are also provided in the order that the testing occurred. Table 4 provi des the date, siren, and GPS location for all of the far-field test locations, with more information provided in each section.

Table 4. Date and locat ion of far-field measurements June 23rd, 2020 Siren 2214, Model Whelen WPS2907 Siren 1211, Model Whelen WPS2907 Meter ID Latitude Longitude Meter ID Latitude Longitude ANO0l 35.323279 -93.141710 ANO0l 35.242431 -93.157977 ANO02 35.304833 -93. 119475 ANO02 35.236126 -93.189973 ANO03 35.304651 -93.128141 ANO03 35.223787 -93.165692 Siren 129, Model Whelen WPS2807 Meter ID Latitude Longitude ANO0l 35.258326 -93.230217 ANO02 35.250495 -93.207652 ANO03 35.257309 -93.203675 June 24th, 2020 Siren 522, Model Whelen WPS2807 Siren 324, Model Whelen WPS2907 Meter ID Latitude Longitude Meter ID Latitude Longitude ANO0l 35.306951 -93.289443 ANOOl 35.333159 -93.245631 ANO02 35.296799 -93.274475 ANO02 35.324876 -93.261671 ANO03 35.287405 -93.294007 ANO03 35.306421 -93.246369 Siren 325, Model Whelen WPS2907 Siren 2213, Model Whelen WPS2907 Meter ID Latitude Longitude Meter ID Latitude Longitude ANO0l 35.324739 -93.273720 ANO0l 35.305384 -93. 148826 ANO02 35.324037 -93.244078 ANO02 35.306214 -93.122389 ANO03 35.345280 -93.258734 ANO03 35.313796 -93.135871

Field Measurements of Siren 2214 Siren 2214, a Whelen model WPS2907 siren, was measured on June 23 rd , 2020 at approximately 9:50 am. This siren is located across the street from the Darby Lane Baptist Church in Russelville, AR. This siren is mounted on top of an approximately 50 foot wooden pole. Far-field SLM ANO 01 was placed to the north-west of the siren and SLMs 02 and 03 were placed south-east and south of the siren, respectively. This is shown below in Figure 3. The ANSI S12.14 data sheet form this test is provided in Figure 4, with a photo of the siren in Figure 5 and the time history of the measured sound level in Figure 6.

Figure 3. Position of siren 2214 relative to the far-field SLMs

Siren Sound Output Measurement per ANSI S12.14 Data Sheet Siren Mfg: Whelen Modal No: WPS2907 SIN:-----

==

Description:==

In situ measurement of ANO siren 2Z14 Meas. Loe. Across the road from a church along the side of a road Date: 6/23/20 Tlme: 9:50 am ev: Bruce I. Tille: _ _ _ _ _ _ __

Temp jg_ °F Wind speed: 5.6 mph Wind Dir: 320 Clouds 100  % Precip. (YIN)? __N Elevation Sbleh of TNI SI..

100Feet SO Feet Grass Mfg rec'd mtg. height: ....22.... feet Acklal height: ...aL leet Method: Laser Power correct <Y"')? _ __

Ground type & cover between ann anct meas. 1oc. _G......,ra ...s..,.s_ _ _ _ _ _ _ __

Deviations from test procedure: _N_o_n_e____________________

SLM Mg: _____l __

D__ Model No: __8_3__1__ SIN 3174 Pri Cal Dale:. 3/11/20 Filler Mfg: _ _ _ _ Model No: _ __ SIN _ _ _ _ __

Pri Cal Dale:.

Calib Mtg: _l_O__ Model No: ca1200 SIN 15674 Pri Cal Da1e: .6/19/20 Field Calibration: Before _____ 9__4__.0____

d__B__

C_ _ Affer 94.0 dBC Max ambient: Before 60 dBC slow Attar 57 dBC slow Microphone SN: 311593 Preamp SN: 51309 Base Line Position Secondary Position

~

Siren Sound: Alert Alert MXSCL (max d8C. slow): 116.6 Average SCL, dBC slow: 113.1 Max 1/3 octave band, Hz: 500 Hz & 630 Hz MXSCL in max 1/3 octave band, dBC slow: 116.5 Average SCL in max 1/3 octave band, dBC slow: 112.8 Bystander MXSCL. dBC slow 111 xxx Dist of bystander MXSCL from mount. feet 53 xxx Other pertinent information: _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ __

Figure 4. ANSI S12.14 Data Sheet for Siren 2214

im;~~--*W.MID.©W~~'i/@QJijll

-~ [oJl!f.112,!;J11(Mj ,- wi-Figure 5. Photo from the bucket truck, looking at siren 2214 130.0

- Measured Siren Level

- - - Average Siren Level 120.0 110.0 100.0 u 90.0 a:,

~

"ii

> 80.0

~

70.0 60.0 50.0 40.0 9:43:45AM 9:44:lSAM 9 :44 :45AM 9:45:lSAM 9:45:4SAM Time Figure 6. Time history of the received sound from siren 2214 as measured from the bucket truck

Far-Field Measurement of Siren 2214 from So und Leve Meter ANO 01 SLM ANO 01 was placed by the water in Pleasant View Park. Figure 7 shows the time history for siren 2214, with the siren signal clearly evident above the background noise by at least 10 dB in the combined 500 Hz and 630 Hz signal. Background noise levels in this area were in the 55 dBC to 58 dB range . Figure 8 has the data collection sheet for this meter.

100.0

- - - C-Weight

- 500 Hz+ 630 Hz 90.0 80.0

-<-- Siren Signal 70.0 I

I I

iii

~ 60.0 qj 50.0 40.0 30.0 20.0 9:42:00AM 9:43:00AM 9:44:00AM 9:45:00AM 9:46:00AM 9:47:00AM Time Figure 7. Time history from SLM ANO 01 for siren 2Z14

ANO Si ren Test Datasheet

ro be fllled by support ~

Date: w~~/"ttJ Time: ~ S'O fr4" SLM Modef: t.-1) S:31 SLM Serial Number: 3 $:$:9 Preamp SN: <) 8 S-0 b Microphone SN: "3 I OD 8 Ll Tester's Name: D'",o~c 11, tY1~1Jao GPS Coordinates: -P\3 *\fr, I West ~f.Y~)}:zq North Checked Battery? @ No Checked Clock? ~ No Memo,y Checked? ~ No Calibration le"81 before teat: 0\ f

  • 0 dBC 30 second calibration tone ~ bJ1fOf9 test? ~ No Calibration level after test: ~~ dBC _

30 second calibration tone recorded after test? (fe, No Calibrator Model: C#-1 )o O Callfntor SN: __t;....',";...._&....iJ_+-_ __

