ORDER CHANGE FEDERAL AVIATION ADMINISTRATION JO … · In compliance with the latest editions of Orders 1100.161, Air Traffic Safety Oversight, and JO 1000.37, ATO Safety Management

DISTRIBUTION: 53AH, SC00 INITIATED BY: AJW-147

CHANGE U.S. DEPARTMENT OF TRANSPORTATION

FEDERAL AVIATION ADMINISTRATION

ORDER JO 6310.30B

CHG 2 Air Traffic Organization Policy Effective Date:

07/17/2018 Implementation Date: 10/20/2018

SUBJ: Maintenance Handbook for Airport Surveillance Radar, ASR-11 Facilities 1. Purpose. This change transmits revised pages to Order JO 6310.30B, Maintenance Handbook for Airport Surveillance Radar, ASR-11 Facilities. This directive implements Configuration Control Decision (CCD) No. N37080 Update 6310.30B to include Technical Refresh Segment 2 changes. 2. Who This Change Affects. This document requires actions by the Airway Transportation System Specialist (ATSS) at operational facilities with Facility, Service, and Equipment Profile (FSEP) equipment: ASR-11 Digital Airport Surveillance Radar and ASR-11 Military GPN-30.

a. FAA Personnel.

(1) For electronic copies, FAA personnel can use one of the following websites to locate this order.

(a) On the Technical Library website at: http://nas.amc.faa.gov/phoenix/views/technicalLibrary.xhtml.

(b) On the Directives website at: https://employees.faa.gov/tools_resources/orders_notices/.

(c) From the My FAA website, select “Tools and Resources” then select 'Orders and Notices'.

(d) On the National Airway Systems Engineering Maintenance Handbooks and Notices CD-ROM. Subscribe to the bi-yearly CD-ROM at http://nas.amc.faa.gov/phoenix/views/documentRequest.xhtml.

(e) The ATSS and all administrative personnel must subscribe to the Auto-Notifications Services for electronic library release notifications at http://technet.faa.gov/. This document can be printed for local use as required.

(2) The field office must keep accurate FSEP records, Logistics and Inventory System (LIS) and Logistics Center Support System (LCSS) addresses per Order 6000.5D, Facility, Service, and Equipment Profile (FSEP).

(a) To update FSEP information, visit https://employees.faa.gov/org/linebusiness/ato/operations/technical_operations/ajw1/ajw1b/fsep/.

(b) To update LCSS information, visit this link: https://lcss.faa.gov/lcss.

http://nas.amc.faa.gov/phoenix/views/technicalLibrary.xhtml

https://employees.faa.gov/tools_resources/orders_notices/

http://nas.amc.faa.gov/phoenix/views/documentRequest.xhtml

http://technet.faa.gov/

https://employees.faa.gov/org/linebusiness/ato/operations/technical_operations/ajw1/ajw1b/fsep/

https://lcss.faa.gov/lcss

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(c) To update LIS information, contact the Logistics Management Specialist (LMS) point of contact within the Service Centers or Robert Walker, AJW Operations Support, AJW-1, Point of Contact at the FAA Logistics Center.

(3) The Periodic Maintenance/Certification Scheduling (PMS) database is maintained by the Office of Primary Responsibility (OPR). The release of this document notifies the field of an update to the Remote Monitoring and Logging System (RMLS) National PMS database. An RMLS Task Glossary Report will be available on the Technical Library for cross referencing the Task Number to the Chapter 4 paragraph in approximately five working days after release of this order.

b. Department of Defense (DoD).

(1) DoD customers with access to the AJW-147 Second Level Engineering website can locate this order at https://www.faa.gov/aos/aos232/main.cfm.

(2) For DoD customers who have questions related to the maintenance handbook, contact Second Level Engineering at (405) 954-4271.

3. Risks.

a. Operational. In compliance with the latest edition of Order JO 6000.50, National Airspace System (NAS) Integrated Risk Management, specialists should assess local system configurations and maintenance actions using the information, instructions or procedures delivered with this MTHB page change for Operational Risk Management (ORM) to the NAS. No operational risks were identified during the evaluation of the deliverables associated with this MTHB change.

b. Safety. In compliance with the latest editions of Orders 1100.161, Air Traffic Safety

Oversight, and JO 1000.37, ATO Safety Management System, local safety assessment is required when conducting the maintenance and operations activities contained in the deliverables associated with this MTHB change. A National Safety Risk Management (SRM) Report for the deliverables associated with this MTHB change is available at http://nas.amc.faa.gov/phoenix/views/technicalDocument.xhtml?&file=6310_30B_mthb_chg2_srmrpt.pdf.

c. Security. In compliance with the latest edition of Order 1370.121, FAA Information Security and Privacy Program and Policy, the FAA must ensure that security controls are implemented and commensurate with the risk and magnitude of the harm that would result from the loss, misuse, denial of service, unauthorized access, or modification of Federal information assets. No security risks were identified during the evaluation of the deliverables associated with this MTHB change.

4. Implementation Date. This MTHB change must be implemented by 10/20/2018. All facilities nationwide must comply with these changes by the implementation date. The changes may be implemented any time after the effective date, but must be implemented by the implementation date. If the implementation date occurs during a completed task interval window, then follow the new guidance for the certification or maintenance task(s) at the next regularly scheduled interval. 5. Disposition of Transmittal. Retain the change transmittal after change pages are incorporated into the MTHB. File in front of the MTHB.

https://www.faa.gov/aos/aos232/main.cfm

http://nas.amc.faa.gov/phoenix/views/technicalDocument.xhtml?&file=6310_30B_mthb_chg2_srmrpt.pdf

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6. Explanation of Changes. This page change incorporates changes resulting from Technical Refresh Segment 2 System Control and Data Interface (SCDI) Replacement program and upgrading.

a. Paragraphs 4-20, 5-40, 5-41 Technical Refresh Segment 2 SCDI Replacement program

b. Paragraphs 3-4, 5-53, 5-92 Correct pulse width tolerance values

c. Paragraphs 3-120, 5-83 Add a procedure to set the current time on radar data recorder test equipment

d. Paragraphs 3-7, 3-30, 4-10, 4-11, 4-14, 4-73 Correct minor typographical errors

e. Paragraphs 5-18, 5-27, 5-31, 5-34, 5-38, 5-70 Clarify and correct several preventative maintenance procedures

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for David E. Spencer Director, Operations Support

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Table of Contents (Continued)

Paragraph Page

Section 4. MSSR Other Maintenance Tasks ......................................................................... 4-20 4-40. MSSR LVA Antenna. .......................................................................................... 4-20 4-41. LVA Antenna Fittings and Connectors. ............................................................... 4-20 4-42. Monopulse Remote Site Monitor (MRSM) .......................................................... 4-20 4-43. MSSR Equipment Cabinets. ............................................................................... 4-21 4-44. MSSR System Performance Analysis................................................................. 4-21 4-45. Probability of Detection (PD) .............................................................................. 4-21 4-46. Variable Site Parameter (VSP) Verification ........................................................ 4-22 4-47. Variable Site Parameter (VSP) Backup .............................................................. 4-22 4-48. and 4-49. Reserved. .................................................................................................. 4-22

Section 5. Data Communication Systems ............................................................................. 4-23 4-50. Surveillance Data Translator (SDT). ................................................................... 4-23 4-51. Digital Video Generator (DVG). .......................................................................... 4-23 4-52. Computer Time Synchronization. ....................................................................... 4-25 4-53. through 4-59. Reserved. ............................................................................................ 4-25

Section 6. DMS MSSR Performance Checks ........................................................................ 4-26 4-60. Transmitter. ........................................................................................................ 4-26 4-61. Receiver. ............................................................................................................ 4-29 4-62. through 4-69. Reserved ............................................................................................. 4-29

Section 7. DMS MSSR Other Maintenance Tasks ................................................................ 4-30 4-70. MSSR LVA Antenna. .......................................................................................... 4-30 4-71. LVA Antenna Fittings and Connectors. ............................................................... 4-30 4-72. Monopulse Remote Site Monitor (MRSM) .......................................................... 4-30 4-73. MSSR Equipment Cabinets. ............................................................................... 4-30 4-74. MSSR System Performance Analysis................................................................. 4-31 4-75. Probability of Detection (PD) .............................................................................. 4-31 4-76. Variable Site Parameter (VSP) Verification ........................................................ 4-31 4-77. Variable Site Parameter (VSP) Backup .............................................................. 4-31 4-78. and 4-79. Reserved ................................................................................................... 4-31

Chapter 5 Maintenance Procedures ...................................................................................................5-1 5-1. General. ............................................................................................................... 5-1 5-2. Remote Maintenance Monitoring. ......................................................................... 5-1 5-3. Test Equipment Calibration. ................................................................................. 5-1 5-4. Manufacturer’s Documentation. ............................................................................ 5-1 5-5. through 5-9. Reserved. .................................................................................................. 5-1

Section 1. PSR Performance Check Procedures .................................................................... 5-2 5-10. Point of Control Configuration. ............................................................................. 5-2 5-11. Termination of Test. ............................................................................................. 5-3 5-12. Measuring PSR’S Transmitter Performance Parameters Using The Operator

Maintenance Terminal (OMT). .............................................................................. 5-4 5-13. PSR Receiver Performance Parameters Using The OMT. ................................... 5-6 5-14. PSR Receiver End to End Test for Noise/Level, and Phase Stability Using The

Monitor and Control OMT. .................................................................................... 5-7

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Paragraph Page

5-15. PSR Transmitter Frequency. ................................................................................ 5-9 5-16. PSR Transmitter Output Power Measurement. ................................................... 5-12 5-17. PSR Transmitter Power Supplies. ...................................................................... 5-19 5-18. PSR Transmitter Radio Frequency (RF) Drivers and Amplifiers. ........................ 5-20 5-19. Verification and Calibration of PSR Transmitter Power Certification Parameters. 5-24 5-20. Verification of PSR Receivers Sensitivity Minimum Discernable Signal (MDS)

Certification Parameters, and Calibration of Operator’s OMT for MDS. .............. 5-26 5-21. Measuring PSR’s Transmitter Pulse Width and Bandwidth Using External Test

Equipment. ......................................................................................................... 5-28 5-22. Measuring PSR’s Receiver Exciter (REX) Units A and B’s A11A2 Power Supply

Voltages. ............................................................................................................ 5-35 5-23. ASDP REX Weather Clutter Maps Verification ................................................... 5-36 5-24. and 5-25. Reserved. .................................................................................................. 5-38 5-26. PSR Short Pulse Sensitivity Time Control (STC) Verification. ............................ 5-39 5-27. PSR Variable Site Parameters (VSP) Verification. ............................................. 5-41 5-28. PSR Antenna’s Voltage Standing Wave Ratio (VSWR). ..................................... 5-44 5-29. Pedestal Local Control Panel Power Supplies. ................................................... 5-48 5-30. PSR Probability of Detection (PD) for Permanent Echoes (PE) .......................... 5-50 5-31. Variable Site Parameters (VSP) Backup – Ultra5 Workstations .......................... 5-51 5-32. Measuring Receiver Protector Timing and Suppression. .................................... 5-66 5-33. Reserved ............................................................................................................ 5-73 5-34. PSR / MSSR System Performance Analysis (FAA Sites Only). .......................... 5-73 5-35. Master Safety Switch and Safety Interlock Test and Inspection. ......................... 5-77 5-36. Antenna/Pedestal Inspection. ............................................................................. 5-82 5-37. Compressor Dryer Regulated Output Pressure Verification. ............................... 5-98 5-38. Variable Site Parameters (VSP) Backup – T2000 Workstations ......................... 5-99 5-39. File Transfer ..................................................................................................... 5-109 5-40. Variable Site Parameters (VSP) Backup – Z440 Workstations ......................... 5-110 5-41. through 5-49. Reserved .......................................................................................... 5-110K

Section 2. MSSR Performance Check Procedures .......................................................... 5-111 5-50. Monopulse Secondary Surveillance Radar (MSSR) Transmitter Frequency. .... 5-111 5-51. MSSR Transmitter and Receiver Performance Parameters Using the OMT ..... 5-112 5-52. Reserved. ......................................................................................................... 5-113 5-53. MSSR Interrogator Forward and Reverse Power and Pulse Width and Spacing

Measurements. ................................................................................................ 5-114 5-54. MSSR Interrogator Pulse Spectrum Measurement ........................................... 5-119 5-55. Reserved. ......................................................................................................... 5-121 5-56. Calibration of MSSR CMS TX Monitor Screen and OMT Radar Certification

Parameters Screen for MSSR TX Forward Output Power. ............................... 5-121 5-57. Calibration of MSSR CMS TX Monitor Screen and OMT Radar Certification

Parameters Screen for MSSR TX Reverse Output Power. ............................... 5-125 5-58. MSSR Receiver Synthetic Target Calibration and Verification – using MBTS. .. 5-133 5-59. MSSR Digital System Sensitivity (DSS). ........................................................... 5-138 5-60. MSSR Receiver Minimum Receiver Sensitivity Verification – using MBTS. ...... 5-142 5-61. MSSR Probability of Detection (Pd) for SSR PARROT. .................................... 5-146 5-62. MSSR Variable Site Parameters (VSP) Verification. ......................................... 5-147 5-63. MSSR Interrogator Power Supply Voltage Verification. .................................... 5-152 5-64. MSSR Pulse Repetition Frequency (PRF) Verification. .................................... 5-153

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Paragraph Page

5-65. MSSR Receiver Synthetic Target Calibration and Verification – using signal generator. ..................................................................................... 5-155

5-66. MSSR Receiver Minimum Receiver Sensitivity Verification – using signal generator .................................................................................... 5-155F

5-67. Reserved ......................................................................................................... 5-155I 5-68. MSSR Configuration Set Backup..................................................................... 5-155J 5-69. Reserved. ......................................................................................................... 5-156 5-70. Edit MSSR Transparent Mode Command (TMC) File. ...................................... 5-157 5-71. MSSR Remote Site Monitor (MRSM) Reply Verification. .................................. 5-159 5-72. Antenna Pattern Measurement (APM) Procedure. ........................................... 5-161 5-73. through 5-79. Reserved. .......................................................................................... 5-163

Section 3. Special Task Procedures ................................................................................. 5-164 5-80. Fiber Optic Measurements. .............................................................................. 5-164 5-81. Digital Video Generator (DVG) Output Parameter Measurements. ................... 5-172 5-82. Digital Video Generator (DVG) and Control and Monitor Console (CMC) File

Verification. ...................................................................................................... 5-177 5-83. Clock Synchronization – Configuration and Verification of Date and Time. ....... 5-183 5-84. through 5-89. Reserved. .......................................................................................... 5-190

Section 4. DMS MSSR Performance Check Procedures ................................................. 5-187 5-90. Transmitter Frequency. .................................................................................... 5-187 5-91. Transmitter and Receiver Performance Parameters Using the OMT ................ 5-188 5-92. Interrogator Forward and Reverse Power and Pulse Characteristics Measurements.

