08/06/2014 SDR-ASR11-048 TI 6310.47 WP 004 01 1 WORK PACKAGE SYSTEM POWER-UP DIGITAL AIRPORT SURVEILLANCE RADAR ASR-11 EFFECTIVITY: ASR-11 Configurations 1 thru 5. LIST OF EFFECTIVE WP PAGES Total number of Pages in this WP is 8 Page Change Page Change Page Change No. No. No. No. No. No. 1 thru 8 0 TABLE OF CONTENTS Paragraph Page 1 Purpose ............................................................................................................ 3 2 Scope ............................................................................................................... 3 3 Equipment Start-Up Procedure ........................................................................ 3 3-1 System Start-Up ............................................................................................... 3 3-2 Antenna Start-Up ............................................................................................. 5 LIST OF ILLUSTRATIONS Figure Page 1 Main Status Screen 4 2 Antenna in Stow Position 5 3 Antenna Safety Switch in Off Position, Ready for turn on 5 4 Antenna Pedestal Group Status and Control Screen 6 5 MSSR Control Screen 7 6 Transmitter Control Screen 7 LIST OF TABLES Table Page None
139
Embed
DIGITAL AIRPORT SURVEILLANCE RADAR ASR-11...h. At MSSR Interrogator Cabinets (Units 8 and 9), switch MAIN POWER switches to POWER ON. i. At REX/SDP Cabinets (Units 1 and 2), locate
This document is posted to help you gain knowledge. Please leave a comment to let me know what you think about it! Share it to your friends and learn new things together.
Figure Page 1 Main Status Screen 4 2 Antenna in Stow Position 5 3 Antenna Safety Switch in Off Position, Ready for turn on 5 4 Antenna Pedestal Group Status and Control Screen 6 5 MSSR Control Screen 7 6 Transmitter Control Screen 7
LIST OF TABLES Table Page None
08/06/2014 SDR-ASR11-048 TI 6310.47 WP 004 01
2
THIS PAGE INTENTIONALLY LEFT BLANK
08/06/2014 SDR-ASR11-048 TI 6310.47 WP 004 01
3
1. PURPOSE. The purpose of this Work Package (WP) is to provide detailed power-up procedures for the Digital Airport Surveillance Radar (ASR-11). These procedures include System Start-Up and Antenna Start-up used for antenna maintenance. If you are powering up after antenna maintenance, skip ahead to paragraph 3-2. 2. SCOPE. This WP is intended to be used for power-up of the ASR-11/GPN-30 equipment. The assumption is that WP 004-06 was used for shutdown. If any other shutdown procedures were followed, these steps may not correlate. Paragraph 3-1 is for System Start-up if the system power down procedures were used (total site shutdown). Paragraph 3-2 is used if the shutdown was for the antenna only. See WP010 00 FP-1 for power one line diagram for DoD and FP-11 for FAA. 3. EQUIPMENT START-UP PROCEDURE.
3.1 SYSTEM START-UP
a. At Engine Generator (EG) shelter, turn on main service disconnect S1.
b. Enable engine generator by placing the run/off/auto switch to the AUTO position.
c. On the Maintenance Bypass Panel (MBP):
(1) Turn the MODE SWITCH from UPS IN BYPASS to the external UPS NORMAL position.
(2) The external UPS IN BYPASS red indicator light goes out and the UPS NORMAL green
lamp illuminates.
d. At site UPS, follow instructions on inside panel and place the UPS in Normal Mode.
e. At ECU-1 and ECU-2, set ON/OFF switches to ON positions.
f. At Power Distribution Panel DP4 (Channel A REX), set MAIN circuit breaker to ON.
g. At Power Distribution Panel DP5 (Channel B REX), set MAIN circuit breaker to ON position.
h. At MSSR Interrogator Cabinets (Units 8 and 9), switch MAIN POWER switches to POWER
ON.
i. At REX/SDP Cabinets (Units 1 and 2), locate UPS (A10) and press ENABLE OUTPUT ON
button (box with circle.)
j. At REX/SDP Cabinets (Units 1 and 2), locate ASDP Chassis Power switch and turn on both
ASDP power supplies.