- - - - - - - - - T o be filled In be by the netd crew et the site---------

Plan View \

,....._ (<:an also use proylded map b:>me

~~~-( ~

r, vef Figure 8. Data collection sheet for SLM ANO 01 for siren 2214

Far-Field Measurement of Siren 2Zl4 from Sound Leve Meter ANO 02 SLM ANO 02 was placed by the side of Sparksfor Dr. south of its intersection with E. Aspen Ln.

Figure 9 shows the time history for siren 2214. Here the combined 500 Hz and 630 Hz siren signal is clearly evident above the background noise by over 10 dB. Also evident in this time history are the passing of cars - shown as sudden spikes in the received noise level. Figure 10 shows the data collection sheet for this test.

100.0

- - - C-WeJeht

- 500 Hz+ 630 Hz 90.0 Siren Signal 80.0 70.0 I

,,', ~

iii"

!:!. 60.0 i', I

~:*.,.,,' \.

\ ~

"ii 50.0 40.0 30.0 20.0 9 :42 :00AM 9 :43 :00AM 9:44:00AM 9:45 :00AM 9:46:00AM 9:47:00AM Time Figure 9. Time history from SLM ANO 02 for siren 2214

ANO Siren Test Datasheet

-~!'9'7r---7..------To be filled by support ltaff- - - - - - - - -

Oate: _ _ _~....~-).._).Q____ Time: '] ~CO f"'

SLM Model: ~ D 8 '3 I SLM Serial Number: '33C) 7 Preamp SN: 5 I } :t e Microphone SN: 3 o7 72 k Tester's Name: .&+f..._t_CJy~<11\....d"'-r'---- - - - - - - - - - - - - - -

GPS Coordinates:_'l_~_.__ 1;p ________ Weat __-q _____~__.__1__1._____ North Checked Battery? ~ No Cheeked Clock? ~ No Memory Checked? ~ No Calibration level before test: '\ *':14-*O dBC 30 second calibration tone recorded before test? Q No Calibration level after test: f:

  • Ci\ f dBC 30 second calibration tone recorded after test? & No Calibrator Model: ~, }DO Calibrator SN: _ _l_~_~._7._+ ____

- - - - - - - - - : r o b e n11ed In be i,y the field aew at the site---------

Location Drawi

.------------------ Plan View


~ Major Elevation Changea (C.n also use provided map to martc locatlOn)

Measurement Location description: .. O'-f'pb~-O~i...d---=.-"...,:._-s,f,,l,.,=~a..;t'_.r.;.,;f,&lc/.....;.,.P..;;..r_ _....,.._ __

Microphone height:c t : ft. VYind Dir: N\A/ 31'2. deg.

Photos Taken? No VYind Spd: _<_.1__ mph Meter Recording? Y No Temp* f'( ,q *F Weather Station on and wind cover removed? ~ No Ambient noise level before test: _ _~_,_._'\______ dBC ~

Maximum level observed duri~the tNt: ,., dBC ""'i'"" 0,,- ~ 'ti Could you hear the sirens? (!!] No Ambient noise level after test: 6g dBC Notes about test (including background noise and noise intrusions during the test):

Tester's Signature: ---i~l'Jill---~------------------

Figure 10. Data collection sheet for SLM ANO 02 for siren 2214

Far-Field Measurement of Siren 2Z14 from Sound Leve Meter ANO 03 SLM ANO 03 was placed by the side of Steel City Ln, about halfway down the road . Figure 11 shows the time history, with the combined 500 Hz and 630 Hz siren signal is clearly visible above the background noise. Background noise before and after the test was approximately 65 dBC. The data sheet for this test is shown in Figure 12.

100.0

- - - C-Welght

- 500 Hz + 630 Hz 90.0

_ . . _ Siren Signal -

80.0 70.0 ii .,\ /

~ 60.0 "ii QI 50.0 40.0 30.0 20.0 9:42:00AM 9:43:00AM 9:44:00AM 9:45 :00AM 9:46:00 AM 9:47 :00AM Time Figure 11. Time history from SLM ANO 03 for siren 2Z14

ANO Siren Test Datasheet Date: g>>-L :::= to To be nlled by support:::

Time: __:1.{_;......._

!{1C

..,,.,,..""'1.....,.._ _ __

SLM Model: r() 3 31

\ , I 3 '2 SLM Serial Num~ 4: ). 7 f Preamp SN: Microphone SN: 3c, 7 3 'J b Tester's Name: -(b.:M:%~ £A~\ "3 ,et,\'1:;

GPS Coordinates: 'i .3,Jl'.}18fJ1 West 1-¢. +K 14'~ North Checked Battery? ?fij No -q3, Id i\41 \..I , , . , o .+ b'> I "1 Checked Clock? ~ No Memory Checked? Y-!I No Calibration level before test: °14- dBC 30 second calibration tone recorded before test? y§i No Calibration level after test: q4, / dBC 30 second calibration tone recorded after tnt? '@) No Calibrator Model: Cc..l ~o Calibrator SN: _('l_lo...;.7_.4-_ _ __

- - - - - - - - - - T o be nned In be by the netd crew at the Sit---------

Location Drawi

......-------------- Plan View Major Elevation Changu cc.n also use provided map to mark IOcatlon)

Ye:~ LI'-

~

~

,, f

~

~

V\

Measurement Location description:

Microphone height:  ?,O ft.

toot@~'!{: Et In Dir:

L S't<Jt!Ls~L-..

~ZS' deg.

Photos Taken? &;) No VVlnd Spd:  ? ,4 mph Meter Recording? Yea No Temp: f,4 .o *F Weather Station on and wind cover removed? Q N o Ambient noise level before test: U, dBC Maximum level obMrved during the t*t: 1:3, *"l: dBC Could you hear the sirens? ~ No Ambient noise level after test:

  • h 4 dBC

~ ~b:\~J~~~~nd~~ ~ ~ ~ t t r ~ > = w r ~t.

Tester's Signature: ' ) \w.n.t".'\ :')\M\

Figure 12. Data co llection sheet for SLM ANO 03 for siren 2214

Field Measurements of Siren lZll Siren 1211, a Whelen model WPS2907 siren, was measured on June 23 rd , 2020 at approximately 10:50 am. This siren is located by the corner of N. 2nd St. and East St. in Oardenelle, AR. This siren is mounted on top of an approximately SO foot wooden pole . Far-field SLM ANO 01 was placed to the north-east of the siren, SLMs 02 was placed to the west of the siren, and 03 was placed south-east of the siren . This is shown below in Figure 13. The ANSI S12.14 data sheet for this test is shown in Figure 14, with a photo of the siren in Figure 15 and the measured time history of the test in Figure 16.

Figure 13 Position of siren 1211 relative to the far-field SLMs

Siren Sound Output Measurement per ANSI S12.14 Data Sheet Siren Mfg: Whelen Modal No: WPS2907 SIN: _ _ _ _ __

==

Description:==

In situ measurement of ANO siren 1211 Meas. Loe. Measurement is across a small road from the siren, close to a da care facili Data: 6 23 20 Time: 10:50 am 8'f: Bruce I.

Title:

Temp M_ °F Wind speed: ...Q__"1)h Wind Dir:_:__ Clouds 100  % Precip. (YIN)? _.N....___

Elevation Slceleh of TNI SIie 100 Feet 50 Feet Grass Grass Mfg rec'd mtg. height: _2Q_ feet Actual height: -2,L laet Method: Laser Power COO'eCt (Y,1>-0? _ __

Gr0IAld type & cowr between siren and meas. loc.

Deviations trom teat prooedure: _N_o_n_e____________________

Grass and asphalt SLM t.tg: ___L=D__ Model No: ....,8.,.3..,l_ _ SIN 3174 SIN _ _ _ _ __

Pri Cal Oata:.3/11/20 Filtar Mfg:____ Model No: _ _ __ Pri Cal Date:

eub Mtg: _Lo___ Model No: ca1200 SIN 1S674 Pri Cal o.::6/19/20 Field Calibration: Before _ _ _ 9..,3.,.,9.,_d.,B.._c_ __ After 94.o dee Max ambient: Before _ _ ____... 6 .._5_ _ dBC slow After 65 dBCslow Microphone SN: 311593 Preamp SN: 51309 Base Line Position Secondary PoatiQn JiUlllsa Siren Sound: Alert Aled MXSCL (max dBC, slow): 118.5 Awrage SCL. dBC &low: 114.3 Max 1/3 octave band, Hz: 500 Hz & 630 Hz MXSCL In max 1J3 octave band, dSC slow: 118.S Awrage SCL in max 1/3 octave band, dBC slow: 114.2 Bystander MXSCL. dBC slow 113 xxx Dist of bystander MXSCL from mooot, feet 92' and 35' xxx Otherperlinent inf0ffl'l8tion: _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ __

Figure 14 ANSI S12.14 Data Sheet for Siren 1211

~~'iiblil5ll'im..!lm l~~ in~*

~~/~U~ni~