......................................................................................................................... 5-190 5-93. Calibration of DMS MSSR CMS TX Monitor Screen and OMT Radar Certification

Parameters Screen for MSSR TX Forward Output Power. ............................... 5-198 5-94. Calibration of DMS MSSR CMS TX Monitor Screen and OMT Radar Certification

Parameters Screen for MSSR TX Reverse Output Power. ............................... 5-201 5-95. DMS MSSR Receiver Synthetic Target Calibration and Verification –

using MBTS. .................................................................................................... 5-209 5-96. DMS MSSR Digital System Sensitivity (DSS). .................................................. 5-215 5-97. DMS MSSR Receiver Minimum Receiver Sensitivity Verification –

using MBTS ..................................................................................................... 5-219 5-98. Probability of Detection (PD) for SSR PARROT. .............................................. 5-223 5-99. Variable Site Parameters (VSP) Verification. .................................................... 5-224 5-100. Interrogator Power Supply Voltage Verification. ............................................... 5-229 5-101. DMS MSSR Pulse Repetition Frequency (PRF) Verification. ............................ 5-230 5-102. DMS MSSR Configuration Set Backup. ............................................................ 5-232 5-103. Reserved. ......................................................................................................... 5-233 5-104. Edit MSSR Transparent Mode Command (TMC) File. ...................................... 5-234 5-105. MSSR Remote Site Monitor (MRSM) Reply Verification. .................................. 5-235 5-106. Antenna Pattern Measurement (APM) Procedure. ........................................... 5-237 5-107. Point of Control Configuration. ......................................................................... 5-240 5-108. Termination of Test. ......................................................................................... 5-242 5-109. DMS MSSR Interrogator Pulse Spectrum Measurement .................................. 5-243

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Paragraph Page

5-110. DMS MSSR Receiver Synthetic Target Calibration and Verification – using signal generator. ..................................................................................... 5-246

5-111. DMS MSSR Receiver Minimum Receiver Sensitivity Verification – using signal generator ...................................................................................... 5-251

Chapter 6 Flight Inspection .............................................................................................................6-1 6-1. General. ............................................................................................................... 6-1 6-2. Pre-Flight Inspection Preparation. ........................................................................ 6-1 6-3. Flight Inspection Participation. .............................................................................. 6-2 6-4. Post-Flight Inspection Actions. ............................................................................. 6-2

Appendix A. Certification Requirements ................................................................................ A-1 System and Subsystem Certification. .................................................................................... A-1

Appendix B. Glossary.............................................................................................................. B-1

List of Illustrations

Paragraph Page Figure 2-1 Radar Site Equipment Configuration 1 ....................................................................... 2-4 Figure 2-2 DMS MSSR CECE Radar Site Configuration 3 Equipment ........................................ 2-7 Figure 2-3 Indicator Site for Configuration 1 Equipment .............................................................. 2-9 Figure 2-4 Indicator Site for Configuration 3 Equipment ............................................................ 2-10 Figure 2-5 ASR-11 Networking Diagram ASDP Configuration 1 Equipment .............................. 2-12 Figure 2-6 ASR-11 Networking Diagram DMS MSSR Configuration 3 Equipment .................... 2-13 Figure 5-1 Frequency Measurement Point ................................................................................ 5-11 Figure 5-2 Forward Power Measurement Configuration ............................................................ 5-14 Figure 5-3 ASDP Trigger Connections ...................................................................................... 5-15 Figure 5-4 RF Amplifier and Driver Module J1 Locations .......................................................... 5-22 Figure 5-5 RF Measurement Test Equipment Set Up ................................................................ 5-23 Figure 5-6 Measure Middle of Detected Long Pulse .................................................................. 5-23 Figure 5-7 ASDP Trigger Connections ...................................................................................... 5-29 Figure 5-8 Power Meter Connection .......................................................................................... 5-30 Figure 5-9 Spectrum Analyzer Connection ................................................................................ 5-32 Figure 5-10 Bandwidth Measurement At –3 dB and –40 dB Points ............................................. 5-33 Figure 5-11 Weather Clutter Map (Example) ............................................................................... 5-38 Figure 5-12 Weather Clutter Map with Anomalies (Example) ...................................................... 5-38 Figure 5-13 Example: STC Curve On RDD ................................................................................. 5-40 Figure 5-14 ExamDiff Pro Icon .................................................................................................... 5-43 Figure 5-15 WS_FTP_Pro Main Screen ...................................................................................... 5-58 Figure 5-16 Weather Laptop Directory Structure ......................................................................... 5-59 Figure 5-17 Reserved. ................................................................................................................ 5-65 Figure 5-18 Reserved. ................................................................................................................ 5-65 Figure 5-19 Change Beam and STC Override Screen ................................................................ 5-68 Figure 5-20 Short Pulse Recovery Margin Measurements .......................................................... 5-69 Figure 5-21 Short Pulse Suppression Value Measurement ......................................................... 5-69 Figure 5-22 Long Pulse Recovery Margin Measurement ............................................................. 5-71 Figure 5-23 Long Pulse Suppression Value Measurement .......................................................... 5-72 Figure 5-24 Antenna Pedestal Group Status and Control Screen ............................................... 5-79

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Table of Contents (Continued) List of Illustrations (Continued)

Paragraph Page Figure 5-25 Drive Motor .............................................................................................................. 5-84 Figure 5-26 Clutch Parts Locations ............................................................................................. 5-86 Figure 5-27 Clutch Lubrication Fittings and Alignment Guides .................................................... 5-86 Figure 5-28 Pedestal Oil Sump Parts Locations .......................................................................... 5-87 Figure 5-29 Drive Unit Assembly ................................................................................................. 5-89 Figure 5-30 Brush Block Assembly ............................................................................................. 5-90 Figure 5-31 Pedestal ................................................................................................................... 5-91 Figure 5-32 PSR Antenna Assembly Parts Locations.................................................................. 5-92 Figure 5-33 Tilt Adjustment Screw .............................................................................................. 5-93 Figure 5-34 LVA Hardware.......................................................................................................... 5-95 Figure 5-35 AJW External Link Homepage ................................................................................5-110 Figure 5-36 Upload Adapt Link ...................................................................................................5-110 Figure 5-36A Upload Site Adapt Interface ................................................................................. 5-110A Figure 5-36B Download Site Adapt Interface ............................................................................. 5-110B Figure 5-36C Weather Laptop Directory Structure ..................................................................... 5-110K Figure 5-37 MSSR Forward Power/Pulse Width and Spacing Measurement Equipment Setup .5-116 Figure 5-38 Typical Pulse Spectrum ..........................................................................................5-120 Figure 5-39 MSSR Reverse Power OMT Calibration Power Level Setup ...................................5-128 Figure 5-40 MSSR Reverse Power OMT Calibration Power Injection ........................................5-129 Figure 5-41 MSSR Receiver Signal Video Processing ...............................................................5-133 Figure 5-42 MSSR Receiver Test Target Calibration Equipment Setup......................................5-136 Figure 5-43 Sum Video Monitor Jack Signal ..............................................................................5-137 Figure 5-44 MSSR Test Equipment Configuration for DSS ........................................................5-140 Figure 5-45 MSSR Receiver Sensitivity Equipment Setup .........................................................5-144 Figure 5-46 MSSR Receiver Example of Normal Signal .............................................................5-144 Figure 5-47 MSSR Receiver Example Minimum Sensitivity ........................................................5-145 Figure 5-48 Display Build State Command .................................................................................5-149 Figure 5-49 Display All Dynamic Parameters Command ............................................................5-149 Figure 5-50 Display Processing Switches Command .................................................................5-150 Figure 5-51 Display Inhibited Tests Command ...........................................................................5-150 Figure 5-51A MSSR Receiver Signal Video Processing ...............................................................5-155 Figure 5-51B MSSR Receiver Test Target Calibration Equipment Setup................................... 5-155B Figure 5-51C Sum Video Monitor Jack Signal ........................................................................... 5-155D Figure 5-51D MSSR Receiver Sensitivity Equipment Setup ...................................................... 5-155G Figure 5-51E MSSR Receiver Example of Normal Signal .......................................................... 5-155H Figure 5-51F MSSR Receiver Example Minimum Sensitivity ..................................................... 5-155H Figure 5-52 MRSM Replies ........................................................................................................5-160 Figure 5-53 Normal Amplitude APM ...........................................................................................5-162 Figure 5-54 APM Displaying Signal Clipping ..............................................................................5-163 Figure 5-55 Single-Mode Fiber Optic Equipment Setup .............................................................5-165 Figure 5-56 Single-Mode Fiber Optic Flexswitch (6551-2) - Radar Site .....................................5-166 Figure 5-57 Single-Mode Fiber Optic Flexswitch (6110-2) - Indicator Site ..................................5-167 Figure 5-58 Single-Mode Indicator Site - Fiber Optic Configuration ............................................5-168 Figure 5-59 Single-Mode Radar Site - Fiber Optic Configuration ................................................5-168

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Table of Contents (Continued) List of Illustrations (Continued)

Paragraph Page Figure 5-60 Single-Mode Radar Site - Fiber Optic Power Measurement ....................................5-169 Figure 5-61 Single-Mode Indicator Site - Fiber Optic Power Measurement ................................5-171 Figure 5-62 Typical DVG Interface .............................................................................................5-173 Figure 5-62A Radar Data Recorder ......................................................................................... 5-1876A Figure 5-62B Radar Data Recorder connection to the Radar Offsite LAN A (an example) ...... 5-1876A Figure 5-62C Laptop direct network connection to the Radar Data Recorder ...............................5-188 Figure 5-62D Radar Data Recorder Home Page ..........................................................................5-189 Figure 5-62E System status returned in yellow box (on Status button pressed) ...........................5-189 Figure 5-62F Setting system time in GMT (press Set to change time) ..........................................5-190 Figure 5-63 Forward Power/Pulse Characteristics Measurement Equipment Setup ...................5-192 Figure 5-64 Pulse Train Display .................................................................................................5-193 Figure 5-65 P6 Pulse Width Measurement .................................................................................5-194 Figure 5-66 P6 1st Sync Phase Reversal and P5 Position ..........................................................5-195 Figure 5-67 MSSR Reverse Power OMT Calibration Power Level Setup ...................................5-203 Figure 5-68 MSSR Reverse Power OMT Calibration Power Injection ........................................5-204 Figure 5-69 MSSR Receiver Signal Video Processing ...............................................................5-209 Figure 5-70 MSSR Receiver Test Target Calibration Equipment Setup......................................5-211 Figure 5-71 Sum Video Monitor Jack Signal ..............................................................................5-212 Figure 5-72 Synthetic Target Replies .........................................................................................5-214 Figure 5-73 MSSR Test Equipment Configuration for DSS ........................................................5-217 Figure 5-74 MSSR Receiver Sensitivity Equipment Setup .........................................................5-220 Figure 5-75 MSSR Receiver Example of Normal Signal .............................................................5-221 Figure 5-76 MSSR Receiver Example Minimum Sensitivity ........................................................5-221 Figure 5-77 Display Build State Command .................................................................................5-225 Figure 5-78 Display Inhibited Tests Command ...........................................................................5-226 Figure 5-79 Offline Parameter Editing Tool ................................................................................5-227 Figure 5-80 MRSM Reply Message ...........................................................................................5-236 Figure 5-81 Normal Amplitude APM ...........................................................................................5-238 Figure 5-82 APM Displaying Signal Clipping ..............................................................................5-239 Figure 5-83 Typical Pulse Spectrum ..........................................................................................5-245 Figure 5-84 MSSR Receiver Signal Video Processing ...............................................................5-246 Figure 5-85 MSSR Receiver Test Target Calibration Equipment Setup......................................5-248 Figure 5-86 Sum Video Monitor Jack Signal ..............................................................................5-249 Figure 5-87 MSSR Receiver Sensitivity Equipment Setup .........................................................5-252 Figure 5-88 MSSR Receiver Example of Normal Signal .............................................................5-253 Figure 5-89 MSSR Receiver Example Minimum Sensitivity ........................................................5-253