08/06/2014 SDR-ASR11-048 TI 6310.47 WP 004 01
4
l. At REX/SDP Cabinets (Units 1 and 2) locate REX power supplies (A11A2) and set circuit
breakers to ON position.
m. At PSR Power Supply Cabinet (Unit 4), set circuit breakers on all PSR Transmitter power
supplies to ON position.
n. At back of cabinet 7, turn on power to both SCDI A and SCDI B.
o. This concludes the System Start-up. When SCDIs complete boot up, main screen SCDI
status should be all green as seen in figure 1. It may take some time for the MSSRs to go green.
Figure 1. Main Status Screen
08/06/2014 SDR-ASR11-048 TI 6310.47 WP 004 01
5
3-2 ANTENNA START-UP
a. If maintenance was performed on antenna, remove stow pin (Figure 2)
Figure 2. Antenna in Stow position
b. At Antenna Pedestal Mezzanine room, remove lockout/tagout devices, notify affected personnel.
c. Turn Pedestal Safety Switch (Figure 3) to ON position.
Figure 3. Antenna Safety Switch in Off Position, Ready for Turn On
d. At selected SCDI, take control.
e. Open Antenna Pedestal Group (APG) Status and Control screen, figure 4.
08/06/2014 SDR-ASR11-048 TI 6310.47 WP 004 01
6
Figure 4. Antenna Pedestal Group Status and Control Screen
f. Set rotation to Start to stop antenna. Verify “Command in Progress” message appears and
after several seconds, “Command is Successful”. You should notice motor current for both motors around 6 or 7 amps.
g. Close APG screen to return to main screen.
h. At both REX/SDP Pop-up menus, select Change Equipment Role/Change to Online.
i. Verify REX/SDP boxes’ color changes to green
j. At both MSSR Pop-up menus, select Change Equipment Role/Change to Online.
k. Verify both MSSR boxes’ color changes to green.
l. At both MSSR channel control screens, figure 5, make sure that RF enable is indicating ON. If it is OFF, click the control to ON.
08/06/2014 SDR-ASR11-048 TI 6310.47
WP 004 01
7
Figure 5. MSSR Control Screen
Figure 6. Transmitter Control Screen
m. At Transmitter Control Screen (figure 6):
(1) Turn on driver power supplies and drivers.
(2) Turn on “All Amplifiers and Amplifier Power Supplies”.
(3) Close transmitter control screen.
n. Verify SCDI Main Status screen in green (figure 1).