~~~~

~~

~~~ ~

~~~

~~~

si Figure 15. Photo from the bucket truck, looking at siren 1211 130.0

- Measured Siren Level

- - - Average Siren Level 120.0 110.0 100.0 90.0 i~

1 80.0

~

70.0 60.0 50.0 40.0 11:09:45AM 11:10:lSAM 11:10:45AM 11:11:lSAM 11:11:45AM Time Figure 16. Time history of the received sound from siren 1Z11 as measured from the bucket truck

Far-Field Measurement of Siren 1Z11 from Sound Leve Meter ANO 01 SLM ANO 01 was placed close to a boat ramp at the end of Old Post Park Rd. The time history from this measurement is shown in Figure 17. In this case there is no evidence of the siren in the C-weight, while it does appear that there is siren signal in the 500 Hz and 630 Hz signal. However, because that level is not consistently 10 dB above the background, it is not possible to determine what portion of that signal comes from the siren and what is from the background noise. The data sheet for this test is shown in Figure 18.

100.0

- - - 500 Hz + 630 Hz

- C-Weight 90.0 80.0 Probable

,... _ Siren Signal ~

70.0 ii"

!:?. 60.0

"'ii

~

50.0 40.0 30.0 20.0 11:08:00 AM 11:09:00 AM 11:10:00AM 11:11:00AM 11:12:00AM 11:13:00AM Time Figure 17. Time history from SML ANO 01 for siren 1211

ANO Siren Test Datasheet

7. To be filled by support~

Date: pl?- '313.D Time: 10:00 o.~

SLM Model: kl) r ~ i SLM Serial Number: >S~g Preamp SN: S: 8 S- o b Microphone SN: -,,, Dd'J j Tester's Name: l,e,(' ;t lie, ~ llc"'

GPS Coordinates: - O\ '; *I 5 7 5 7 7 West ~ S . ~ 4}. 'l 3 I North Checked Battery? 'lea No Checked Clock? " - No Memory Checked?

  • No Calibration level before test: q f *I dBC 30 second calibration tone recorded before test? ~ No Calibration level after test: ~ 1.J dBC 30 second calibration tone l'9COfded after teat? ~ No Calibrator Model: ( -1 ~ o Calibrator SN: I 'l t, 7 +

- - - - * - - - - ~ T o be tllled In be by the field crew at the stt.---*----- -

Location Drawi


Plan View Major Elevation Changu (can also use provided map ID mark location)

Microphone height:

Photos Taken?

  • Meter Recording?

!:ft.

Measurement Location description:

e No No

?t1t: ~::i}sibN:d o.. °Sir' c~JCtd:t,, sc4 i:i:~ '(~)r~

(,b6-\S. Wnd Dir: ~

Wnd Spd: ~ mph Temp: "ls$

deg.

  • F

~ -*

Weather Station on and wind cover removed? ~ No Ambient noise level before teat 63 dBC :'Tb ( t 0<) , ,

  • Maximum level observed during the test: '-36-2. dBCW M- w &-i:k ~
  • t'b"I ~ (} ' -~ ~
  • Could you hear the sirens? (fjj . No
  • Ambient noise level after test: "23 dBC No.tes.Jlbolilt te1~including ba no_i1.e and noise iptrUSiOnl~

- during ltle telt):6-J<aS1 ~i ( Qd..aiek.

~ \ <0? C.k\lf \ ~ ~ ~ ~ ~ ~ ~ , s ; ; ( n < -\'\.){O, tq ~a:\-ratn.a.J~1,t<+> -t-+ur 1 ,<l;.

~~ C f Ii\. * ,v~CQ..(l,i}, ( \ v 1r -~ °!* -CC)"):,Jr~i2i,/ tr1J ~~ ~ -~

  • 1 Tester's Signature:r,,,;;;.,.:.a.1:..i.o..i.. :x.::~...;..J,jl.llC~---------==-£ :4".i.i::.....c::>Q1 _-t, ,l~ -" ., '.t.-'f'I .

, tdg r -

figure 18. Data collection sheet for SLM ANO 01 for siren 1211

Far-Field Measurement of Siren lZll from Sound Leve Meter ANO 02 SLM ANO 02 was positioned close to the intersection of Rte 51 and Hillside Dr. The time history from this test is shown in Figure 19, with the comined 500 Hz and 630 Hz siren signal clearly evident above the background level. Background levels at this location was around 55 dBC. The test data sheet is provided in Figure 20.

100.0

- - - C-Weight

- 500 Hz+ 630 Hz 90.0 i

Siren Signal - '

80.0 70.0 ai

~ 60.0

'ii Q) 50.0 40.0 30,0 20.0 11:08:00AM 11:09:00AM 11:10:00AM 11:11:00AM 11:12:00AM 11:13:00AM Time Figure 19. Time history from SLM ANO 02 for siren lZll

ANO Siren Test Datasheet

- - - - - - - - - T o be fllled by supportstatlblf'lffr----------

Date: Q(;,/'l2 I :z.020 Time: ....Jt_:"I_~_ _ _ _ _ __

SLM Model: f... 0 I} I SLM Serial Number: _ __..,... 3_.'l._.7__

Preamp SN: 5: I }; O Microphone SN:  ; o 71 7 h Tester's Name:_.$,.,....~1"'~W::'-----------------

GPS Coordinatea:____.~....S....,t_,,!t_____ VVest_..q........,J_.1....i°'-------NOfth Checked Battery? Yee No Checked Clock? Yes No Memory Checked? Yes No calibration level before test: C\ q. *\ dBC 30 second calibration tone recorded Calibration level after test:

'en "l i_E teat?

dBC

@ No 30 second calibration tone recorded after test? 'lej No Calibrator Model: (.,.) >oo  ! ____

calibrator SN: ______I_S-_&t_..7...

- - - - - - - - - T o be nned In be by the field crew at the site---------

Location Orawin :

Plan View Major Elevation Changu ccan also use provided map to mark location)

Measurement Location description: tJ:....~" *{ H:P.i,J* .-J ~ - OP!' .f?tlo-Microphone height:  ? ft. W i ~W 1'10'deg. ~* . .

Photos Taken? @ No Wind Spd: l .1 mph , **

Meter Reeotding? t:!§J) No Temp: 'R,2,S *F  :

  • Weather Station on and wind cover removed? @s No Ambient noise level befote test: 52 dBC Maximum level observed duri~ teat: ,., dBC Cou~you~arthesirens? \t!J No 'll s:..... .f.J,.,i: UJ?.~

Ambient no1Se level after teat:

>>: S7.. dBC Notes about test (including background noise and noise Intrusions during the test):

Tester's Signature:

~ ;,~ f,J: 1. ~:.ZJ 0,,1, E...ls 0w-y;1 d,.,;1 ....)T Figure 20. Data collection sheet for SLM ANO 02 for siren 1211

Far-Field Measurement of Siren 1Zll from Sound Leve Meter ANO 03 SLM ANO 03 was located in a large parking lot close to the busy road Rt. 22. Unfortunately because of the busy road, the elevated background noise made it almost impossible to identify the siren signal in the time history (shown in Figure 21). Background levels in this location were in the low 60s dBC. The data sheet for this test is shown in Figure 22.

100.0

- - -C-Weight

- 500 Hz +630Hz 90.0 80.0 Possible Siren Signal 70.0

=

~ 60.0 I._

..,,,.r ti .,,,*' , .....,

~

50.0 40.0 30.0 20.0 11:08:00AM 11:09:00AM 11:10:00AM 11:11:00AM 11:12:00AM 11:13:00AM Time Figure 21. Time history from SLM ANO 03 for siren 1211

ANO Siren Test Datasheet Date: 6 / z }l to to

- - - - T o be filled by support Time:

staff----------

iO ', J oe..-

SLM Model: L.Q jll SLM Serial Number: f'").7 f Preamp SN: l~ 13, Microphone SN: '30 7 3 ') b Tester's Name: 2.Lw e1:+ "'is '"- A:>::i::u4) 1 *1£1/4¥j:

GPS Coordinates: - q '3.\ ~S-- (,'} ~ West 3£, ). }. 3 t B7 North Checked Battery? &i1 No Checked Clock? ~ No Memory Checked? ~ No a Calibration level before test: * ,4 *I dBC 30 second calibration tone recorded before test? '@ No Calibration level after test: C\4. \ dBC 30 second calibration tone recorded after test? ~ No Calibrator Model: (""' 4'00 Calibrator SN: ( ') lei 14-To be fllled In be by the ne1c1 aew at the S l t e - - - - - - - - - -

,-------------------. Plan View Location Drawing:

Major Elevation Changes (can also use provided map to mark location)

Measurement Location description: ?,50 :fm( erv,t °f iltt Z,t Microphone height: £ 'v ft. Wind Dir. , ,o 5 deg.

Photos Taken? ~ No \Mnd Spd: <<>o mph Meter Recording? t~. No Weather Station on and wind cover removed? ~ No Temp: B~-~ *F Ambient noise level before test: 64 dBC Maximum level observed duri~ test: t 6.'k dBC Could you hear the sirens? Q:!!) No Ambient noise level after test:

Notes atx,ut test (including backgl"Qund

~ ~,'f.Q. is c_ l,,f\ ~ C\. wti:i--JIYY" t'tltl

= 63 dBC and noi~ intrusions during the test):

t Rf.e U . \Jir.\.v.e,\l,~ f tW- ~ ... ~It)

J

'Z,-~~l.t"llPS Tester's Signature: s. b """"'"1'; "'-'~ ':) \o ~

Figure 22. Data collection sheet for SLM ANO 03 for siren 1211

Field Measurements of Siren 129 Siren 1Z9, a Whelen model WPS2807 siren, was measured on June 23 rd , 2020 at approximately 12:00 pm. This siren is located on Bay Ridge Dr. in Dardenelle, AR, next to the Lion's Den Golf Course . This siren is mounted on top of an approximately 50 foot wooden pole. Far-field SLM ANO 01 was placed to the west of the siren, SLMs 02 was placed to the south-east of the siren, and 03 was placed east of the siren. This is shown below in Figure 23. The measured output from this test were significantly lower than other similar models of siren suggesting there may be a maintenance issue with this particular siren. After the testing Acoustic Analytics learned that the siren had, in fact, suffered damage (possibly from a lightning strike) and was repaired shortly after the testing was completed. The ANSI S12.14 data sheet is provided in Figure 24, with a photo of the siren in Figure 25 and the measu red time history in Figure 26.

Figure 23. Position of siren 129 relative to the far-field SLMs

Siren Sound Output Measurement per ANSI S12.14 Data Sheet Siren Mfg: Whelen Modal No: WPS2807 SIN: _ _ _ __

Oe1Cf1)tion: In situ measurement of ANO siren 129 Meas. Loe. Measurement alon the side of a road next to a olf course Oas: 6 23 20 Time: 12:00 pm By: Bruce I. Tide: _ _ _ _ _ _ __

Temp_§§_ °F Windspeed:_Q__q,ti Wind Dir:_:__ Clouds 100  % Precip.(Y/N)?_N _____

Elwatlon Sketch ofT* SIii 100 Feet SO Feet Grass Mfg rec'd mtg. height: ...2Q_ feet Actual height:~ feet Method: Laser Power conect (Y.t4)? _ __

Ground type & COY8f' between sken and meas. loc. _G¥+'r....

a £.,.S_ _ _----:----.,...,....---,-

Oevialions from test prooadura: There appearedto be some repairs or modification to this siren. One of the bird screens was a different size than the others.

SLMMlg: LO ModelNo: 831 SIN 3174 PriCalDal8:.3/11/20 Filter Mfg:____ Model No:___ SIN______ Pri Cal Date:

CalibMtg: LP Model No: ca1200 SIN 15674 Pri CaJ Data::6/19/20 Field Calbration: Before 94.0 dBC AAer.94.,,....0_,d...B.,.C..,__________

Max ambient: BefORI 53 dBC slow Afler _____5__6_________ dBC slow Microphone SN: 311593 Preamp SN: 51309 Base Line Position Secondary P06ition

.ti1.Jlasn Siren Sound: Alert Aflrt MXSCL (max dBC, slow): 110.7 Avvrage SCL dBC slow: 107.4 Max 113 octave band, Hz: 500 Hz & 630 Hz MXSCL in max 1/3 oclave band, dBC slow: 110.9*

Avvrage SCL in max 1/3 octave band, dBC slow: 107.3 Bystander MXSCL, dBC slow 119 xxx Dist of bystander MXSCL from mooot. feet 52 xxx Other pertinent information:

  • The fact that the 500 Hz & 630 Hz appears higher than the C-welghted level Is an artifact of the sound level meter's processing and Is within the experimental error.

Figure 24. ANSI S12.14 Data Sheet for Siren 129

~~~*.!mil

~ ~-oo m ~ v~~@.U ©'IDV 1~@>'t!W'W <<::tn~

~aK?~nia

~~

~--~

~* . ~-4$1,,

Figure 25. Photo from the bucket truck, looking at siren 129 130.0

- Measured Siren Level

- - - Average Siren Level 120.0 110.0 100.0 u 90.0 ID 1 80.0

~

70.0 60.0 50.0 40.0 12:12:30 PM 12:13:00PM 12:13:30PM 12:14:00 PM 12:14:30PM Time Figure 26. Time history of the received sound from siren 129 as measured from the bucket truck

Far-Field Measu rement of Siren 1Z9 from Sound Leve Meter ANO 01 This SLM was placed close to the intersection of Rte. 406 and Rte . 22. Because of an equipment malfunction, no data was collected from SLM ANO 01 for this siren.

Far-Field Measurement of Siren 1Z9 from Sound Leve Meter ANO 02 This SLM was placed at the intersection of Bay Ridge Rd. and Marina Rd. The time history from this tests is shown in Figure 27, with the data sheet provided in Figure 28. As identified in the data sheet (and as is clearly obvious in the time history), three cars passed by the meter during the siren sounding. This briefly artificially elevates the received sound level and does not accurately represent the siren signal. Therefore, those portions of the data were removed when computing the siren characteristics. Despite the intrusion of the cars, the siren signal is clearly evident above the background noise, which is in the low 60 dBC range for this location.