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List of Tables

Paragraph Page Table 5-1. Values for Transmitter Frequencies ......................................................................... 5-10 Table 5-2 Example of A11A2 Power Supply Voltages .............................................................. 5-35 Table 5-3. Typical Adaptation Test Directory Listing ................................................................. 5-43 Table 5-4 VSWR Conversion Table ......................................................................................... 5-47 Table 5-5 Example of Encoder-X Power Supply Voltages ........................................................ 5-48 Table 5-6 Example of Encoder-Y Power Supply Voltages ........................................................ 5-48 Table 5-7 Example of Polarizer Power Supply (PS3) Voltages ................................................ 5-49 Table 5-8 Example of Weather Beam Switch Power Supply (PS4) Voltages............................ 5-49 Table 5-9 Example of Typical Values of PE ............................................................................. 5-50 Table 5-10 SIU Maximum Range Settings ................................................................................. 5-75 Table 5-11 VSWR Conversion Table ........................................................................................5-118 Table 5-12 MSSR Dynamic Parameters Offsets .......................................................................5-123 Table 5-13 MSSR Dynamic Parameters Offsets .......................................................................5-131 Table 5-14 SSR PARROT Typical Values .................................................................................5-147 Table 5-15 Single-Mode Fiber Optic Connection Table .............................................................5-167 Table 5-16 DVG-1 & DVG-2 Feeding ARTS IIE DDAS (ACP, ARP) Parameters -

Oscilloscope Verification .........................................................................................5-174 Table 5-17 DVG-3 & DVG-4 Feeding DBRITE (ACP, ARP) Parameters -

Oscilloscope Verification .........................................................................................5-174 Table 5-18 DVG-1 & DVG-2 Feeding ARTS IIE DDAS (Video) Parameters – Oscilloscope

Verification ..............................................................................................................5-175 Table 5-19 DVG-3 & DVG-4 Feeding DBRITE (Video) Parameters -

Oscilloscope Verification .........................................................................................5-176 Table 5-20 DVG-5 Feeding RADS (Video) Parameters -Oscilloscope Verification ....................5-176 Table 5-21 DVG-6 Through DVG-12 (If Applicable) Feeding RADS (Video) Parameters -

Oscilloscope Verification .........................................................................................5-177 Table 5-22 Example of dvg-cp.ini Data File ...............................................................................5-180 Table 5-23 VSWR Conversion Table ........................................................................................5-197 Table 5-24 MSSR Dynamic Parameters Offsets .......................................................................5-199 Table 5-25 MSSR Dynamic Parameters Offsets .......................................................................5-207 Table 5-26 SSR PARROT Typical Values .................................................................................5-223 Table A-1. Airport Surveillance Radar (ASR-11) System ............................................................. A-3

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Table of Contents (Continued) List of Forms

Paragraph Page Form 5-1 MSSR Transmit Power Output Radar Certification Parameters Screen Calibration

Worksheet for Procedure 5-56 ................................................................................5-124 Form 5-2 MSSR Transmit Reverse Power Radar Certification Parameters Screen Calibration

Worksheet for Procedure 5-57 ................................................................................5-132 Form 5-3 MSSR Transmit Power Output Radar Certification Parameters Screen Calibration

Worksheet for Procedure 5-93 ................................................................................5-200 Form 5-4 MSSR Transmit Reverse Power Radar Certification Parameters Screen Calibration

Worksheet for Procedure 5-94 ................................................................................5-208

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Section 1. Description

2-4. Typical ASR-11 Radar Site Equipment Configuration 1.

a. Functionally the ASR-11 is divided into two specific areas; the radar site equipment, and the indicator site equipment. Figure 2-1 Radar Site Equipment identifies the various subsystems and interconnecting peripheral equipment that supports a typical radar site configuration.

b. The radar site configuration 1 equipment consists of the following:

(1) Azimuth Data Group

(2) Primary Surveillance Radar (PSR)

(3) Monopulse Secondary Surveillance Radar (MSSR) or DMS MSSR

(4) Site Control and Data Interface (SCDI) with Operator Maintenance Terminal (OMT)

(5) MSSR Control and Monitor System (CMS)

(6) Facilities Monitoring and Control (FMAC)

(7) Communication Server

(8) Radar Control Panel (RCP)

(9) Uninterruptible Power Source (UPS)

(10) Engine Generator

(11) Fiber Optic Hub and Transmitter 2-5. ASR-11 Functional Elements.

The ASR-11 functional elements, figure 2-1, includes the ASR-11 prime mission equipment (PME) and facilities. The ASR-11 PME includes the primary surveillance radar (PSR) with weather channels, monopulse secondary surveillance radar (MSSR), PSR and MSSR beacon antennas, operator maintenance terminals (OMTs), surveillance data displays, modems and surveillance data translator equipment (DTE) with video control units. The site facilities include tower, radome (when necessary), equipment shelter/housing with heating, ventilation and air conditioning (HVAC) and power distribution system, uninterruptible power supply (UPS), engine generator and interconnecting cabling within the ASR-11. Other ancillary equipment include the PSR moving target indicator (MTI) reflectors with towers and housing, the MSSR remote system monitor (MRSM) with tower and housing and local and remote control panels.

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Figure 2-1 Radar Site Equipment Configuration 1

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Figure 2-2 DMS MSSR CECE Radar Site Configuration 3 Equipment

* *

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2-9. ASR-11 Indicator Site.

a. Figures 2-3 and 2-4 Indicator Site Equipment identify the various subsystems and interconnecting peripheral equipment that supports the indicator site subsystems.

b. The indicator site equipment for configuration 1 equipment consists of the following:

(1) Remote OMT (2) Surveillance Data Translator (SDT)

(3) Control and Monitoring Console (CMC) Terminal

(4) Radar Control Panel (RCP)

(5) Digital Video Generator (DVG)

(6) Video Distribution Control Unit (VDCU)

(7) Fiber Optic Hub and Transmitter

(8) System Interface Unit (SIU)

(9) ARTS-IIE, Radar Alphanumeric Display System (RADS), Digital Bright Radar

Indicator Tower (DBRITE), and Digital Video Mapper, STARS or TAMR

c. The indicator site equipment for configuration 3 equipment consists of the following:

(1) Remote OMT (2) Radar Control Panel (RCP)

(3) Fiber Optic Hub and Transmitter

(4) System Interface Unit (SIU) (If Used) (5) DASR Routers (If Used)

(6) STARS Automation System

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Chapter 3 Standards and Tolerances 3-1. General.

a. This chapter prescribes the standards and tolerances for the Airport Surveillance Radar model 11 (ASR-11) facilities, as defined and described in the latest edition of Order 6000.15. All key performance parameters and/or key inspection elements are clearly identified by an arrow (→) placed to the left of the applicable item.

b. Entries in the reference paragraph column refer to either an instruction book or this handbook. An instruction book reference is identified by a section and paragraph (for example, 6.2.3) or a table designator. A handbook reference is identified by a paragraph number only. A Technical Instruction book reference is identified by the book number and title, for example, TI 6310.57, ASR-11 S-Band, Solid State Primary Surveillance Radar.

c. The ASR-11 system consists of a Primary Surveillance Radar (PSR), a Monopulse Secondary Surveillance Radar (MSSR) or Diminishing Manufacturing Source Monopulse Secondary Surveillance Radar (DMS MSSR) and ancillary equipment.

(1) The standards and tolerances for the PSR System are contained in section 1 through

section 3.

(2) The standards and tolerances for the System Interface are contained in section 4.

(3) The standards and tolerances for the MSSR are contained in sections 5 through 10.

(4) The standards and tolerances for the Digital Video Generator (DVG) s are contained in section 11.

(5) The standards and tolerances for the ASR-11 common equipment are in section 12.

(6) The standards and tolerances for the DMS MSSR are contained in section 13 through

section 18.

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Section 1. PSR Transmitter – Standards and Tolerances

Parameter Reference Standard Tolerance/Limit Paragraph Initial Operating

→ 3-2. Power Output. a. Long Pulse (LP) Forward

Power

(1) 8 of 8 RF Amp Modules ...... 5-16 Commissioned

Value ≥ 42.5 dBW ≥ 40.4 dBW

(2) 7 of 8 RF Amp Modules ..... 5-12

5-16 Commissioned


b. Short Pulse (SP) Forward

Power

(1) 8 of 8 RF Amp Modules ..... 5-16 Commissioned


(2) 7 of 8 RF Amp Modules ..... 5-12

5-16 Commissioned


→ 3-3. Voltage Standing Wave Ratio

(VSWR).

a. VSWR Calculated Using OMT

Antenna Reverse Power ........... 5-12 Commissioned

Value Same as standard

≤1.5:1

b. VSWR Calculated Using

Antenna Reverse Power ........... 5-28 Commissioned


≤1.5:1

→ 3-4. Pulse Width (PW). a. Transmitted Short Pulse PW

at 3 dB points ............................ 5-21 1.8 µs Standard

- 0.70 µs + 1.10 µs

Standard - 0.70 µs + 1.10 µs

b. Transmitted Long Pulse PW

at 3 dB points ............................ 5-21 89.0 µs Standard

± 4.0 µs Standard ± 4.0 µs

→ 3-5. Bandwidth. a. Bandwidth at 3 dB points ......... 5-21 Commissioned


≤ 1.9 MHz

b. Bandwidth at 40 dB points ....... 5-21 Commissioned


≤ 7.0 MHz

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Section 2. PSR Receiver and Processor – Standards and Tolerances (Continued)


→ 3-22. Phase Stability. a. Target LO Beam SP .................... 5-14 Commissioned

Value ≥ 55.0 dB Same as

Initial b. Target LO Beam LP ..................... 5-14 Commissioned


Initial c. Target HI Beam SP ...................... 5-14 Commissioned


Initial d. Target HI Beam LP ...................... 5-14 Commissioned


Initial e. Weather SP .................................. 5-14 Commissioned


Initial f. Weather LP .................................. 5-14 Commissioned


Initial 3-23. and 3-24. Reserved. 3-25. Short Pulse Sensitivity Time

Control (STC). 5-26 Commissioned

Value Same as Standard

± 3 dB

3-26. Reserved. 3-27. Receiver Power Supplies. a. Units 1 and 2: A11A2 Receiver

Exciter (REX) A/B

(1) Voltage: -8 Vdc ....................... 5-22 -8.00 Vdc ± 0.40 Vdc Same as

Initial (2) Voltage: +8 Vdc ...................... 5-22 +8.00 Vdc ± 0.40 Vdc Same as

Initial (3) Voltage: +18.5 Vdc ................. 5-22 +18.50 Vdc ± 0.90 Vdc Same as

Initial (4) Voltage: -18.5 Vdc .................. 5-22 -18.50 Vdc ± 0.90 Vdc Same as

Initial 3-28. Variable Site Parameters 5-27 Commissioned

Values Same as standard

Same as standard

3-29. REX Cabinet UPS (1A10, 2A10) N/A No “Failed

Battery” Indication

Same as standard

Same as standard

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Section 3. PSR System and Antenna Group – Standards and Tolerances


3-30. PSR Antenna Tilt Verification 5-36 Commissioned


Same as Standard

3-31. Compressor Dryer. a. Start/Stop Pressure (1) Compressor Start ................. Manufacturers

Handbook, Section 7.0

20 psig ± 2 psig Same as initial

(2) Compressor Stop .................. Manufacturers

Handbook, Section 7.0

45 psig ± 2 psig Same as initial

b. Regulated Output Pressure ..... 5-37 1.5 psig ± 0.3 psig Same as initial c. Compressor Run Time ............. N/A Stop time to

Start time >3 minutes

Same As Standard

Same As Standard

3-32. Permanent Echoes. a. Search Permanent Echo (1) Probability of Detection (PD),

minute.......................................... 5-30 Commissioned


Same as Standard

(2) PD, hour................................ 5-30 Commissioned

Value, not less than 80%

Same as Standard

Same as Standard

(3) Range ................................... 5-30 Commissioned


Same as Standard

(4) dRange ................................. 5-30 0 ±0.13 nmi ±0.13 nmi (5) Azimuth ................................. 5-30 Commissioned


Same as Standard

(6) dAzimuth ............................... 5-30 0 ± 0.7 Degree ± 0.7 Degree

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Section 12. ASR-11 Common – Standards and Tolerances


3-120. Clock Synchronization. a. Primary Surveillance Radar

(PSR) – Site Control and Data Interface (SCDI) Computers

SCDI-A/B – Date and Time ......... 5-83 Greenwich

Mean Time (GMT) Date and Time

Same as standard

Same as standard

b. Monopulse Secondary

Surveillance Radar (MSSR)

(1) CMS – DOS Date and Time . 5-83 GMT ± 5 minutes Same as

initial (2) MSSR Interrogator Date

and Time ............................... 5-83 GMT ± 5 minutes Same as

initial c. Control and Monitoring

Console (CMC) - Computer

CMC – Windows Date and Time. 5-83 GMT ± 5 minutes Same as

initial d. Radar Data Recorder (RDR) –

Computer RDR – Date and Time

5-83

GMT

± 15 seconds

Same as initial

3-121. through 3-139. Reserved.

*

*

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Section 13. DMS MSSR Transmitter – Standards and Tolerances


→ 3-140. Frequency 5-90 1030.0 MHz ± 0.01 MHz Same as initial → 3-141. Interrogator Power Output. a. Σ Forward Power on OMT

screen ....................................... 5-91 Commissioned

Value ± 1.0 dB Same as initial

b. Ω Forward Power on OMT

screen ....................................... 5-91 Commissioned


c. Sum Port Forward Power ........ 5-92 Commissioned


d. Control Port Forward Power ... 5-92 Commissioned


→ 3-142. P1 and P3 Pulse

Characteristics.

a. Pulse Width .............................. 5-92 0.8 µs ± 0.10 µs Same as initial → 3-143. Mode Spacing. a. Mode 3/A ................................... 5-92 8.0 µs ± 0.10 µs Same as initial b. Mode C ...................................... 5-92 21.0 µs ± 0.10 µs Same as initial c. Mode 2 ...................................... 5-92 5.0 µs ± 0.10 µs Same as initial → 3-144. P2 Pulse Characteristics. a. Pulse Width .............................. 5-92 0.8 µs ± 0.10 µs Same as initial b. Pulse Position .......................... 5-92 2 µs after P1 ± 0.10 µs Same as initial → 3-145. Improved Interrogator Side

Lobe Suppression (IISLS).

a. P1to P2 Power Ratio ................ 5-92 -3.0 dB ± 1.0 dB Same as initial b. P1 Pulse Width ......................... 5-92 0.8 µs ± 0.10 µs Same as initial

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Section 2. PSR Other Maintenance Tasks (Continued)

Reference Paragraph Maintenance Tasks Standards &

Tolerances Maintenance Procedures

4-11. Antenna/Pedestal Assemblies. a. Annually. Perform the following tasks: Antenna/Pedestal Inspection ........................................... Antenna Tilt

PSR 3-30 LVA 3-70 and 3-170

5-36

4-12. PSR Microwave Assembly (Unit 6). a. Quarterly. Perform the following checks on Receiver

Protectors 6Z1, 6Z2.

(1) SP recovery margin ................................................... 3-35.a.(1) 5-32 (2) SP suppression value ................................................ 3-35.a.(2) 5-32 (3) LP recovery margin ................................................... 3-35.b.(1) 5-32 (4) LP suppression value ................................................ 3-35.b.(2) 5-32

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4-13. Pedestal (Unit 35). a. Quarterly. Perform the following checks using external

test equipment

(1) Pedestal Local Control Panel Power Supplies (a) Encoder X, PS-1 ..................................................... 3-33.a. 5-29 (b) Encoder Y, PS-2 ..................................................... 3-33.b. 5-29 (c) Polarizer, PS-3 ........................................................ 3-33.c. 5-29 (d) Weather Beam Switch, PS-4 .................................. 3-33.d. 5-29 (2) Withdrawn by Change 1

(3) Pedestal Main Gear Oil Level Inspection .................... N/A IAW TI 6310.59

Book 1 Para 3.6.2.1

b. Semiannually. Perform the following tasks: (1) Sample Pedestal Main Gear Oil Sump ....................... N/A IAW TI 6310.59

Book 1 Para 3.6.1.2

(2) Sample Drive Train Gearbox Oil ................................. N/A IAW TI 6310.59

Book 1 Para 3.6.1.1

c. Annually. Perform the following task: Test Master Safety Switch and Safety Interlock

Operations ...................................................................... N/A 5-35

d. Initial 5 Year. As Required: (1) Replace Pinion Lip Seals ........................................ N/A IAW TI 6310.59

Book 1 Para 3.8

(2) Replace Sump Outer Felt Seal................................ N/A IAW TI 6310.59

Book 1 Para 3.9.2

* *

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Section 2.PSR Other Maintenance Tasks (Continued)



e. As Required. Perform the following tasks: Replace Sump Inner Felt Seal (performed

concurrently with paragraph 4-14 b.) N/A IAW TI 6310.59

Book 1 Para 3.9.1

4-14. Rotary Joint. a. Annually. Perform the following tasks: Audible Check ................................................................ N/A IAW TI 6310.57

[TI 6310.63] Sect. 5

b. As Required. The following task is to be coordinated

with Engineering Services.

Complete Rotary Joint Change Out ............................... N/A IAW TI 6310.59

Book 2 Corrective

Maintenance

4-15. Compressor Dryer. a. Quarterly. Perform the following tasks: (1) Regulated Output Pressure Verification .................. 3-31.b 5-37 (2) Compressor Run Time ............................................ 3-31.c N/A b. Semiannually. Perform the following tasks: (1) Purge Verification .................................................... N/A IAW

Compressor Dehydrator

Manual Section 7.1

(2) Start Pressure Verification....................................... 3-31.a.(1) IAW


Manual Section 7.1.1

(3) Stop Pressure Verification ....................................... 3-31.a.(2) IAW


Manual Section 7.1.1

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4-16. MTI Reflectors. As Required. (1) Solar Panel Cleaning ................................................ N/A IAW

MTI Reflector Manual

Section 6.1 (2) Desiccator Plug ......................................................... N/A IAW


Section 6.2 (3) Visual Inspection ....................................................... N/A IAW


Section 6.3 4-17. Permanent Echoes (PE)

Annually. (For each applicable PE) verify the following:

(1) Probability of Detection (PD) Verification (a) PD, minute ......................................................... 3-32.a.(1) 5-30 (b) PD, hour............................................................. 3-32.a.(2) 5-30 (c) Range ................................................................ 3-32.a.(3) 5-30 (d) dRange .............................................................. 3-32.a.(4) 5-30 (e) Azimuth .............................................................. 3-32.a.(5) 5-30 (f) dAzimuth ............................................................ 3-32.a.(6) 5-30 4-18. PSR System Performance Analysis.

Monthly. Perform the following check. Performance Analysis (FAA Facilities Only) .................. N/A 5-34

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4-19. Variable Site Parameters (VSP) Verification. Annually. Verify compliance with commissioned

baseline ............................................................................... 3-28 5-27

4-20. Variable Site Parameters (VSP) Backup.

a. As Required. Before and after changing any VSP value(s)

(1) Ultra5 Workstation N/A 5-31 (2) T2000 Workstation N/A 5-38

(3) Z440 Workstation N/A 5-40 b. As Required. Transfer files to/from AJW-1471 N/A 5-39

4-21. Fiber Optics.

Annually. Perform the following check. (1) Single-Mode Fiber Configuration (a) Distance Path: >100 meters and < 1 kilometers 1 Transmission Path Losses .............................. 3-40.a.(1).(a) 5-80 2 Radar Site Transmission Level ....................... 3-40.a.(1).(b) 5-80 3 Indicator Site Transmission Level ................... 3-40.a.(1).(c) 5-80 (b) Distance Path: >1 kilometers 1 Transmission Path Losses .............................. 3-40.a.(2).(a) 5-80 2 Radar Site Transmission Level ....................... 3-40.a.(2).(b) 5-80 3 Indicator Site Transmission Level ................... 3-40.a.(2).(c) 5-80 4-22. Verify ASDP REX Weather Clutter Maps

As Required. Following any ASDP REX reset, verify Weather Clutter Maps. .......................................................

N/A 5-23

* *

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4-23. Lightning Protection System Components

a. Pedestal and Antenna Lightning Protection. (1) As Required. (a) Pedestal Local Control Panel (PLCP) Transient

Voltage Surge Suppressor (TVSS) #1 .......................... N/A IAW TI 6310.47

[TI 6310.64] Vol 1, WP 010 04,

Section 2-4 (b) PLCP TVSS #2 ...................................................... N/A IAW TI 6310.47

[TI 6310.64] Vol 1, WP 010 04,

Section 2-4 (c) DP2 TVSS ............................................................. N/A IAW TI 6310.47

[TI 6310.64] Vol 1, WP 010 04,

Section 2-4 (d) DP3 TVSS ............................................................. N/A IAW TI 6310.47

[TI 6310.64] Vol 1, WP 010 04,

Section 2-4 (e) Weather Beam Assy. TAZ Diodes ......................... N/A IAW TI 6310.47

[TI 6310.64] Vol 1, WP 010 04,

Section 2-5 (f) Citel Base Five (CB5) ............................................ N/A IAW TI 6310.47

[TI 6310.64] Vol 1, WP 010 04

(g) Pedestal Room, TVSS, U34A1 ............................. N/A IAW TI 6310.47

[TI 6310.64] Vol 1,, WP 010 04,

Section 2-2.1 (h) Pedestal Room, TVSS, U35A7 ............................. N/A IAW TI 6310.47

[TI 6310.64] Vol 1, WP 010 04,

Section 2-3

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Section 7. DMS MSSR Other Maintenance Tasks (Continued)

Reference Paragraph

Maintenance Tasks Standards & Tolerances

Maintenance Procedures

b. Annually. Perform the following tasks: (1) Check connector mating.............................................. N/A Visual Inspection (2) Inspection for dirt, dust, and debris ............................. N/A Visual Inspection c. 5 Years. Perform the following tasks: Plot Extractor Processor Battery Replacement .................. N/A IAW TI 6310.61

Section 7 Para. 2.1 and TI 6310.60

Section 7 para. 8.2.1 4-74. MSSR System Performance Analysis.

Monthly. Perform a System Performance Analysis (FAA Facilities Only).

N/A 5-34

4-75. Probability of Detection (PD)

Annually. Perform the Probability of Detection for SSR Parrot

(1) PD, minute ................................................................ 3-163.a. 5-98 (2) PD, hour .................................................................... 3-163.b. 5-98 (3) Range ....................................................................... 3-163.c. 5-98 (4) dRange ..................................................................... 3-163.d. 5-98 (5) Azimuth ..................................................................... 3-163.e. 5-98 (6) dAzimuth ................................................................... 3-163.f. 5-98 4-76. Variable Site Parameter (VSP) Verification

Annually. Perform the VSP verification................................ 3-180 5-99 4-77. Variable Site Parameter (VSP) Backup

As Required. Perform the Configuration Set Backup prior to changing any VSP value(s) ................................................

N/A 5-102

4-78. and 4-79. Reserved

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5-17. PSR Transmitter Power Supplies.

a. Objective. This procedure will be used to measure the Primary Surveillance Radar (PSR)’s transmitter power supplies’ dc voltages and check power supply fan operation. The power supplies are contained in unit 4 (U4) power supply cabinet.

b. Discussion. (1) There is no down time required for this procedure. (2) Failure of the power supply fans can cause subsequent power supply failures. This

procedure verifies power supply fan operation. (3) This test is performed on an operational PSR system and there is no down-time

required. All maintenance procedures should be coordinated with air traffic control.

c. Test Equipment Required. Digital Voltmeter.

d. Conditions. Ensure that the PSR System is operating fault free.

e. Detailed Procedure.

(1) Measure dc voltages.

(a) 4A4A1 to 4A4A3, 4A5A1, 4A6A1, 4A6A2, 4A7A1, 4A7A2, +36 volt dc, and 4A6A3 and 4A7A3 +42 volt dc Power Supplies. Using a digital voltmeter, measure the output (V+, RET) of each +36 and +42 V dc power supply and verify that the voltage is within the standards and tolerances listed in chapter 3 of this handbook.

(b) 4A3A1 and to 4A3A2 +5, +30, and -15 volt dc Power Supplies.

Note: If adjustment is required, the alternate power supply (4A3A1 or 4A3A2) must be turned off while making the adjustment.

1 Using a digital voltmeter, measure the output of the +5 V dc power supply at

the 5V test points (5V, 5V RET) located on the front panel of each power supply and verify that the voltage is within the standards and tolerances listed in chapter 3 of this handbook. If required, adjust front panel control “5V ADJ” for the correct voltage.

2 Using a digital voltmeter, measure the output of the +30 V dc power supply

at the 30V test points (30V, 30V RET) located on the front panel of each power supply and verify that the voltage is within the standards and tolerances listed in chapter 3 of this handbook. If required, adjust front panel control “30V ADJ” for the correct voltage.

3 Using a digital voltmeter, measure the output of the -15 V dc power supply at

the -15V test points (-15V, -15V RET) located on the front panel of each power supply and verify that the voltage is within the standards and tolerances listed in chapter 3 of this handbook. If required, adjust front panel control “-15V ADJ” for the correct voltage.

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(2) Check power supply fan operation.