100.0

- - - C-Weight

- 500 Hz+ 630 Hz 90.0 With car data included 80.0 70.0 iii"

~ 60.0 "ii

~

50.0 40.0 30.0 20.0 12:11:00 PM 12:12:00 PM 12:13:00 PM 12:14:00 PM 12:15:00 PM 12:16:00 PM Time Figu re 27. Time history from SLM ANO 02 for siren 129

ANO Siren Test Datasheet

- -- To be fi lled by $t1Pl)Ol't staft!----------

Date: ab/11,,/ 1 O,Z. 9 Time: \1~011 SLM Model: L C> S~ i SLM Serial Number:_...,3.._}.... 9...7___

PreampSN: S--1 }4o Microphone SN: 30-717

  • Tester's Name: ef, "f~cr GPS Coordinates:____.1,"'S:;...._2_?_ _ _ _ _ West ~3. 2.l North Checked Battery? Yes No Checked Clock? Yes No Memory Checked? Yes No Calibration level before test: °'- 4*(} dBC 30 second calibration tone recorded before test? ~ No Calibration level after test: vi (c,.,I' dBC 30 second calibration tone recorded after test? ~ No Calibrator Model: C"' ) ").c)O Calibrator SN: ___l_S"_~ t ___

- - - T o be ftlled In be by the neld aew at the site--

Location Drawin

~-------------------,Plan View

..--~--------------,

Major Elevation Changes (can also use provided map to mark location)

Measurement Location description: frjAJ1c,  ! A,!b, .-0,,\- ~~( *"-4 "" 4 N~,"M ,..,J ~

Microphone height:  ;- ft. \i\'ind Dir: /JV) ~ t'1.. deg. Q{t!....

Photos Taken? ~ \i\'ind Spd: 0 mph Meter Recording? ~ No Temp: ~Sc!<< °F Weather Station on and wind cover removed? ~ No Ambient noise level before test: St> dBC Maximum level observed duriN-the_t_eat_  : --~-2---- dBC , \ ~4,- °"~ po**"- I,,,~ ~ ~ O..f" Could you hear the sirens? \!:J No Ambient noise level after test: S'f dBC Notes about test {including background noise and noise intrusions durinq the test): B;,/5 ~ ~

Tester's Signature: _ _ _

<d.77

. 3t:SA

__._(t-==-,..,_*--------------1-,.... '::::......_c:M,~

_______.!!n......., _ _ __

41.t lj1ti ,/~II:.

Figure 28. Data collection sheet for SLM ANO 02 for siren 129

Far-Field Measurement of Siren 1Z9 from Sound Leve Meter ANO 03 This SLM was in a cul-de-sac at the end of Birdie St. The siren signal is clearly evident above the background noise shown in the time history in Figure 29. Backgroun d noise levels in this location were in the low 60 dBC range. The data sheet for this test is provided in Figure 30.

100.0

- - -C-Weight

- 500 Hz+630 Hz 90.0

-< Siren Signal 80.0 70.0 iii

!:!. 60.0 "ii

...I so.a 40.0 30.0 20.0 12:11:00 PM 12:12:00 PM 12:13:00 PM 12:14:00 PM 12 :15:00 PM 12:16:00 PM Time Figure 29. Time history from SLM ANO 03 for siren 129

ANO Siren Test Datasheet Date:

- - - - - - - - - : r o b e filled by support btU l 2 ow staff---------

) \e_o______

Time: ___, .....

SLM Model: t,.. I) ~3 I SLM Serial Number: __f_)._.7...,B_ __

Preamp SN: I'i, 13 b Microphone SN: }O 73'l

  • Tester's Name: 7144,p:f:,r)j CA~) 1" :<<-**?J:

GPS Coordinates: -q3 .'M 3 b 75* Welt  ?§. lf7)tt~ North Checked Battery? Gs No Checked Clock? 'flp No Memory Checked? ... No Calibration level before test: :J I 4, dBC 30 second calibration tone recorded before test? ~ No Calibration level after test: 0\4-. I dBC 30 second calibration tone recorded after test? ~ No Calibrator Model: l. .... ) )cc Calibrator SN: _ _ l _~-~...7...f _ __

- - - - - - - - - - - T o be filled In be by the field aew at the sl*~ --------

Location Drawing:

.-------------------. Plan View Major l!levatlon Chang*

(can also use proylded map to mark location)

Measurement Location description: J\.u,. .f414 ctt: fbv4:, Cr: a,t, , tow,;rL4 m p. M ~

Microphone height: .; *o ft. Wind Dir: 299 deg. t'\l,l~

Photos Taken? ~ No \Mnd Spd: t, \ mph Meter Recording? Yes No Temp: $9 . l °F Weather Station on and wind cover removed? (i;) No Ambient noise level before test: _ __.~.,_5°..,_____ dBC Maximum level obeerved during the test: 3:9.9 dBC Could you hear the sirens? ~ No Ambient noise levef after test: 6Y dBC

~ 1t.e Notes about tnt (includina background ,n ol~nd noise intrusions ~uring the test): 't

~ l"J...ifJ'J.,,bC r- V\.)£\ 7J., ,~ .~ c:....J+il\J} w., M~1 , \ t \S, ~'l.,O'f" IC1,<.A ~ m-, ~*,c.">t'

  • Tester's Signature: ) k '>i- 1 ~:J ::S \. :4:':2S Figure 30. Data collection sheet for SLM ANO 03 for siren 129

Field Measurements of Siren SZ2 Siren 522, a Whelen model WPS2807 siren, was measured on June 24 th , 2020 at approximately 8:40 am. This siren is located on Rt. 393 between Oak Rd. and Riverside Dr. in Illinois Township, AR. This siren is mounted on top of an approximately 50 foot wooden pole. Far-field SLM ANO 01 was placed to the north of the siren, SLMs 02 was placed to the east of the siren, and 03 was placed south-west of the siren. This is shown below in Figure 31.

Figure 31. Position of siren 522 relative to the far-field SLMs

/

Siren Sound Output Measurement per ANSI S12.14 Data Sheet Siren Mtg: Whelen Modal No: WPS2807 SIN: _ _ _ __

==

Description:==

In situ measurement of ANO siren 522 Meas. Loe. Measurement across a road near a farm.

Date: 6/24/20 Time: 8:40 am By: Bruce I.

Title:

Temp.l!_ °F Wind speed: 2.5 mph Wind Dir: 100 Clouds _Q_ % Precip. (YIN)?_.N...__ _

Elwation SUld'I of T... Sill 100 Feet SO Feet Grass Grass Mfg rec'd mtg. height: ..2Q_ feet Actual height: _9_ leet Method: Laser Power conect (YIN)? _ __

Ground type & COYel' between siren and meas. loc. Grass and asphalt Deviations from lest procedura: _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ __ __ _

SLM Mtg: LO Model No: __8__

3__

1 __ SIN 3174 Pri Cal Oal8:. 3/11/20 Filter Mfg: Model No: _ __ SIN _ _ _ __

Pri Cal Data:

Calib Mtg: LP Model No: ca1200 SIN 15674 Pri Cal Oa: :6/19/20 Field Calibration: Befora 94.0 dBC Mer 94.0 dBC Max ambient: Befora _ _ ___.._ 5 ....

2 __ dBC slow Mer 56 dBCslow Microphone SN: 311593 Preamp SN: 51309 Base Line Position Seconda,y posjtjon fil.Jlll5a Siren Sound: Alert Alert MXSCL (max dBC, slow): 118.6 Average SCL dBC slaN: 115.1 Max 1'3 octave band, Hz: 500 Hz & 630 Hz MXSCL in max 1/3 octave band, dBC slow: 118.6 Average SCL in max 1/3 octave band. dBC slow: 104.6 Bystander MXSCL dBC slow 116 xxx Dist of bystander MXSCL from mount, feel 47 xxx Other per1nent information: _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ __

Figure 32. ANSI S12.14 Data Sheet for Siren 522

~~Lfi:§1,~/.l!)ij l~l&~

m*:ii.--.~~

~~

&,q Figure 33. Photo from the bucket truck, looking at siren 522 130.0

- Measured Siren Level

- - - Average Siren level 120.0 110.0 100.0 90.0 u

Ill

~

'ii 80.0

....II 70.0 60.0 so.a 40.0 9:06:4SAM 9:07:lSAM 9:07:4SAM 9:08:15 AM 9:08:4SAM Time Figure 34. Time history of the received sound from siren 522 as measured from the bucket truck

Far- Field Measurement of Siren 5Z2 from Sound Leve Meter ANO 01 Ths SLM was placed on the side of the road on Riverside Rd. The siren signal is clearly evident in the time history provided in Figure 35. Background noise levels in this location were in the mid 50 dBC range. The data sheet for this test is provided in Figure 36.

100.0

- - -C-Weight

- 500 Hz +630Hz 90.0 80.0 70.0

!:!. 60.0 "ii

~

\' . . ,,, ' t~

I , ,.._ 1 \I ' \ -,'- ,._,

~' ,.,",, ,. .,.,'",,,,

, ... ,,,,, ,, '1 *

  • 50.0 40.0 30.0 20.0 9 :0S :30AM 9:06 :30AM 9:07 :30AM 9:08 :30AM 9:09:30AM 9 :10:30AM Time Figure 35. Time history from SLM ANO 01 for siren 522

ANO Siren Test Datasheet

,") *To be fifled by support mfr Date: Gz/4~?-o Time: 1;30 9:c'!'