(a) Verify the fan in each power supply unit is working by placing a piece of light tissue paper outside of the caged area of the fan and making sure the paper is drawn in and moves. If the fan is making noises, or there is little movement of the tissue paper, the power supply should be replaced. 5-18. PSR Transmitter Radio Frequency (RF) Drivers and Amplifiers.

a. Objective. This procedure will be used to measure RF output levels of the “Primary Surveillance Radar” (PSR)’s transmitter RF drivers and amplifiers contained in unit 3 (U3) transmitter cabinet.

b. Discussion.

(1) There is no down time required for this procedure.

(2) The output of the transmitter RF drivers and amplifiers contained in cabinet U3 are measured.

c. Test Equipment Required. RF Power Meter, (Gigatronics 8652A or equivalent) Peak Power Sensor Oscilloscope

d. Conditions. Ensure that the PSR System is operating fault free.


(1) Test Equipment Initial Settings

(a) Calibrate Power Sensor as follows: 1 Power on RF power meter. 2 Connect power sensor grey cable into Channel A of the power meter. 3 Select [Meter Setup] [Calibrator] on the power meter main menu. 4 Enter 0 dBm for level and set meter frequency to: 50 MHz for sensor 80350A 1.00 GHz for sensor 80701A

5 Press [OK] and plug the power sensor head into the CAL O/P port on the

power meter. 6 Push the CAL ZERO hard key to initiate the calibration procedure. When

calibration is complete, proceed to the power meter set up.

*

*

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5-21

(b) Set up RF Power Meter as follows:

1 Sensor Peak 2 Trigger Internal 3 Average 16 4 Trigger Level -20 dBm 5 Delay 155 µsec 6 Frequency 2.8 GHz

(c) Set up oscilloscope as follows:

1 Connect Peak Power Sensor Sample Delay to Oscilloscope Channel 1. 2 Connect Peak Power Sensor Detector Output to Oscilloscope Channel 2. 3 Trigger Oscilloscope on Channel 1. 4 Nominal settings: Main Timebase 50 µsec Channel 1 0.5 VDC Channel 2 2 VDC

(2) Measure RF Output of 3A5 and 3A10 Transmitter RF Drivers.

(a) At cabinet unit 3, remove termination from RF Driver Module A5 [A10]. Refer to

figure 5-4.

1 Connect the peak power sensor to the front panel output jack J1 of the RF Driver Module A5 [A10]. Measure the RF power levels. Refer to figure 5-5.

2 Viewing the oscilloscope, ensure trailing edge of Sample Delay

(Oscilloscope Channel 1) is aligned to middle of Detector Output long pulse (Oscilloscope Channel 2). Adjust Power Meter Delay and use oscilloscope Delayed Timebase function, if necessary. Refer to figure 5-6.

3 Calculate the difference between the Initial Reference Value, which is

contained in the site commissioning data, for power at the output jack and the measured value.

* *

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5-22

4 Verify that the power differences between the measured value and the initial reference value are within the established standard and tolerance contained in chapter 3 of this handbook.

5 Reinstall RF Driver Module termination. 6 Repeat steps 5-18e (2)(a) 1 through 5 for amplifier driver module A10.

(3) Measure RF Output of 3A1 – 3A4 and 3A6 – 3A9 Transmitter RF Amplifiers.

(a) At cabinet unit 3, remove termination from RF Amplifier Module A1 [A2, A3, A4,

A6, A7, A8, A9]

1 Connect the peak power sensor to the front panel output jack on RF Amplifier Module A1 [A2, A3, A4, A6, A7, A8, A9]. Measure the RF power level.

2 Calculate the difference between the “Initial Reference Value”, listed in the

site commissioning data, for power at J2 and the measured value. 3 Verify that the power differences between the measured value and the initial

reference value are within the established standard and tolerance contained in chapter 3 of this handbook.

4 Reinstall RF Amplifier Module termination. 5 Repeat steps 5-18e(3)(a) 1 through 4 for amplifier modules A2, A3, A4, A6,

A7, A8, and A9.

Figure 5-4 RF Amplifier and Driver Module J1 Locations

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5-41

(3) Target STC Map, Map 2 Verification.

(a) Repeat step (2), select Map 2, and verify its values.

(4) Target STC Map, Map 3 Verification. (a) Repeat step (2), select Map 3, and verify its values.

(5) Original Configuration. Restore the current, operating, STC Map and return control of

the radar to Air Traffic.

(6) Termination of Test. Perform procedure 5-11 Termination of Test to conclude this procedure 5-27. PSR Variable Site Parameters (VSP) Verification.

a. Objective. This procedure will be used to verify that no unauthorized changes have been made to the current PSR VSP values.

b. Discussion.

(1) There is no downtime required for this procedure.

(2) During the optimization and flight check process, various radar operational parameters were established in the VSPs. This procedure will allow the technician to extract the current operating VSP values and compare them with previous valid VSP data files. This process is used to ensure the integrity of the system and verify that no unauthorized changes have been made.

(3) This test will be used to compare the latest valid adaptation files with current

adaptations files (Raytheon and customer) that have been transferred from SCDI A and SCDI B to the weather laptop during performance of VSP Backup, paragraph 5-31.

c. Test Equipment Required. Weather Optimization Laptop Computer d. Conditions. This procedure can be performed off-line e. Detailed Procedure.

(1) Unzip and Rename Adaptation Files

(a) On the Wx laptop, delete all files residing in the C:\VSP Verification folder. If

the folder does not exist, create it.

(b) Locate the most recent adaptation data files on Wx laptop. The files should be located in the C:\Site_Adaptation\<site data> directory, with <site data> = (Site ID_Build_Month_Day_Year).

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(c) Copy the files <site data>_scdia.tar and <site data>_scdib.tar to the C:\VSP Verification directory.

(d) Double click on the file <site data>_scdia.tar to unzip the file.

1 In the PeaZip window, select the raytheon_adapt_data_file_site.c file. Click on “Extract” from the menu bar.

2 In the Extract window, the “Extract to:” field should display the C:\VSP

Verification folder. If not, navigate to it in the “Folders/Drives” field. The “Use Folder Name” box should not be checked. Click the “Extract” button.

3 In the Peazip window, select the

customer_online_adapt_data_file_ascii.c file. Click on “Extract” from the menu bar. 4 In the Extract window, the “Extract to:” field should display the C:\VSP

Verification directory. Click the “Extract” button. 5 The two extracted files should now reside in C:\VSP Verification. Rename

the two files with file names containing the channel and date the files were originally created:

Original File Name New File Name raytheon_adapt_data_file_site.c araymmddyy.txt

customer_online_adapt_data_file_ascii.c acustmmddyy.txt

Note: mm=month, dd=day, yy=year of date file was originally created.

(e) Repeat step 5-27e(1)(c) for the file <site data>_scdib.tar and rename the files:

Original File Name New File Name raytheon_adapt_data_file_site.c braymmddyy.txt

customer_online_adapt_data_file_ascii.c bcustmmddyy.txt

Note: mm=month, dd=day, yy=year of date file was originally created.

(f) Perform paragraph 5-31 Variable Site Parameter (VSP) Backup, if necessary, to

capture and transfer the current sets of adaptation data for SCDI A and SCDI B to the Wx Laptop. (g) Repeat step 5-27e(1)(c) to copy, unzip, and rename the current adaptation data

files.

(2) Compare Current Adaptation Files to Previous Adaptation Files.

(a) Computer Verification using ExamDiff Pro.

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(4) Copy Site Tailoring files to Weather Laptop

Caution: Although extremely remote, there is a possibility of taking the radar out of service when the weather laptop is connected into the Radar LAN. Coordination with Air Traffic Control is essential. Advise that the weather laptop is connected into the LAN and there is a remote possibility of service interruption caused by reconfiguring the LAN, which could lead to the SCDI terminals rebooting.

(a) Connect LAN cable from weather laptop:

1 Notify Air Traffic Control that maintenance activity could lead to a radar data

service disruption. Should the SCDIs reboot, there will be a 3 to 5 minute outage and the system will recover automatically.

2 Connect LAN cable from weather laptop to any free port on the RADAR LAN

A (138 LAN) ethernet switch located in cabinet 7. (b) Configure the weather laptop's IP address to communicate with the Radar LAN.

The IP address must be set to 138.1.1.10. 1 On the weather laptop, click on Start/Control Panel/Network Connections.

2 Change adapter Settings 3 Double click on "Local Area Connection".

4 Select General tab.

5 Click on "Properties".

6 In the "Local Area Connection Properties" menu scroll to select "Internet

Protocol (TCP/IP)". (IPv4)

7 Click on the "Properties" button.

8 Click on "Use the following address:" If there is an IP address already in the IP address box, write it down so that it can be restored later. ___.___.___.___ IP address found

9 In the IP address: box enter 138.1.1.10.

10 In the subnet mask: box enter 255.255.255.0.

11 Click OK and close all open windows.

(c) Using WS_FTP Pro, connect to SCDI-A

1 At the Weather Optimization laptop, click ICON on Wx laptop desktop for Ipswitch WS_FTP 12. See Figure 5-15 WS_FTP_Pro Main Screen for a screen shot of the main screen.

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Figure 5-15 WS_FTP_Pro Main Screen

2 Click on down arrow next to the Connect button in the upper left. If the

Disconnect button is active, click on disconnect and then click on connect. The disconnect button is shown when the program was shut down without disconnecting.

3 Use drop down menu to select "scdia". Once connected, the SCDI A file

directory will be displayed in the connection pane on the right.

(d) Transfer both site tailoring files located in the /usr/home/sband folder

/usr/home/sband/<site data>_scdia.tar /usr/home/sband/<site data>_omt.tar

from SCDI-A to Weather laptop C:\Site_Adaptation\<site data> directory. See Figure 5-16, Weather Laptop Directory Structure for site adaptation.

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5-33. Reserved 5-34. PSR / MSSR System Performance Analysis (FAA Sites Only).

a. Objective: This procedure requires the system specialists to analyze the processed radar beacon data sent from the ASR-11 to the applicable automation unit (ARTS/STARS). Radar data analysis is performed on this data. The results will be used for site trend analysis.

b. Discussion:

(1) This procedure does not require downtime and should be performed on the online selected channel. No configuration change is required. This statement assumes that the selected PSR/MSSR channels are changed periodically as part of normal operation.

(2) The procedure should be performed on a day with no severe weather within the

coverage area. (3) A data file is recorded with the DTE Monitor, and a program called “Radar Beacon

Analysis Tool” (RBAT) is used to analyze the file. This program generates output files containing many parameters such as PD (beacon & search), and ID/Altitude confidence. Values obtained through this procedure will be compared to previously recorded output files for trend analysis.

c. Test Equipment Required:

Weather optimization notebook computer DTE Monitor DTE Monitor software RBAT radar data analysis software (should be version 9.8) It can be obtained from the DTE Monitor install CD or from AJW-147).

Note: If necessary, refer to the ASR-11 Second Level Engineering Support website, http://www.faa.gov/aos/aos232. for the ASR-11 DTE Monitor and CD2 capture device’s connection and operation, and installation of required DTE Monitor software. The computer’s IP address should be 172.16.199.11.

d. Conditions: Ensure that the PSR System is operating normally.

e. Detailed Procedure:

(1) Record Data and Analyze System Performance.

(a) Record data for one hour as follows:

1 Start the DTE Monitor program. 2 After visually ensuring primary and secondary targets are being displayed,

click on the “Record” button. The “Open CD RECORD file for recording” dialog box appears on the screen.

Note: Look at the middle of the dialog box under the label “CD RECORD File Header” where the “Channels and Site Names” information is displayed. If the Site ID doesn’t match your site ID, please refer to the procedures on the ASR-11 Second Level Engineering Support website, and perform the necessary steps to set your site ID.

3 Enter the filename “Proc534” in the filename field (do not hit return!)

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http://www.faa.gov/aos/aos232

http://www.faa.gov/aos/aos232

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4 Select the radio button labeled “Minutes” located at the bottom of the dialog box. Over on the right side there is a field showing the default value of 90 minutes, change that to 60 (do not hit return!)

5 Click the “Date_Time Filenames” box to make sure it is checked. (This will add a unique date/timestamp to the filename. So, for example, the file created here will have a name that looks similar to “Proc534_May13_2006_131612.dat Proc534_May13_2006_131612_a.dat for channel A and Proc534_May13_2006_131612_b.dat for channel B””).

6 In the “Comments” enter: “PSR performance check, <today’s date>, SEL=

PSR-A (or PSR-B), MSSR-A (or MSSR-B), SCDI-A” and any other useful info (do not hit return!). 7 Click the “Save” button to start the recording, it will run for 60 minutes (the

“Recording Goal” display in the upper left corner of the monitor window will turn gray and show “Not Recording” when it halts).

8 After the recording completes, click the “Scr” (scroll) checkbox in the “DTE

Monitor – Message Display” window at the top of the screen. Click on the up arrow button to scroll backward through the message log from the “Stopped Recording” message to the “Starting record” message. Error messages (if any) are displayed in red type.

Note: There should be no errors during the recording. If errors are present, the recording should not be used. The recording should be re-run after the errors have been resolved.

9 The first file recorded with this procedure should be saved indefinitely on

the weather optimization computer and its location annotated as part of the site commissioning data. The subsequent files recorded should be saved as directed by the data retention policy for the site.

10 Exit from the DTE Monitor program by selecting “File, Exit” from the menu.

(b) Run the RBAT data analysis program on the recorded data file (the following steps apply to version 8.5 of that program).

1 First, verify the recorded file is good. Start the RBAT program. From the

RBAT menu select “Programs”, and then “Analyze Data.” 2 From the “Program Selection” list, select “Scan Summary” and click “OK”. 3 When the “Options Selection” window appears, click on “Plot” and this

should remove the check mark from the box. Click “OK”. 4 In the “Open (Input File) dialog box, locate and select the

“Proc534_date_timestamp.dat Proc534_date_timestamp_a.dat for channel A and Proc534_date_timestamp_b.dat for channel B” file recorded in step e. (1) (a). Click the “Open” button.

Note: If more than one timestamp is selected, an error message will appear.

5 In the “Save As (Output Text File) dialog, click the “Save” button. 6 Next the “Site Parameters: XXX” dialog box appears (XXX should be your 3

letter Site ID). In the “Radar type, beacon, search” field select the radar entry that corresponds to the maximum range settings of the DTE device (i.e., SDT, SIU, etc.) used to record the data. If a SDT was utilized as the DTE device, select the “ASR11, ASR11, ASR11” entry by clicking the black arrowhead at the right of the field and then selecting from the drop-down list. If a SIU device was used, the entry

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for this field is dependent on the “Maximum Range” settings of the SIU. Table 5-10 SIU Maximum Range Settings lists the proper radar entry for different SIU “maximum range” settings.

Table 5-10 SIU Maximum Range Settings

SIU Maximum Range setting (Nm) “Radar type, beacon, search” field entry 64 ASR11 FAA, ASR11, ASR11 128 ASR11 DOD, ASR11, ASR11 256 ASR11 1/16 NMI LSB, ASR11, ASR11

7 If the recording was from the output of the SDT, click “Beacon Sector

Mark”; if the recording was from the output of the SIU, click “Search Sector Mark.” Click “OK”.

8 Next the “Filters” dialog box appears. Click “OK”. This should result in the program running with your entries. You may briefly see a progress bar and then the main RBAT window is displayed when the run is complete.

9 To see the “Scan Summary” results, from the main RBAT menu select

“Programs, Display Results”. In the “Program Selection” list, select “View” and click “OK’. 10 In the “Open (Text File)” dialog, select the file just created

(PROC534_date_timestamp_dat_scansum.txt Proc534_date_timestamp_a_dat_scansum.txt for channel A and Proc534_date_timestamp_b_dat_scansum.txt for channel B) and click “Open”.

11 The “View Program” window will open with the results of the analysis

displayed. Page down twice to see the tabulated results summary. In the middle of the view there is a column titled “Srch ScMk”. There should be 32 sectors for each scan, although some instances may exist where sectors per scan may follow a 31, 33 pattern (Sector Mark Inconsistency or SMI event) in consecutive scans. If there are no errors elsewhere in the summary list and there are 32 sectors per scan or one SMI event, the recording is good. It is not a problem if the first and last scans do not contain 32 sector marks. If there are more than one instances of the 31/33 pattern found in the summary list, the automation system operation logs (e.g. ARTSIIE or STARS) should be inspected for any signs of missing or extra sector marks. If no SMI events exist in the automation system logs, proceed with the analysis. If an SMI event exists at the automation site, contact the AJW-1471 personnel for further assistance. When finished, the “View Program” window can be closed.

12 From the main RBAT menu select “Programs”, then “Analyze Data.” From

the “Program Selection” list, select “Surveillance Analysis” and click “OK”. 13 When the “Options Selection” window appears, click on “Plot” and this

should remove the check mark from the box. Click “OK”. 14 In the “Open (Input File) dialog box, locate and select the


15 In the “Save As (Output Text File) dialog, click the “Save” button. 16 Next the “Site Parameters: XXX” dialog box appears (XXX should be your 3

letter Site ID). In the “Radar type, beacon, search” field select the radar entry that corresponds to the maximum range settings of the DTE device (i.e., SDT, SIU, etc.) used to record the data. If a SDT was utilized as the DTE device, select the “ASR11 FAA, ASR11, ASR11” entry by clicking the black arrowhead at the right of the field and then selecting from the drop-down list. If a SIU device was used, the entry for this field is dependent on the “Maximum Range” settings of the SIU. The Table 5-10 SIU Maximum Range Settings lists the proper radar entry for different SIU “maximum range” settings.

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17 Set MagDec to 0 18 If the recording was from the output of the SDT, click “Beacon Sector

Mark”; if the recording was from the output of the SIU, click “Search Sector Mark.” 19 Enter the elevation of your antenna in the “Elevation of antenna above MSL

(FT). This may be found in the site commissioning data or INCO data for your site. 20 Set the “Maximum range (NMIs)” to 60. Click “OK”. 21 Enter the information for your site’s fixed transponders (MSRM, Parrot,

CPME) in the next dialog. Click “OK” when finished. 22 In the “User Parameters” dialog, click “OK”. 23 In the next User Parameters dialog box, enter “1” for “Range window

(NMIs), “5” for “Azimuth window (DEGs), “4” for “Number of consecutive coasts…), and “10” for “Minimum track life…). Click “OK” when finished.

24 Next the “Filters” dialog box appears. For:

“Range in nautical miles” enter “0.5, 60.0”; “Azimuth in degrees” enter “0.0, 360”; “Altitude in feet” enter “0, 24000”; and “Elevation angle in degrees” enter “0.5, 30.0”. Click “OK” when finished.

This should result in the program running with your entries. You may briefly see a progress bar and then the main RBAT window is displayed when the run is complete.

25 From the RBAT menu select “Programs, then Analyze Data.” 26 From the “Program Selection” list, select “Beacon False Target Summary”

and click “OK”. 27 When the “Options Selection” window appears, click “Plot” and this should

remove the check mark from the box. Click “OK”. 28 In the “Open (Input File) dialog box, select the


29 In the “Save As (Output Text File) dialog”, click the “Save” button. 30 At this point the “Site Parameters: XXX” dialog box appears (XXX should be

your 3 letter Site ID). In the “Radar type, beacon, search” field select the radar entry that corresponds to the maximum range settings of the DTE device (i.e., SDT, SIU, etc.) used to record the data. If a SDT was utilized as the DTE device, select the “ASR11 FAA, ASR11, ASR11” entry by clicking the black arrowhead at the right of the field and then selecting from the drop-down list. If a SIU device was used, the entry for this field is dependent on the “Maximum Range” settings of the SIU. The Table 5-10 SIU Maximum Range Settings lists the proper radar entry for different SIU “maximum range” settings.

31 If the recording was from the SDT, click “Beacon Sector Mark”; if the

recording was from the SIU, click “Search Sector Mark.” 32 Enter the elevation of your antenna in the “Elevation of antenna above MSL

(FT)” field. 33 Set the “Maximum range (NMIs)” to 60. Click “OK”.

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34 Set MagDec to 0 35 In the “User Parameters” dialog box, click “OK” 36 In the next User Parameters dialog box, enter “4” for “Number of

consecutive coasts…”, “0.2” for “Delta range limit for false target categories (NMIs)”, “4.0” for “Delta azimuth limit for false target categories (DEGs)”, and “200” for “Delta altitude limit for false targets (FT)”. Click “OK”.

37 In the “Filters” dialog, enter “0, 7777” for “ATCRBS id in octal”. Click “OK”. This should result in the program running with your entries. You may briefly see a progress bar and then the main RBAT window is displayed when the run is complete.

38 To see the “Surveillance Analysis” results, select “Programs, Display

Results”. In the “Program Selection” list, select “View” and click “OK’. 39 In the “Open (Text File)” dialog, select the file just created

(PROC534_date_timestamp_dat_sa.txt Proc534_date_timestamp_a_dat_sa.txt for channel A and Proc534_date_timestamp_b_dat_sa.txt for channel B) and click “Open”.


displayed. Page down twice to see the tabulated results summary. From the “Total” row, note the values. When finished, the “View Program” window can be closed.

41 To see the “Beacon False Target Summary” results, select “Programs,

Display Results”. In the “Program Selection” list, select “View” and click “OK’. 42 In the “Open (Text File)” dialog, select the file just created

(Proc534_date_timestamp_dat_bfts.txt Proc534_date_timestamp_a_dat_bfts.txt for channel A and Proc534_date_timestamp_b_dat_bfts.txt for channel B) and click “Open”.


displayed. Page down twice to see the results summary column. Note the numbers in the “Percent” columns. When finished, the “View Program” window can be closed.

(c) Compare results with your initial system performance analysis. If a degrading trend is noticed for those numbers, follow local escalation protocol to obtain assistance.

(d) Exit the RBAT program and shut down the laptop computer. 5-35. Master Safety Switch and Safety Interlock Test and Inspection.

a. Objective. This procedure will test and inspect the antenna and pedestal safety interlocks. It will require approximately 3 hours of system downtime. The Technical Operations system specialist must coordinate the downtime with Air Traffic Control.

b. Discussion.

(1) In this procedure, all safety interlocks and switches associated with the antenna and antenna pedestal are activated and verified to be operational. The system specialist will also verify that the appropriate alarms occur at the SCDI.

(2) This test event assumes that Air Traffic Control’s Radar Control Panel (RCP) has system control (normal configuration) and that coordination with Air Traffic is required for system downtime and for them to release control of the ASR-11 system to Technical Operations technicians to perform this procedure.

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Note: This procedure requires the antenna motors be operational. Do not isolate the Antenna Motor Controller circuit breakers. The required Lockout/Tagout will be initiated at Safety Switch 35S1. c. Test Equipment Required.

Rust Inhibitor P/N 78360X or equivalent. Appropriate Lockout/Tagout devices. Refer to Local Lockout/Tagout Procedures as required. Cloth TI 6310.47 [TI 6310.64] WP005 01

d. Conditions. The PSR System will be taken out of service to perform this procedure. This procedure must be coordinated with Air Traffic Control.


(1) Point of Control.

Perform the required actions detailed in procedure 5-10 Point of Control Configuration.

(2) System Shutdown at the Radar Shelter

(a) Disable MSSR and PSR RF transmission.

1 At the on-line selected SCDI-A, click on selected MSSR box. Select Equipment Control. Set Interrogator RF Enable to OFF. Confirm when prompted and close to return to Main Status Screen.

2 At SCDI Main Status Screen, click on PSR Tx box. At Transmitter Pop-up Menu, select Equipment Control. Set each amplifier and driver to OFF.

Note: This procedure does not require shutdown of the Transmitter Power Supplies.

3 Confirm when prompted. Select CLOSE to return to Main Status Screen.

(b) Transition MSSR and PSR standby and selected channels to Maintenance.

1 At selected SCDI Main Status Screen, click on standby MSSR box. Select

Change Equipment Role. Change to Maintenance. Verify MSSR box color changes to orange.

2 At selected SCDI Main Status Screen, click on selected MSSR box. Select Change Equipment Role. Change to Maintenance. At confirmation screen, press OK to confirm. Verify MSSR box color changes to orange.

3 At selected SCDI Main Status Screen, click on standby REX/SDP box. Select Change Equipment Role. Change to Maintenance. Verify REX/SDP box color changes to orange.

4 At selected SCDI Main Status Screen, click on selected REX/SDP box. Select Change Equipment Role. Change to Maintenance. At confirmation screen, press OK to confirm. Verify REX/SDP box color changes to orange.

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(c) Change the selected user to “root” (password should change to root) then

connect to SCDI A using the connect button in WS_FTP_Pro. (d) On the SCDI A side of the WS_FTP window, navigate to the /usr/home/sband

directory. Transfer the SCDI A “.tar” to the /usr/home/sband directory on the SCDI A (e.g. “smx_011_05_17_2013_scdia.tar”) from the Weather laptop.

(e) Click the disconnect button in WS_FTP_Pro to close the connection to SCDI A. (f) Connect to SCDI B using the connect button in WS_FTP_Pro. (g) On the SCDI B side of the WS_FTP window, navigate to the /usr/home/sband

directory. Transfer the SCDI B “.tar” to the /usr/home/sband directory on the SCDI B (e.g. “smx_011_05_17_2013_scdia.tar”) from the Weather laptop.

(h) Click the disconnect button in WS_FTP to close the connection to SCDI B.

(4) Install updated site tailoring. (a) On SCDI A [B], open a UNIX window, if one is not already open.

1 Click on the grey background and select "Local Workstation Actions" then click the “UNIX Admin” button.

2 Log on as user ray . Password ray . 3 Type autosu to become super-user. 4 Type cd /usr/home/sband to navigate to the proper directory.

(b) In the UNIX window on SCDI A[B] Type rm -rf site_tailoring to

remove the backup site tailoring folder. (c) Type tar xvf xxxx.tar where xxxx is the file name. (d) Type update_site_tailoring.sh to copy the new adaptation files to

their operational locations. Messages should scroll by. (On Build 11, Ignore the missing file messages, they are normal.)