SLM Model: kQ ~ 1 I SLM Serial Number: ~ s--s-g Preamp SN: 5:i: S:o & Microphone SN: }I 0,,; ')

Tester's Name: D" c ~ t-1 le.. '""°") l4'"

GPS Coordinates: - ~ *} ~'\ 4f~ West ~f. '0 bct",' I North Checked Battery? ~ No Checked Clock? ~ No Memory Checked? 'NI No Calibration level before test: "7 41 dBC 30 second calibration tone recorded before test? Y)i) No Calibration level after test: 'j "°* 0 dBC 30 second calibration tone recorded after test? Yo) No Calibrator Model: CA I )co Calibrator SN: _..._1__

.r;-...:i:,_7.....4-_ _ __

- - - - - - - - - T o be l'Hled tn be t,y the fleld crew at the stte---------

Location Drawing:

~ Plan View _ '9 ~ -~*jor Elevation Changes n also use provided map to martt "°1' _-\

(;,'<ff - ~- "'\

~ .... ~ ~

~ J("... s

..I --- c7':~ .

/+\

qJs ">'s,1 -~-~?- \

i \ ..\-- (~ ~*\- \_

,\.' ~ - -

et, ~ " r-:;,C- - --' .) \

'"'I-- ------ ---- - - - \

Measurement Location description: ~ff:V\ \aue i:Oie- ,ooq m ~deanai ~ ~l Microphone height: ~ f t . ~ -t-reeS Wind Dir: 6 IO\ dig.

Photos Taken? es No Wind Spd: J* 'R mph Meter Recording? es No Temp:  % *F Weather Station on and wind cover removed? ~ No Ambient noise level before test: $3 dBC

  • Maximum level obeerved during the tett: ' 2 , $" dBC Could you hear the sirens? @ No Ambient noise levet after test: S::3 dBC Notes about test (including background 119ise and notJIJI intrusions during the test): {ot5 dt-brro\sc~

...- ~~~ - t:n~f3..Y -W-"l.Qc.,,nJ'.VH1tt? l-¥' ~1YfoU-n,,.

Tester's Signature: lla n:::<R1J'- ~11 allc:u Figure 36. Data collection sheet for SLM ANO 01 for siren 522

Far-Field Measurement of Siren 5Z2 from Sound Leve Meter ANO 02 This SLM was placed in the Delaware Park Public Use Area. The time history for this SLM is provided in Figure 37, with the siren signal clearly rises above the background noise. From the data sheet shown in Figure 38 it appears that a car pulled up close to the meter shortly after the test. This is also evident in the time history as the peak in noise shortly after the siren sounded. Fortunately this did not impact these measurements. The background noise in this area was in the low 50 dBC range.

100.0

- - -C-Weieht

- 500 Hz + 630 Hz 90.0

. Siren Signal 7

80.0 I

II 70.0 11 I I I I I 1 I I I 1 I I iii' I 1

~ 60.0 I 1

,,I I I

'ii \

I

\

> I Qj 1 I

\,

. I *

"i ll I \ I

"' \,,',,' l '

50.0 40.0 30.0 20.0 9:0S:30AM 9:06:30AM 9:07:30AM 9:08:30AM 9:09:30AM 9:10:30AM Time Figure 37. Time history from SLM ANO 02 for siren 522

ANO Siren Test Datasheet

- - r - r - - - , - - - - - -

  • T o be ftlled by support 11:ltalllllffr----------

Oate: "1'}):f/~

Time
?i3'2""tr' SLM Model: L- D §-\ I SLM Serial Number: _ _.1-3...9...,7......___

Preamp SN: S- I },t.o Microphone SN: }97771>

Tester's Name: ....EQ:..,.__tpg__.,.._r_ _ _ _ _ _ _ __,,.,,,---------

GPS Coordinates:___1__5__....,f\""""""C.__.1_ _ _ _ _ West -1'~ , .l."J'f (p North Checked Battery? 'iii No Checked Clock? ~ No Memory Checked? ~ No Calibration level before test: "14: .i) dBC 30 second calibration tone recorded before test? ~ No Calibration level after test: e*H ,o dBC 30 second calibration tone recorded after test? ~ No Calibrator Model: C"'J );90 Calibrator SN: _ ___,;l....S'"_.~....7....4..___ __

- - - - - - - - - T o be filled In be by the field crew at the slte---------

Location Drawi

.------------------. Plan View Major Elevation Changes (Qin also use provided map to mar1<

location)

Measurement Location description: -'t];_,_,,"""-J"""c_&\.___B'-""..-UJ.,s...._~ t ______,.__,,,..--,--

Microphone height 5 ft. Wind Dir: N001 deg.

Photos Taken? rr!l No Wind Spd: _0

____ mph Meter Recording? @ No Temp: '79 °F Weather Station on and wind cover removed? @ No Ambient noise level before test: Su dBC Maximum level obaerved duri~ te8t: ___ rn,

.2._____ dBC Could you hear the sirens? ~ No Ambient noise level after test: 5"'1 dBC Notes about test (including background noise and noise intrusions during the test): O"' I. 'o:,J.1 Tester's Signature: ~

,,:,6;:7 ~ '""'<J ~,,f A ~.. ~ *,. .:. ,J,...," rJlfd Olfff

~~ J.. ~ ~*'* .Q.. IJ. 1...-f. IM}., ,rt:;.1 Figure 38. Data collection sheet for SLM ANO 02 for siren 522

Far-Field Measurement of Siren 5Z2 from Sound Leve Meter ANO 03 This SLM was placed towards the end of Western Shores Drive. The time history from this test is shown in Figure 39, with the data sheet in Figure 40. The siren signal is clearly visible above the background noise, with the background noise level in the mid 50 dBC range. The data sheet for this test in provided in Figure 41.

100.0

- - -C-Weight

- 500 Hz +630 Hz 90.0 80.0 70.0 iii

~ 60.0 "ii f',. . ,. , ,"{-, \ r

\ \ '

!l - \ . , , , , , *\,,'" "'-""I\ ,1 \ 11" I

\

so.a 40.0 30.0 20.0 9:05:30AM 9:06 :30AM 9:07 :30AM 9:08:30AM 9:09:30AM 9:10:30AM Time Figure 39 . Time history from SLM ANO 03 for siren 522

ANO Siren Test Datasheet

- - - - - - - - - - T o be tilled by support staff*- --------

Oate: kz (>-4,/ rO Time: 7 ~ 3o °' ...,..

SLM Model: L-0 i ~ I SLM Serial Number: 4) 7 8 Preamp SN: l 'i l '3 b Microphone SN: 30 7 3') (,

Tester's Name: j~AA:1,,,, M ( ~ ) 1 *,et,H}:

GPS Coordinates: -q 3 1d- ".I 4t?(1J West s 5'. ):B 1 +o North Checked Battery? ~ No Checked Clock? .... No Memory Checked? Y~ No Calibration level before test: .?\3 . "I dBC 30 second calibration tone recorded before test? ~ No Calibration level after test: °l I <J dBC 30 second calibration tone recorded after test? -6' No Calibrator Model: (-..\ ')oo Calibrator SN: _ _l_~_~_7_+- _____

- - - - - - - - - - T o be ftlled In be by the fleld crew at the 111stte.__ _ _ _ _ _ __

Location Drawing:

,-----------------, Plan View Major Elevation Changes (can also use provided map to mart(

location)

Measurement Location de6cription: .... ,goo* sc:u;e... ,t Wwm :swc., Pc, uwtu< "i"W'P-,

Lr Microphone height: Li .a ft. Wind Dir: ti~ deg. N,~~

Photos Taken? (fi;> No 'MndSpd: o mph Meter Recording? Yes No Temp: 1',&83*F Weather Station on and wind cover removed? ~ No Ambient noise level before test: $5 dBC Maximum level observed duri~ teet: '2l:z '\ dBC Could you hear the sirens? (!!Y No Ambient noise level after teat: Pb dBC Notes about test (induqing background noiff --~ noise intrusions during the test):

~ ..;.~1, ~ ~ ~ A. 1-Wt:t re~ MIA .

Tester's Signature:) k0\ VX 1 1 \ '1A4; Figure 40. Data collection sheet for SLM ANO 03 for siren SZ2

Field Measurements of Siren 3Z4 Siren 324, a Whelen model WPS2907 siren, was measured on June 24th , 2020 at approximately 10:15 am . This siren is located on Fleetwood Rd, London, AR, about3/4 of a mile north-west of Akransas Nuclear One. This siren is mounted on top of an approximately 50 foot wooden pole. Far-field SLM ANO 01 was placed to the north of the siren, SLMs 02 was placed to the north-west of the siren, and 03 was placed south of the siren. This is shown in Figure 41 below. The ANSI Sl2.14 data sheet is provided in Figure 42, with a phot of the siren in Figure 43 and the acoustic time history of this test shown in Figure 44.

Figure 41. Position of siren 324 relative to the far-field SLMs

Siren Sound Output Measurement per ANSI S12.14 Data Sheet Siren Mtg: Whelen Model No: WPS2907 SIN: _ _ _ __

==

Description:==

In situ measurement of ANO siren 324 Maas. Loe. Measurement along the side of a small road.

Daw: 6/24/20 Time: 10:15 am By: Bruce I. Tdla: _ _ _ _ _ _ __

Temp ..§2.. °F Wind speed:~,.-. Wind Olt: _Q__ Clouds _g_ % Precip. (Y/N)? _N _____

Elevation Suleh of Teet SIii 100 Feet -

SO Feet Grass Mfg rec'd mtg. height: _fill_ feet Actual height:_£/_ feet Method: Laser Power correct (YIN)? _ __

Ground type & cover between siren and meas. loc. -'G_,._,.ra_s__

s _ _ _ _ _ _ __

Deviations from test procedure: _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ __

SLM Mfg: LO Model No: . .a:8=3-=1__ SIN 3174 Pri Cal Dat/1:.3/11/20 Fitter Mfg: Model No: _ __ SIN _ _ _ __

Pri Cal Date:

Calib Mfg: LO Model No: Cal200 SIN 15674 Pri Cal Oata::6/19/20 Field Cabation: Before 94,0 dBC After 93,9 dBC Max ambient: Before _ _ _ _4,...,8,.__ dBC slow After 48 dBCslow Microphone SN: 311593 Preamp SN: 51309 Base line Position SecOf)dary posjtion

.!it.JllmU Siren Sound: AJert AIQrt MXSCL (max dBC, slow): 120.3 Average SCL dBC slow: 116.9 Max 113 octave band, Hz: 500 Hz & 630 Hz MXSCL in max 1/3 octave band, dBC stow: 120.1 Awrage SCL in max 1/3 octave band, dBC slow: 116.7 Bystander MXSCL, dBC slow 114 XXX Dist of bystand9r MXSCL from mount. feet 92 XXX Oth8rper11nentinformatlon: _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ __

Figure 42. ANSI S12.14 Data Sheet for Siren 324

Figure 43. Photo from the bucket truck, looking at siren 324 130.0

- - - Average Siren Level 120.0 110.0 100.0 90.0 u

GI

~

"ii 80.0

..J 70.0 60.0 50.0 40.0 10:32:4SAM 10:33:lSAM 10:33:45AM 10:34:lSAM 10:34:45 AM Time Figure 44. Time history of the received sound from siren 324 as measured from the bucket truck

Far-Field Measurement of Siren 3Z4 from Sound Leve Meter ANO 01 This SLM was placed in the corner of a baseball diamond, close to the corner of Old Wire Rd . E. and Hays Ln. N. The siren signal does rise above the background noise when viewing the 500 Hz and 630 Hz signal (as shown in Figure 45). Background noise in this area was in the low 70 dBC range, probably driven by the presence of 1-40 nearby. The data sheet for this test is provided in Figure 46.

100.0

- - -C-Weight

- 500 Hz+ 630 Hz 90.0 80.0 70.0 iii"

~ 60.0 "ii QI

...I 50.0 40.0 30.0 20.0 10:31:00AM 10:32:00AM 10:33:00AM 10:34:00AM 10:35:00AM 10:36:00AM Time Figure 45. Time history from SLM ANO 01 for siren 324

ANO Siren Test Datasheet

- , - . . - - - . . - - - - - - ~ T o be ftlled by suppo,t statr*----

Oate: ',h-A /'HJ Time: 9f}O ... ,,...

SLM Model; { D ii 3 I SLM Serial Number: *~ ~ 8 Preamp SN: t; g ,;-,o b Microphone SN: ~ / o <.: 'Z> 1 Tester's Name: UP-e:; d!< IY'\"'}1'2.-,.

GPS Coordinates: -0\1,d- 4 t, lo~I West '\S-, '\131~5 North Checked Battery? Y,s No Checked Clock? 'Gs No Memory Checked? t,s No Calibration level before test: P\A-. O dBC 30 second calibration tone recorded before test? ~ No Calibration level after test: 4.

'j 0 dBC 30 second calibration tone recorded after test? '<Ml No Calibrator Model: (A./ ,-co Calibrator SN: IS-~ 14

- - - - - - - - -

  • T o be nned In be by the field crew at the Site--

.--------------...... Location Drawin :

Major Elevation Changes I

I Figure 46. Data collection sheet for SLM ANO 01 for siren 324

Far-Field Measurement of Siren 3Z4 from Sound Leve Meter ANO 02 This SLM was placed on Hill Blvd ., close to its intersection with West Dr. The siren signal time history is provided in Figure 47 and the measurement data sheet is provided in Figure 48. The siren signal is evident above the background noise, with the background noise in the low 60 dBC range.

100.0

- - -C-Weight

- 500 Hz + 630 Hz 90.0

-- Siren Signal 80.0 70.0 al

!:!. 60.0

'ii 50.0 40.0 30.0 20.0 10:31:00AM 10:32:00AM 10:33:00AM 10:34:00AM 10:35:00AM 10:36:00AM Time Figure 47 . Time history from SLM ANO 02 for siren 3Z4

ANO Siren Test Datasheet Date:

- - . - - - - - - - T o be ftlled by support ah{l1/JD2P Time:

staff-*--------

p:10 SLM Model: L. Q $:'>I SLM Serial Number: __'3...,3...9.._7_ __

Preamp SN: ~ I } +o Microphone SN: 16 777 &,

Tester's Name: 'ft =,-'"""'r GPS Coordinates: 35 .12~'\ North Checked Battery? )'" No Checked Clock? ~ No Memory Checked? "e No .,

Calibration level before test: "l 1, O dBC 30 second calibration tone recorded before test? ~ No Calibration level after test: ""14 ~ dBC 30 second calibration tone recorded Calibrator Model: ( .._ J ~ 0 after test? '(!!)

Calibrator SN:

No l ~' 14- __

nned In be by tne field crew at the stt---------

- - - - - - - - - T o be

,--------------..... Location Orawi __.,.__

Plan View Major Elevation Changu (can also use provided map to mark locatlon)

-;: I

~

i;...

Photos Taken?

W=ft.

Measurement Location description:

Microphone height:

Y e No No

_.O&-tpt!l,..-..--#-<f....d"----~--*._fl-._/.c......_{"""'..... .,_,

A ,"""'*__ __,,.___

Wind Dir: IJIJW lr~eg.

'Nind Spd: 6, (

Temp: f2 .o mph

  • F Meter Recording?

Weather Station on and wind cover removed? @ No Ambient noise level before test: 5'.'1_ dBC "-40'-ld -lrl Maximum level observed duR9 tat: 1,,,f dBC 36.32.'141\ - q;:(~ t,G Could you hear the sirens? ~ No I,.,,_. 1 Ambient noise level after test: 5  ! 5 dBC __..

Notes about test (including background noise and noise intrusions during the test):

~ 0-,.,. '--'1 wrO, .JJ.. ,-,*,c-..,

Tester's Signature: - - . . . . . ~ - - - * - - - - - - - - - - - - - -

Figure 48. Data collection sheet for SLM ANO 02 for siren 324

Far-Field Measurement of Siren 3Z4 from Sound Leve Meter ANO 03 This SLM was placed in the cul -de -sac at the end of Sta r Harbor Rd . The time history for this test is shown in Figure 49 with the data sheet provided in Figure 50. The 500 Hz and 630 Hz signal is moe then 10 dB above the background noise, where the levels were in the high 40 dBC range.

100.0

- - -C-Weight

- 500 Hz+ 630 Hz 90.0 80.0 70.0 L- Siren Signal ----.

iii"

!:!. 60.0 ti 50.0 40.0 30.0 20.0 10:31:00AM 10:32:00AM 10:33:00AM 10:34:00AM 10:35:00AM 10:36:00AM Time Figure 49. Time history from SLM ANO 03 for siren 324

ANO Siren Test Datasheet Cate: 1/4,vpo:)l) To be fll~:.~pport it-;~--~

SLM Modef: 1-D 'i'1>1 SLM Serial Number:___,,...4-.... ~....

Z.. S_ _

Preamp SN: I q ,:3& Microphone SN: 3073') ~

Tester's Name: ~t14 ( A(!),14) 1,e.Nt GPSCoordinates: - Cj3.)-+(e31,') West 3S.1Cb,4)) North Checked Battery? @ No Checked Clock? ~ No Memory Checked? 'Qa No Calibration level before test: °'\4- ,0 dBC 30 second calibration tone recorded before test? '@ No Calibration level after test: v) f. v dBC 30 second calibration tone recorded after test? '(js No Calibrator Model: ( .... I };oo Calibrator SN: _ _1_>-=b_7....:4:..-_ __

- - - - - - - T o be filled In be by the fleld crew at the site----------

,_ ___________ Plan View Location Drawing:

Major Elevation Chango (can also use provided map to mart<

~ location)

~ r Hc.>.(\;,or ~

Measurement Location description: :rt,, 4 flt'f,~ P\ ',to, t-4µ(1;,Q < 84 <e:t ~ ~-tfptxe of t'lP Microphone height: tz. 0 ft. Wind Cir: 4 I deg .Stllr ffr.k.-

Photos Taken? {§) No Wind Spd: \-4 mph r<eA)

Meter Recording? ~ No Temp: i3 *l °F Weather Station on and wind cover removed? fi_;;> No Ambient noise level before test: so dBC Maximum level oblerved du~e teet: t;I,, t dBC Could you hear the sirens? l'!.!IJ No Ambient noise level after test: 4 ""+- dBC Notes about test (including background noise and noise intrusions during the test):

V~ ~~,.t.t tl((Q\ , ~ ~~ c,..-o-c4o- ~",,,,\ f,o,.._ ~ ~ooun.41'1) {(U .L Tester's Signature: _J_ te+w"l<<\ ::S'\Ao&(

Figure SO. Data collection sheet for SLM ANO 03 for siren 324

Field Measurements of Siren 3ZS Siren 325, a Whelen model WPS2907 siren, was measured on June 24th, 2020 at approximately 11:15 am. This siren is located on Hwy 64, just west of the junction with Old Hwy 64 Win London, AR. This siren is mounted on top of an approximately 50 foot wooden pole. Far-field SLM ANO 01 was placed to the south-west of the siren, SLMs 02 was placed to the south-east of the siren, and 03 was placed north of the siren. This is shown below in Figure 51. The ANSI Sl2.14 data sheet is provided in Figure 52, followed by a photo of the siren in Figure 53 and the measured time history in Figure 54.

Figure 51. Position of siren 325 relative to the far-field SLMs

Siren Sound Output Measurement per ANSI S12.14 Data Sheet Siren Mtg: Whelen Model No: WPS2907 SIN: _ _ _ __

==

Description:==

In situ measurement of ANO siren 325 Meas. Loe. Measurement on the side of a bus road, alon a dirt road with some shrubs.