(e) Close the UNIX window. (f) Repeat steps 5-39 e. (4) (a) through (e) on SCDI B

(5) Finalize Update

Note: A full primary and secondary RADAR outage is required to complete the process. The SCDIs and REXs need to be soft rebooted and time should be reserved to re-certify the PSR and verify that the primary RADAR presentation is correct prior to returning the RADAR to service. Time should also be reserved to fall back in case the changes prove unacceptable. At a minimum, 1 hour should be reserved.

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Note: The following steps will reset the SCDIs to load the Raytheon adaptation update into the SCDIs and REXs. This can be done by performing the time synchronization or by resetting each SCDI individually. The method described here uses the time synchronization procedure. As an alternative to time sync, both SCDIs can be brought to the OK prompt using local workstation actions SCDI shutdown and then rebooted with the boot command.

(a) Perform the time synchronization procedure in paragraph 5-83 Clock

Synchronization to reboot both SCDIs and any Operator Maintenance Terminal (OMTs) attached to the system.

(b) When the system boots back up, perform the following steps.

1 Take control on SCDIA and select the Equipment control screen to “soft” re-boot REX A using the reset button. Perform the same procedure to re-boot REX B.

Caution: A full PSR outage for an extended period of time (weeks) is possible if the REX Power on/Off switch is touched. DO NOT reboot the REX using the power on/off switch for the VME chassis or the REX Power supply.

2 Evaluate PSR performance using the Radar Data Display, (RDD), RADAR certification parameters, and performance parameters to be sure the display and values are reasonable.

3 Perform any certification checks required to return the system to service. 4 If system performance is abnormal or unacceptable, restore the original site

tailoring.

(6) Termination of Procedure. Perform procedure 5-11, Termination of Test to conclude this procedure.

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5-40. Variable Site Parameters (VSP) Backup – Z440 Workstations

a. Objective. This procedure backs up the variable site parameters (VSP) on Z440 Workstations. Only those parameters that are site specific can be changed by the Technical Operations system specialist, all other VSP values must be as specified in the site commissioning data. Any other changes must be authorized by AJW-147, Terminal Radar Systems Engineering.

b. Discussion.

(1) There is no downtime required for this procedure. (2) This procedure will:

(a) Backup SCDI-A site tailoring to a tar file. (b) Backup SCDI-B site tailoring to a tar file. (c) Copy the SCDI-A backup tar files to SCDI-B. (d) Copy the SCDI-B backup tar files to SCDI-A. (e) Burn a backup CD on the Standby SCDI. (f) Verify the Selected SCDI can read the CD. (g) Copy the backup tar files from the CD to the weather laptop. (h) Upload the backup tar files from the CD to the ASR-11 Support Website.

(3) Maintainers are not required to save OMT VSPs. The restore script used

during an R&R procedure can restore VSPs to any workstation (SCDI or OMT) from any SCDI workstation VSP backup.

(4) ASR-11 sites need backups of their VSPs to restore site-specific values for the

event of Removal and Replacement (R&R) of any of their Z440 workstations. c. Test Equipment Required.

Weather Optimization Laptop Computer Blank CD-R

d. Conditions. Ensure that the PSR system is operating fault free. e. Detailed Procedure: Note: This procedure is for Z440 Workstations.

(1) On SCDI A, Backup SCDI-A Site Tailoring

(a) On SCDI-A, open a UNIX ADMIN window by performing these actions.

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1 Click on the UNIX ADMIN login button. This button is located on the bottom right corner of the SCDI-A main screen, on the far right side of the task bar.

2 Login as user ray

(b) Type the following commands to delete any old data and to prepare the current data to be transferred.

1 scdiaray: autosu 2 root # cd /usr/home/sband 3 root # rm –rf site_tailoring 4 root # backup.sh

(c) Execute the next command to generate a backup site tailoring tar file:

1 root # tar cvf <site_data>_scdia.tar site_tailoring see below for description of <site_data>

EXAMPLE COMMAND: tar cvf pbi_013_2017_09_26_scdia.tar site_tailoring where <site_data> is one string that has the format xxx_bbb_yyyy_mm_dd The fields are defined as follows: xxx is a three-character site identifier (lower case) bbb is a three-digit number identifying the software build. yyyy is a four-digit number specifying the year in which the data is being saved mm is a two-digit number specifying the month in which the data is being saved dd is a two-digit number specifying the day in which the data is being saved For example, a set of site tailoring data used with Build 13 of the West Palm Beach, FL (PBI) ASR application software is to be saved on Sept 26, 2017. Replace the string <site_data> with the string: pbi_013_2017_09_26 If you are unsure of the current build, type show_build in the command line window. Build number is the three-digit number just before the word "release" in the text on the screen. It will be helpful to write down the string <site_data> since it is used many times throughout this procedure. The resulting tar file will be saved as /usr/home/sband/<site_data>_scdia.tar

2 On SCDI-A, do not close the UNIX ADMIN window yet.

(2) On SCDI-B, Backup SCDI-B Site Tailoring

(a) On SCDI-B, open a UNIX ADMIN window by performing these actions. *

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1 Click on the UNIX ADMIN login button. This button is located on the

bottom right corner of the SCDI-B main screen, on the far right side of the task bar. 2 Login in as user ray

(b) Type the following commands to delete any old data and to prepare the current data to be transferred.

1 scdibray: autosu 2 root # cd /usr/home/sband 3 root # rm –rf site_tailoring 4 root # backup.sh

(c) Execute the next command to generate a backup site tailoring tar file: 1 root # tar cvf <site data>_scdib.tar site_tailoring

EXAMPLE COMMAND: tar cvf pbi_013_2017_09_26_scdib.tar site_tailoring where <site_data> is one string that has the format xxx_bbb_yyyy_mm_dd The fields are defined as follows: xxx is a three-character site identifier (lower case) bbb is a three-digit number identifying the software build. yyyy is a four-digit number specifying the year in which the data is being saved mm is a two-digit number specifying the month in which the data is being saved dd is a two-digit number specifying the day in which the data is being saved For example, a set of site tailoring data used with Build 13 of the West Palm Beach, FL (PBI) ASR application software is to be saved on Sept 26, 2017. Replace the string <site_data> with the string pbi_013_2017_09_26 The resulting tar file will be saved as /usr/home/sband/<site_data>_scdib.tar

(3) On SCDI-B, Copy the SCDI-A backup site tailoring tar file to SCDI-B

Note: The command line in the next step ends with a space character followed by a period character.

(a) root # rcp scdia:/usr/home/sband/<site_data>_scdia.tar .

The term <site_data> is described in paragraph 5-40e(1)(c) and includes the site ID, current build, and date as follows: xxx_bbb_yyyy_mm_dd

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(b) On SCDI-B, do not close the UNIX ADMIN window yet.

(4) On SCDI-A, Copy the SCDI-B backup site tailoring tar file to SCDI-A

Note: The command line in the next step ends with a space character followed by a period character.

(a) root # rcp scdib:/usr/home/sband/<site_data>_scdib.tar .


(b) On SCDI-A, do not close the UNIX ADMIN window yet.

(5) On the Standby SCDI, Burn Site Tailoring Files to a CD

(a) root # ls –l *tar

(b) Verify today’s backup tar files for SCDI-A and SCDI-B are listed.

(c) root # mkisofs –o st.iso –J -R –v <site data>_*.tar


(d) Insert a blank CD-R into the Standby SCDI’s DVD drive. (e) root # cdrecord –v dev=4,0,0 st.iso (f) Wait for the root # prompt. (g) root # ls –l /misc/cd (h) Verify that the names of both the SCDI-A and SCDI-B backup tar files

display on the screen to indicate they exist on the CD. (i) root # rm st.iso (j) root # eject (k) Remove CD from the Standby SCDI’s DVD drive. (l) root # exit (m) scdiray: exit (n) Label the CD with the following information:

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UNCLASSIFIED <site data>_scdia.tar <site data>_scdib.tar


(6) On the Selected SCDI, verify SCDI can read the CD (a) On the Selected SCDI, load the backup CD into the DVD drive.

(b) root # ls -l /misc/cd (c) Verify that the names of both the SCDI-A and SCDI-B backup site

tailoring files display on the screen. (d) root # eject (e) Remove CD from the Selected SCDI’s DVD drive. (f) root # exit (g) scdiray: exit

(7) Copy Backup Site Tailoring tar files from CD to the Weather Laptop

(a) On the Weather Optimization Laptop, open Windows Explorer. Note: See Figure 1, Weather Laptop Directory Structure for site adaptation.

(b) Use Windows Explorer and the following steps to create the weather

laptop folder: C:\Site_Adaptation\<site_data>

1 In Windows Explorer, verify the folder C:\Site_Adaptation exists. If it does not already exist, create it using the New Folder button in the Windows Explorer toolbar.

2 Open the C:\Site_Adaptation folder (if not already open) by

double clicking on it. 3 With the C:\Site_Adaptation folder highlighted, click on the

New folder button on the Windows Explorer toolbar. A New folder is created. 4 Rename the New folder as <site_data>


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5 Verify the following new folder exists: C:\Site_Adaptation\<site_data>

(c) Use Windows Explorer and the following steps to copy the SCDI-A and SCDI-B backup site tailoring tar files from the CD to the weather laptop folder: C:\Site_Adaptation\<site_data>

1 Load the newly written CD into the weather laptop’s DVD drive. 2 Using Windows Explorer, navigate to the folder for the weather

laptop’s DVD drive. The folder should contain both the SCDI-A and SCDI-B backup site tailoring tar files. To see the DVD drive folder in Windows Explorer (which might be called something like DVD RW Drive (D:)), you might need to double click on the entry labeled Computer.

3 Copy both SCDI-A and SCDI-B backup site tailoring tar files by:

a Click on one of the backup site tailoring tar files to highlight it. b Press and hold down the <Ctrl> key on the laptop keyboard. c While holding down the <Ctrl> key on the laptop keyboard,

click on the other tar file. c Release the <Ctrl> key. Both files should be highlighted now. d Right click on one of the files. e Select the Copy menu option.

4 Navigate back to the folder: C:\Site_Adaptation\<site_data> 5 Right click on the folder: C:\Site_Adaptation\<site_data> 6 Select the Paste menu option. 7 Wait until the copy operation is complete. 8 Verify both SCDI-A and SCDI-B site tailoring files appear in the folder:

C:\Site_Adaptation\<site_data> 9 Remove the CD from the weather laptop’s DVD drive.

(8) Upload Backup Site Tailoring tar files from CD to the ASR-11 Support Website

(a) Using the newly written CD and an administrative computer connected to the internet, upload the SCDI-A and SCDI-B backup site tailoring tar files to the ASR-11 Support Website according to the procedure in paragraph 5-39 titled “File Transfer to upload the Site Tailoring files to AJW-1471.”

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Weather Optimization Laptop ComputerC:\

Site_Adaptation

<site_data>Directory for LastAdaptation data

<site_data>_scdia.tarSCDI-A Adaptation Data

<site_data>_scdib.tarSCDI-B Adaptation Data

<site_data>Directory for Current

Adaptation data



<site_data>Directory for NextAdaptation data



Figure 5-36C Weather Laptop Directory Structure

5-41. through 5-49. Reserved

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5-70. Edit MSSR Transparent Mode Command (TMC) File.

a. Objective. This procedure uses a DOS text editor to make changes to a Transparent Mode Command (TMC) file. Anytime a Dynamic Parameter, or other VSP, is changed in the system, a corresponding change should be made to the TMC file.

b. Discussion. The TMC files contain a sequence of Transparent Mode commands that are

used to restore the Interrogator’s Plot Extractor Processor flash memory in the event of failure or replacement. The TMC files are stored on the Local CMS Computer hard drive. The files reside in the C:\CMS\TMC directory. There are channel specific files for channels A and B and common files with commands common to both channels. Anytime a Dynamic Parameter, or other VSP, is changed in the system, a corresponding change should be made to the TMC file. System control or communication with the MSSR is not required to edit TMC files.

c. Test Equipment Required:

3 ½” Floppy Disk.

d. Conditions. Operational CMS Terminal.

e. Detailed Procedures.

(1) Point of Control.

(a) System control or communication with the MSSR is not required to edit TMC files.

(b) The procedure is done using the local CMS terminal.

(2) Edit the MSSR Channel’s TMC file.

(a) After changing a VSP, perform the following steps to update the Transparent

Mode Commands (*.TMC) file for the MSSR channel.

(b) At the Local CMS Bar Menu Line, click on “Exit” to exit the CMS program and go to DOS.

(c) At the Local CMS Keyboard, type cd c:\CMS\TMC to change to the TMC

directory. (d) Type DIR *.TMC to list files and locate the TMC file for the appropriate MSSR

channel. Naming convention is the site identifier followed by CHA or CHB and the .TMC file extension (i.e., “PSFCHA.TMC”).

(e) Type EDIT siteCHa.TMC (i.e., “EDIT PSFCHA.TMC”) to edit the TMC text file.

(f) Navigate to the line that requires updating (i.e., “DP16 11 = n”).

(g) Enter the new value.

(h) Click on “File” at the menu bar, then click on “Save” from the pull-down menu.

(i) Click on “File” at the menu bar, then click on “Exit” from the pull-down menu.

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(j) Repeat procedure, paragraph 5-70 step e (2), as required for appropriate TMC

files

(k) From the DOS prompt type CD.. to return to the C:\CMS directory. Type CMS to restart the CMS application program.