Date: 6 24 20 lime: 11:15 am By: Bruce I.

Title:

Temp_§§_ °F Wind speed: ...Q_~ Wind Dir:...:,__ Clouds _Q_ % Precip. (YIN)? _.N _____

Elevallon Slleletl of T..a SIii 100 Feet so Feet DlrtRoad Mfg rec'd mtg. height: ..2Q_ feet Actual height: .2Q_ feet Method: Laser Power cooect (YIN)? _ __

Ground 1ype, COY9I' between siren and meas. toe. Grass. dirt road. and shrubs Deviations from teat procedure: _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ __

SLM t.tg: LO Model No: _8_3_1_ _ SIN 3174 Pri Cal Oala:_3/11/20 Fbar Mtg: Model No: _ __ &N_____ PriCalOale:

Calib Mtg: LO Model No: Cal200 &N 15674 Pri Cal Oale: :6/19/20 Field Cali>ration: Before 93.9 dBC Ahet93.9dBC Max ambient: Before _ _ ___._7=3__ dBC slow Ahet 75 dBC slow Microphone SN: 311593 Preamp SN: 51309 Base line Position Secondary Poeition

~

Siren Sound: Alert Alert MXSCL (max dBC, slow): 119.2 Awrage SCL. dBC slow: 116.1 Max 113 octave band. Hz: 500 Hz & 630 Hz MXSCL in max 1/3 octave band, dBC slow: 119.2 Awrage SCL in max 1/3 octave band, dBC slow: 116.0 Bystander MXSCL dBC slow 114 xxx Dist of bystanc>>r MXSCL from mount. feet 92 xxx Othef per1inent Information: _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ __

Figure 52. ANSI S12.14 Data Sheet for Siren 325

Figure 53. Photo from the bucket truck, looking at siren 325 130.0

- Measured Siren level

- - - Average Siren Level 120.0 110.0 100.0 90.0 u

a:i j 80.0

~

70.0 60.0 50.0 40.0 11:33:15 AM 11:33:45AM 11:34:15 AM 11:34:45 AM 11:35:15 AM Time Figure 54. Time history of the received sound from siren 325 as measured from the bucket truck

Far-Field Measurement of Siren 3Z5 from Sound Leve Meter ANO 01 Because of an equipment malfunction, no data was collected from SLM ANO 01 for this siren.

Far-Field Measurement of Siren 3Z5 from Sound Leve Meter ANO 02 This SLM was placed on Rte. 333, just to the east of some train tracks. The time history for this test is provided in Figure 55. The 500 Hz plus 630 Hz signal from the siren is over 10 dB above the background. Also visible in this plot are peaks generated by cars passing, fortunately not during the siren test. The background level (when cars were not present) is in the mid 50 dBC range. The data sheet for this test is shown in Figure 56.

100.0

- - -C-Weight

- 500 Hz +630 Hz 90.0 ,,J.

80.0 ,,,, . Siren Signal I I I I I I 70.0 iii

!:!. 60.0 Ii II ,,v ..... ',' "

50.0 40.0 30.0 20.0 11:31:30AM 11:32:30AM 11:33:30AM 11:34:30AM 11:35:30AM 11:36:30AM Time Figµre 55. Time history from SLM ANO 02 for siren 325

ANO Siren Test Datasheet

- - - - - - - - - : r o b e ftlled by supportsWf.---------

Oate: b/2.'i /'J!l1.& Time: lt:2'!,

SLM Model: &.,I) 'I~ I SLM Serial Number: __,_1_'\..,.7___

Preamp SN: '>' I ')-4o Microphone SN: 30777 '1 Tester's Name: ft -rui&!r GPS Coordinates: 1;. 12. 'CO West ~'t. Vf'{ ( North Checked Battery? ~ No Checked Clock? Gs No Memory Checked? 'M No Calibration level before test: °'.) 4.0 dBC 30 second calibration tone recorded before test? Y@ No Calibration level after test: ') 4 ~ dBC 30 second calibration tone recorded after test? (ii) No Calibrator Model: C~ I £PO Calibrator _ _ __

SN: __l_t;"_&__i __4-

- - - - - * - - - -

  • T o be filled In be by the fleld aew at the Site---------

Location Drawina:

Plan View Major Elevation Changee (Can also use proylded map to mark location) l

\

Measurement Location dnaiption: _O_f!'_l}__ d...._d1\__trr-

__ R.il

__ ~~.

~.,J_ _ _

Microphone height: ~ ft. deg.

Wn~i Photos Te,ken? ~ WndS : mph Meter Recofding? ~ No Temp: *f Weather~ on and wind cover removed? @ No Ambient noise level before test: ___5_? .a......=--,,---- dBC Maximum level observed duri~ test: 9-/.!, dBC Could you hear the sirens? ~ No Ambient noise level after teat: 5l/ : dBC Notes about teat (indµding background noise and l1()iae intrusions during the test):

~,I~ . 0,,t~ bi,<}-;.

Tester's Signature: ------~-_e,.,___________

(/

Figure 56. Data collection sheet for SLM ANO 02 for siren 325

Far-Field Measurement of Siren 3Z5 from Sound Leve Meter ANO 03 This SLM was placed at the end of Rock ln. The time history is provided in Figure 57 and the data sheet is in Figure 58. The 500 HZ and 630 Hz combine signal clearly shows the siren more than 10 dB above the background noise, which was in the mid 60 dBC range .

100.0

- - - C-Weight

- 500 Hz + 630 Hz 90.0 80.0 Siren Signal 70.0 cc

~ 60.0 "ii

...J 50.0 40.0 30.0 20.0 11:31:30AM 11:32:30AM ll:33:30AM 11:34:30AM 11:35:30AM 11:36:30AM Time Figure 57. Time history from SLM ANO 03 for siren 325

ANO Siren Test Datasheet

- - - - - - - - -To be ftlled by suppo,t *IUl~rF' - - -- - -- - -

Date: ~(2!:ll:l,QR Tme: (l:OCJ SLM Model: L. 0 83 I SLM Serial Number: 41-7 S Preamp SN: l '\ I ~ b Microphone SN: '.} 7 ~ Cf£,

0 Tester's Name: ?Ji,,, ,&M*~ ( Atfl1) ,tu\{4: 1 GPS Coordinates: -"13,)?~ 73-t West 3S-,"34W North Checked Battery? '11is No Checked Clock? '(js No Memo,y Checked? 'th No Calibration level before test: °}{I t) dBC 30 second calibration tone ~ before test? '(je No Calibration level after test: l 4-, \) dBC 30 second calibration tone recorded after test? '6J) No Calibrator Model: ( .... j }DO Calibrator SN: __l....~  ;...;le~J+..____

- - - - -- - - - T o be ftlled In be by the field aew It the dll~----

te -----

~ - - - - -Plan - View- - - - - -Location Drawi Major Elevation Changes (Can also use provided map to mane loeatlon)

,,, a ioa,t t:U\AA!'Sl:' A I Q(.tl\ v Microphone height:

Photos Taken?

Meter Recording?

i Measurement Location description:

~

CJ c No No ft.

Weather Station on a a wind cover removed?

I acrtod

@ No Wind Dir:

Wind Spd:

Temp: ~, .o

+M-

~t;tj.

3,2

µyJ.. o,\ ~ le:.

deg.

mph

  • F lf\ .

Ambient noise level before test: ~'l. dBC Maximum level observed during the tat: blcl dBC Could you hear the sirens? a- No Ambient noiae level after test: $ dBC Notes about test (Including background noiae and noiM Intrusions during the test):

\ . \ ~ r,.. olo'a ~ ;"1 *~ ~ ~ ~b\ ~ \~ i,,fl..t\ vJ>.b ~ .

Tester's Signature: ) L:-Yi:~ ::J\M=,r Figure 58. Data collection sheet for SLM ANO 03 for siren 325

Field Measurements of Siren 2213 Siren 2213, a Whelen model WPS2907 siren, was measured on June 24 th , 2020 at approximately 1:00 pm. This siren is located near the corner of Reasoner Ln . and N. Arkansas Ave in Russelville, AR, next to a fire department. This siren is mounted on top of an approximately 50 foot wooden pole . Far-field SLM ANO 01 was placed to the north-west of the siren, SLMs 02 was placed to the north-east of the siren, and 03 was placed north of the siren. This is shown below in Figure 59. The ANSI S12.14 data sheet is provided in Figure 60, with a photo of the siren in Figure 61 and the measured time history in Figure 62 .

The decision to measure this siren was made while in the field to add an additional test after siren 1Z9 appeared to be having a maintenance issue. Unfortunately, this meant that there were limited supplies, so the testers had to resort to hand-written datasheets rather than the pre-printed version usually employed.

Figure 59. Position of siren 2Z13 relative to the far-field SLMs

Siren Sound Output Measurement per ANSI S12.14 Data Sheet snn Mfg: Whelen Model No: WPS2907 SIN: _ _ _ _ __

==

Description:==

In situ measurement of ANO siren 2213 Meas. Loe. Measurement across grass In front of a fire department.

0a1e: 6/24/20 Time: 1:00 pm e-,: Bruce I.

Title:

Temp JlL °F Wind speed: _2_mph Wind Dir: ~ Clouds _ L % Precip. (Y/N)? _N _____

Elevation Sulctl of TNt SIie 100 Feet SO Feet Grass Mfg rec"d mtg. height: ..fill_ feet Actual height ~ feet Method: Laser Power corract (Yh-,1)? _ __

Ground type & cover between siren and meas. loc. _ Gllll.&.lra...,s""'

s _ _ _ _ _ _ _ __

Deviations from lest procedure: _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ __

SLM t.tg: ___L=D__ Model No: -"8__ 3=1__ SIN 3174 Pr1 Cal D*: .3/11/20 Filler Mfg: _ _ _ _ Model No: ____ SIN _ _ _ _ __

Pri Cal Data: .

Calib Mfg: _L_p__ Model No: Cal200 SIN 15674 Pri Cal Data: .6/19/20 Field Calibration: Before _ _ _ 9_3...,9...d_B_c___ Arter 93.9 dBC Max ambient: Before 66 dBC slow After 69 dBC slow M icrophone SN: 311593 Preamp SN: 51309 Base Line Position Secondary Position

<it usect>

Snn Sound: Afet:t Alert MXSCL (max dBC, slow): 120.3 Average SCL. dBC slow: 117.2 Max 1/3 octave band, Hz: 500 Hz & 630 Hz MXSCL in max 1/3 octave band. dBC slow: 120.2 Average SCL in max 1/3 octave band, dBC slow: 117.0 Bystander MXSCL, dBC slow 114 XXX Dist of bystander MXSCL from mount. feet 72 XXX Other pertinent information: _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ __

Figure 60. ANSI S12.14 Data Sheet for Siren 2213 Figure 61. Photo from the bucket truck, looking at siren 2213

130.0

- Measured Siren Level

- - - Average Siren Level 120.0 110.0 100.0 90.0 uCD

~

"ii 80.0

!l 70.0 60.0 50.0 40.0 1:03:45 PM 1:04:15 PM 1:04:45 PM 1:05:15 PM 1:05:45 PM Time Figure 62. Time history of the received sound from siren 2213 as measured from the bucket truck Far-Field Measurement of Siren 3Z5 from Sound Leve Meter ANO 01 This SLM was placed a pull out along Lake Front Dr. Unfortunately, t his location was close to 1-40 which resulted in elevated backgrou nd noise levels. There is no obvious siren signal in the time history shown in Figure 63, with the background in the mi d 70 dBC range. The hand-written data sheet is provided in Figure 64.

100.0

- - -C-Weight

- - 500 Hz + 630 Hz 90.0 Possible Siren Signal --->-

80.0

, *  ! i ,,

't 70.0 I

~*

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iii'

~ 60.0 ai

~

50.0 40.0 30.0 20.0 1:02:00PM 1:03:00 PM 1:04:00 PM 1:05:00 PM 1:06:00PM 1:07:00 PM Time Figure 63. Time history from SLM ANO 01 for siren 2213

C\4,1 J~ re.\ - sO ~<'.C

.. q1 . \ If~ 8>\, '-" ',-, ) 0}' ~ ~ if- ~

Figure 64. Data collection sheet for SLM ANO 01 for siren 2213

Far- Field Measurement of Siren 3ZS from Sound Leve Meter ANO 02 This SLM was placed at the corner of Cain Ave. and E. Aspen Ln. The time history is provided in Figure 65 with the data sheet in Figure 66. The 500 Hz and 630 Hz combined signal clearly shows the siren soun ding over 10 dB above the background noise. There is clearly an intrusion in the C-weighted levels at the beginning of the siren sounding, but it did not appear to impact the 500 Hz and 630 Hz combine signal.

100.0

- - - C-Weight

- 500 Hz +630 Hz 90.0

,,, ~

I

-ir- Siren Signal -

80.0 I I I I I I II , ,

I I 1"' ,, *' I\

't .,. i I 1, 70.0 I I 11 I

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=

~ 60.0 I I

I

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CII 50.0 40.0 30.0 20.0 1:02 :00 PM 1:03 :00 PM 1:04:00PM 1:05:00PM 1:06:00PM 1:07:00 PM Time Figure 65. Time history from SLM ANO 02 for siren 2213

II

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Figure 66. Data collection sheet for SLM ANO 02 for siren 2213

Far-Field Measurement of Siren 3Z5 from Sound Leve Meter ANO 03 This SLM was placed on the side of an unnamed road just north of Elliot Pl., off of Rte. 7. The time history is provided in Figure 67, with the hand-written data sheet provided in Figure 68.

Unfortunately, the siren signal was not clearly visible in the time history and was not 10 dB above the background noise. Background noise in this area was in the mid 60 dBC range.

100.0

- - -C-Weight

- 500 Hz+ 630 Hz 90.0 80.0

. Possible Siren Signal I I I \

,,,I

  • 70.0 ~ ,,

I I iii \

. , ,,I

~ 60.0 "ii CII 50.0 40.0 30.0 20.0 1:02:00 PM 1:03:00PM 1:04:00PM 1:05:00PM 1:06:00PM 1:07:00 PM Time Figure 67. Time history from SLM ANO 03 for siren 2213

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\)~~Cl, : 06/1.J..tt ~OJJ C5Yv c,I +- ~o s~~ ru*-J~------1 N\tAu *. ftt."60 03

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A N

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  • Figure 68. Data collection sheet for SLM ANO 03 for siren 2213

Appendix A- Acoustics, Perception, and the Weighting Scales Perception of sound involves two main factors - amplitude and frequency. Amplitude is the measure of the sound's volume, while frequency is often described as the 'pitch' of the sound. For amplitude, sound is generally described using the logarithmic decibel scale, which uses the symbol dB. The 'd' is lowercase to represent 'deci' for a factor of 10, and the uppercase 'B' comes from the proper name in honor of Alexander Graham Bell. Zero decibels (O dB) is defined as the threshold of human hearing. An increase of 10 dB is perceived as roughly twice as loud, and a level of 120 dB is at the threshol d of pain.

In terms of frequency, humans can hear sounds in a frequency range from about 20 Hz (a very low rumble) to 20,000 Hz (a high-pitched whine). Our best hearing is centered around the frequencies most common in human voices, near 1,000 Hz. Because sound is so complex and has so many features, it is difficult to quantify a complex, time-varying signal with a single number. How does a noise at 20,000 Hz compare to a noise at 1,000 Hz?

To reduce the complexity, single number metrics are used. These metrics work by applying weightings to sounds of different frequencies. These weighting factors allow us to combine the noise from all frequencies into a single number by including a penalty (or addition) to certain frequencies, better representing human perception. The two most widely used weighting factors are the A-weighting, designated by dBA, and the C-weighting, designated by dBC. If no weighting is used, the am plitude is designated simply by dB. Figure 69 is a graph showing both the A and C weighting factors used to compute dBA and dBC values.

Frequency (Hz) 100 1000 10000 0.00

-5.00 i-10.00 0

- A-Weight ti ca - C-Weight

~ -15.00 C

.c

_gp 3: -20.00

-25.00

-30.00

-35.00 Figure 69. A and C frequency weighting.

The A-weighted factors, shown in blue in Figure 69, represents how the average human perceives sounds at normal, speaking amplitudes. We have the best hearing in the range from about 1,000 Hz to 5,000 Hz, and we have poor hearing at the very high and very low frequencies. A-weighted sound levels are the most commonly used when describing sound. Typical SLM tools and phone apps will often provide the A-weighted levels.

The C-weighting, shown in red in Figure 69, represents how humans perceive high amplitude sound. If the noise we hear is loud, our ear responds differently than for quieter sounds. At higher amplitudes, people can hear frequencies between 100 Hz and 5,000 Hz at about the same amplitude. This means that our ear responds better when the sound is louder - proof that music does sound better if it is played loud. For siren analysis, FEMA recommends using the C-weighting scale for descriptions of siren sound levels.

Appendix B - Testing Procedures for Measuring the Acoustical Output of a System Siren Test Overview:

The purpose of this measurement protocol is to collect acoustical data using hand-held sound level meters to characterize the sound produced from a full-scale siren system test Test Schedule and Procedure:

Please plan on arriving at your location at least 45 minutes before the test to ensure that you have time to find the spot and park your car and set up the equipment. Each measurement location has been selected so that the sound level should not be excessive. No hearing protection will be needed. In addition, each tester will be required to completely fill in the lower half of their datasheets, starting with the drawings.

At your location, you should find a good level spot away from any major vertical surfaces such as walls, large boulders, or even cars. The requirement is to be at least 50 feet from any such objects, and farther is better. Once the exact location has been selected, set up the two tripods a few feet apart. Then carefully mount both the Sound Level Meter (SLM) and the weather station to the tripods. For the weather station, please follow the instructions attached for assembling and mounting the weather vane and weather station.

The microphone of the SLM should be 5 feet above the ground (mark the actual meter height on your datasheet). Use the tape measure to make sure that the height of the microphone is correct. The weather station should be mounted as high as the tripod will normally reach.

Make sure that the weather station is level by adjusting the tripod such that the spirit level is centered. Once the weather station is properly set up make sure to open the impeller cover so that the system can collect wind speed data. Finally, please snap at least three pictures showing the measurement set-up in relation to the things around it from different vantage points.

After the test equipment is set up, please take a few moments to draw the top-down plan view of your measurement location, including all buildings, vehicles, and walls within 300 feet. Make sure to note where the meter is in relation to these and all major roads. In addition, please provide a brief identifying description so that someone else could find this same spot again (assuming they were in the right general location). For example, '75 feet in front of 32 W.

Walnut St.'

The measurement should be started at least 10 minutes before all the sirens sound off. First, turn the weather station on and then turn on your SLM. After the meter has started up (which may take a few moments for some of the meters), start the meter recording data.

Before the siren sounding, please record on the datasheet what the main source of background noise is (such as traffic, a lawnmower or dogs barking), what the ambient noise level is, and the current wind speed, direction, and temperature.

During the test, all cell phones should be turned off, and please refrain from talking while the meter is recording data. During the measurement observe the SLM and keep a note of the highest noise level recorded during the test. If this was caused by something other than the sirens (a barking dog for instance) please note that on the datasheet.

After the siren sounding is complete check and record the ambient noise level again. Please wait for a full 10 minutes after the sirens finish siren sounding before stopping the meters and turning them off. Then please return the meter and weather station with the datasheet to Dr.

Ikelheimer.