(3) Copy TMC file to floppy disk.

(a) Insert 3 1/2 “ floppy” in CMS disk drive. From the CMS Bar Menu, select FILE,

then COPY.

(b) Select MSSR Transparent Commands

(c) From the popup window, select the TMC file by name.

(d) Click OK to copy and OK to use the current file name.

(e) Refer to paragraph 5-31 e.(6) for instructions on transferring a copy of the files to ASR-11 Second Level Engineering Group (AJW-1471).

(4) Termination of Test. Perform procedure 5-11 Termination of Test to conclude this procedure.

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5-83. Clock Synchronization – Configuration and Verification of Date and Time.

a. Objective. The ASR-11 radar system has several computers that have been deemed necessary to have close time synchronization. These computers are the Site Control and Data Interface (SCDI) A and B that are associated with the Primary Surveillance Radar; the Control and Monitoring System (CMS) computer affiliated with the Monopulse Secondary Surveillance Radar (MSSR); and finally, the Control and Monitoring Console (CMC) that is connected to the Surveillance Data Translator (SDT). There is also the Radar Data Recorder (RDR) system attached to the Off-site LAN A network that requires time adjustment.

Note: Those sites feeding the Standard Terminal Automation Replacement System (STARS) do not have a SDT.

b. Discussion.

(1) The time synchronization of the SCDI computers require both computers to be placed

into “Maintenance” and then restarted causing a loss of live target data to Air Traffic Services (ATS). Before performing this procedure total down-time will be required and coordination must be performed with ATS. Up to twenty minutes may be required to perform the SCDI time synchronization.

(2) The CMS computer does not require any down-time from ATS. This computer time is set via the Disk Operating System (DOS) commands, then the CMS main program is restarted and the time is synchronized for the MSSR Interrogator system.

(3) The MSSR Interrogator time synchronization requires both interrogators to be placed in maintenance, causing a loss of beacon targets. Before performing this procedure, down-time will be required and coordinated with ATS. The time is synchronized via the windows operating system (OS) pop-up menu. Up to five minutes may be required to perform the MSSR time synchronization.

(4) The Radar Data Recorder time adjustment requires the device to be disconnected from and re-connected to the offsite LAN A and therefore total down-time will be required and coordination must be performed with ATS. Up to twenty minutes may be required to perform the RDR time adjustment.

c. Material Required. 1) Digital Watch synchronized to Greenwich Mean Time (GMT) 2) PSR Equipment Manual TI 6310.57 [TI 6310.63] 3) Radar Data Recorder user manual and installation.pdf 4) A personal computer equipped with Win-XP or Win-7 Operating System

d. Conditions. Normal operation of the ASR-11 system. e. Detailed Procedure:

(1) GMT Synchronization.

(a) Synchronize the digital watch with GMT by using the following method:

1 Access GMT (also known as: Universal Coordinated Time) via telephone at

(303) 499-7111 and set the watch to the time value. This may take a few minutes before you can sync your digital watch with the voice prompt that occurs 10-seconds prior to the start of each minute.

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(2) Verification of Date/Time on SCDI-A/B.

(a) On SCDI-A and SCDI-B, observe that the date and time, as indicated in the top left-hand corner of the system status display, is within the tolerances listed in chapter 3 of this handbook. If the date and time are not within the tolerances listed, then perform steps (b) and (c) of this procedure.

(b) Point of Control. Perform the required actions detailed in procedure 5-10, of this handbook.

(c) SCDI-A/B Time Synchronization.

1 Coordinate with Air Traffic Services (ATS) for total system down-time of 10-minutes.

2 With SCDI-A having “Monitor and Control” place SCDI-B into the maintenance mode of operation by moving the mouse pointer to the SCDI-B box and click on the gray box that says: “SCDI-B” to open a sub-menu. In the sub-menu click on “Change Equipment Role” to open another menu, and then click on “Change to Maintenance”. Observe that the “SCDI-B” box changes color from green to orange (maintenance).

3 With SCDI-A having “Monitor and Control” place SCDI-A into the maintenance mode of operation by moving the mouse pointer to the SCDI-A box and click on the gray box that says: “SCDI-A” to open a sub-menu. In the sub-menu click on “Change Equipment Role” to open another menu, and then click on “Change to Maintenance”. A pop-up menu will appear and you will be advised that “This action will affect radar data! Action must be confirmed” (this action will terminate all radar and beacon data to air traffic control), click on the “CONFIRM” button. Observe that the “SCDI-A” box changes color from green to orange (maintenance).

4 Perform procedure 4.2.1.7 in the PSR Equipment Manual TI 6310.57 [TI 6310.63] to set the date and time of the SCDI computers. As mentioned in this procedure that when the time is set on the SCDI that is in control all other system-wide SCDI computers are synchronized to this time.

5 After the SCDI have restarted and the ASR-11 system status is displayed on the monitor, verify that the time displayed is within the tolerance specified in chapter 3 of this handbook.

(3) Verification of Date/Time on CMS.

(a) At the CMS, observe that the date and time, as indicated in the top right-hand corner of the system status display, is within the tolerances listed in chapter 3 of this handbook. If the date or time is not within the tolerances listed, then continue with steps (b) and/or (c).

(b) Point of Control. This procedure does not require system control or down-time.

(c) CMS Time Synchronization – CMS DOS Date and Time.

1 At the CMS computer, move the mouse pointer to the top of the display screen and click on “Exit”.

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2 A pop-up “QUERY” will appear asking you if you wish to Exit the CMS System, click on “Yes”.

3 At the DOS prompt, if the date needs to be set, type “date” then depress the enter key.

4 Enter the correct date as per the format “mm-dd-yyyy” then press “Enter”.

5 Verify the date by typing “date”, at the DOS prompt then observe that the

correct date is displayed, then press the “Enter” key to return to the DOS prompt.

6 At the DOS prompt, if the time needs to be set, type “time” and enter the correct GMT time in the following format “hh:mm:ss” then press “Enter”.

7 Verify the time by typing “time”, at the DOS prompt, verify that the time displayed is within the tolerance specified in chapter 3 of this handbook. Press the “Enter” key to return to the DOS prompt.

8 At the DOS prompt type “CMS” to restart the MSSR monitoring menu. If the CMS computer locks up, use the CTRL/ALT/DELETE keys to reboot it.

(4) Verification of MSSR Interrogator Date and Time.

(a) Position one of the MSSR’s A/B switches to the B position (communication with CMS) and verify that the CMS computer display “CHANNEL A” and “CHANNEL B” change color from gray to green for both interrogators.

Note: The DMS MSSR does not utilize an A/B switch. The interrogators will be in communication with the CMS.

(b) Verify that the time displayed for both Interrogators on the mimic display is

within the tolerance specified in chapter 3 of this handbook. If the date or time is not within tolerance proceed to the next step. If the time is within tolerance, return the MSSR’s A/B switch to the A position and skip to step 5-83 e(5).

Note: This procedure is not applicable to the DMS MSSR. The interrogator date/time on the DMS MSSR is automatically synchronized to a GPS Time Stamp Unit. If the interrogator time is out of tolerance, refer to TI 6310.60 Digital Airport Surveillance Radar ASR-11, System Manual For Mode S MSSR System, or OEM 80828/090 Ancillary Manual for RSL Radar Systems GPS Time Source. Caution: Placing both MSSR channels in maintenance results in a loss of live beacon targets and must be coordinated with air traffic control.

1 At the SCDI in control, transition both MSSR channels to maintenance

mode.

2 At the CMS: logon as maintainer.

3 At the CMS: click on either the time or date window on either interrogator, then click on “Set Time and Date”. As necessary, enter the correct GMT time (HH:MM:SS) and/or correct date (DD/MM/YY), then click on “Ok”. The message line should display a message stating that the time and date have been accepted. Both interrogators will update to the new time and date.

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4 On the CMS computer, logoff as maintainer.

5 Return the MSSR’s A/B switch to the A position (control to SCDI) and verify

that on the CMS computer mimic display both interrogators change color to gray. (c) At the SCDI in control, configure both MSSR channels to online.

(5) Return Control to Air Traffic Services (ATS). Perform procedure 5-11 to return control to ATS.

(6) CMC Time Synchronization.

(a) At the CMC computer that connects to the SDT (TRACON):

1 Close the windows program: “DASR SDT Control and Maintenance Console” window by clicking on the “X” box located at the top right-hand corner on this program’s menu.

2 A pop-up box will appear asking if you want to end your CMC session.

Click on the “Yes” button.

3 The CMC computer is now operating under the direction on the windows operating system. Click on the “Start” button located at the bottom left-hand corner of the display, click on “Control Panel”, then “Settings”, and finally click on the “Date/Time” icon.

4 Set the Date and Time to correspond with the exact GMT date and time as

indicated on the wrist watch that was synchronized with GMT, and then click on the “OK” button to set this date and time.

5 Close the control panel window.

6 Restart the CMC program by double-clicking on the “Sensis CMC” icon.

(7) Verification of Radar Data Recorder Date and Time Caution: Plugging/unplugging the network cable from RDR to and from offsite LAN A may

result in unexpected behaviors and loss of targets and must be coordinated with air traffic control.

(a) Coordinate with Air Traffic Services (ATS) for total system down-time of 20 minutes.

Note: Refer to the Radar Data Recorder documentation for information on this product.

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Figure 5-62A Radar Data Recorder

(b) Shut down the Radar Data Recorder (figure 5-62A). Push and hold the “EJECT” button (found on the front panel) for upwards of six seconds or until the center LED goes from red to green and back to red (if no external storage device is connected to the RDR, the LED goes from green to red). At this point release the button and wait till the red LED goes off.

(c) Unplug the dc connector from the back of the RDR.

(d) Unplug the CAT-5 cable connecting RDR to the Radar offsite LAN A (disconnect

from the Radar end, figure 5-62B). If your computer is running Windows 7, skip to step (d2) below.

Figure 5-62B Radar Data Recorder connection to the Radar Offsite LAN A (an example)

Note: Internet browser software (a.k.a, Internet Explorer) running on a laptop is used to set up the

RDR parameters and time. The procedure below sets up the PC to communicate with the RDR. Set the laptop (with WIN_SP OS) IP network address by the following procedures:

1 Power up the laptop and wait for system to come ready. The system may take

several seconds to come ready.

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2 On the PC, use the “Start” button to navigate to the “Control Panel” (Start-

>Settings->Control Panel)

3 Find and click on “Network and Sharing Center”. 4 Find and click on “Change Adapter Settings”. 5 Find and right-click on “Local Area Connection” and select “properties”. 6 Locate the entry “Internet Protocol Version 4 (TCP/IPV4)” and highlight it.

Click on the “Properties”. 7 In the “Internet Protocol (TCP/IP) Properties” dialog window, select the “Use

the following IP address” radio button and enter the following numbers: IP address 10.1.1.199

Subnet mask 255.255.255.0

8 Click the “OK” buttons to close the Internet Protocol Properties window, & click the “Close” button to close the Local Area Connection Properties window and apply your changes.

(e) Use the CAT-5 cable to connect the laptop network port straight to the RDR

LAN A Port 9, figure 5-62C. Apply power to the RDR.

Figure 5-62C Laptop direct network connection to the Radar Data Recorder

(f) Wait for the RDR to come ready. The device is ready when the “RECORDING”

LED is solid blue, and the “USB” LED is solid red (or green if no external storage memory is attached). (g) With laptop network cable connected to the RDR LAN A port, launch the

Internet explorer (IE) software on the laptop (Start -> All Programs -> Internet Explorer).

(h) Type http://10.1.1.191 in the address bar section of the Internet Explorer (figure 5-62D). With the web page shown on the screen, press the Status button and wait to get the RDR current time (figure 5-62E)

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Figure 5-62D Radar Data Recorder Home Page

Figure 5-62E System status returned in yellow box (on Status button pressed)

(i) Type in the current date & time in the edit boxes located inside the “Set

Time/Date GMT” section of the web page (figure 5-62F). Place the laptop mouse on the Set button next to the edit boxes. Watch the time on the clock until it reaches the programmed time less one second, and press the Set button on the web page. Press the Status button and wait to get the RDR updated time (figure 5-62E).

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Figure 5-62F Setting system time in GMT (press Set to change time)

(j) Turn off the RDR by pressing the Shutdown button on the web page. With this action, the front panel blue LED turns off. The red LED stays on until the RDR has completed the shutdown operation. Remove DC power connector on the back of the RDR when the red LED turns off.

(k) Disconnect the (CAT-5) network cable from the laptop (network connector) end, and connect to the RADAR Offsite LAN A switch (figure 5-62A).

(l) Apply power to RDR to start the device. Refer to Para. 4.5 “RDR Functionality

Verification” in the Radar Data Recorder user & operation manual.

(8) Test Termination. Verify that the system is operating fault free and control of system

returned to air traffic services.

5-84. through 5-89. Reserved.

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Documents

ORDER CHANGE FEDERAL AVIATION ADMINISTRATION JO … · In compliance with the latest editions of Orders 1100.161, Air Traffic Safety Oversight, and JO 1000.37, ATO Safety Management