4. SYSTEM CONTROL AND MONITORING ........................................................ 4
4-1 ASR-11 RADAR CONTROL PANELS ............................................................... 4 4-2 SYSTEM CONTROL AND MONITORING ........................................................ 4 4-3 LOCAL SCDI REQUIREMENTS ....................................................................... 6 4-4 ROLES OF OPERATION .................................................................................. 7 4-5 LOCAL SCDI CONTROL .................................................................................. 7 4-5.1 Maintenance Role Commands ......................................................................... 7 4-5.2 On-line Role Commands .................................................................................. 7 4-6 LOCAL SCDI MONITORING ............................................................................ 8 4-7 LOCAL SCDI RECONFIGURATION ................................................................ 8 4-8 REMOTE OMTs ................................................................................................ 8 4-9 POINT OF CONTROL ...................................................................................... 8 4-10 RADAR DATA DISPLAY ................................................................................... 9 4-11 PERFORMANCE VERIFICATION TARGET(S) ................................................ 12 4-12 SYSTEM STARTUP ......................................................................................... 12
* *
*
*
XX/XX/XXXX SDR-ASR11-057 TI 6310.47 WP 004 02
2
Paragraph Page 5. SYSTEM EXTERNAL INTERFACES ................................................................ 12 5-1 AUTOMATION INTERFACE ............................................................................. 13 5-1.1 Modified Common Digitizer (CD-2) Format (for STARS) ................................... 13 5-1.2 Digital Surveillance Format ................................................................................ 13 5-1.3 ASTERIX Format (for STARS) .......................................................................... 14 5-1.4 Other Formats ................................................................................................... 15
LIST OF ILLUSTRATIONS
Figure Page
1 Withdrawn by sdr-asr11-057
2 Radar Control Panel ................................................................................................. 5
LIST OF TABLES
Table Page 1 System Control Panel Functions ............................................................................. 6 2 ASDP Target Channel Display Test Points/Display Options .................................. 10 3 ASDP Weather Channel Display Test Points/Display Options .............................. 11 4 ASDP Preprogram Map Display Test Points/Display Options ............................... 11
REFERENCE MATERIAL REQUIRED
Publication Number Publication Title
TI 6310.57A S-Band, Solid State Primary Surveillance Radar Technical Manual
APPLICABLE TCTOS
None
*
*
XX/XX/XXXX SDR-ASR11-057 TI 6310.47 WP 004 02
3
1. PURPOSE. The purpose of this Work Package (WP) is to provide detailed system level operational information for the Digital Airport Surveillance Radar (ASR-11) sites. 2. SCOPE. This WP is intended to be used for reference and guidance in the overall operation of the Digital Airport Surveillance Radar (ASR-11). For a detailed description of the ASR-11 equipment, refer to WP 002 00. 3. OPERATIONAL CONSIDERATIONS. The ASR-11 provides digital information on aircraft targets within a 60 nmi radius of the radar and Monopulse Secondary Surveillance Radar (MSSR) reports from targets at either 60 nmi or 120 nmi (depending on local site configuration) from the radar. The ASR-11 also provides calibrated weather precipitation intensity reports out to 60 nmi. This information is transmitted to DoD/FAA automation subsystems for presentation on controller displays. The ASR-11 has the capability to feed target reports to Automated Radar Terminal System (ARTS)-IIA/E, ARTS-IIIA/E and provides reconstructed surveillance video and weather video for the analog displays. The ASR-11 system is capable of providing the following digital outputs to automation systems:
a. Primary Surveillance Radar (PSR)/Secondary Surveillance Radar (SSR) - merged reports (correlated and uncorrelated).
b. PSR-only reports (correlated and uncorrelated).
c. MSSR-only reports.
d. Six level weather reports. The system provides a capability to send radar, beacon, and weather data in digital format to Standard Terminal Automation Replacement System (STARS) (future). The ASR-11 uses an MSSR that is upgradeable to Mode-S to provide for both surveillance and data link. The ASR-11 provides specific radar features that maintain aircraft detection performance and limit false target reports under any combination of the following:
a. Ground and sea clutter.
b. Precipitation clutter (rain, snow, hail).
c. Bird and “angel” clutter.
d. Long range clutter (second time around ground or precipitation clutter or apparent ground clutter induced by anomalous propagation).
e. Very large discrete clutter, usually from buildings or other man-made objects.
f. Automobile and truck returns.
* *
XX/XX/XXXX SDR-ASR11-057 TI 6310.47 WP 004 02
4
g. Interference from other radars in the same frequency band.
h. Long range aircraft aliased into the instrumented range.
The ASR-11 incorporates a Radar Monitoring Subsystem (RMS) to be used for system optimization and changing selected Variable Site Parameters (VSPs), and for both local and remote monitoring of PSR and MSSR surveillance performance and facility environmental, operational and security conditions, diagnosing faults, and controlling the radar. The ASR-11 operates in either an operational/on-line mode or a maintenance mode. While in an on-line mode, the ASR-11 monitors its operational status and automatically reconfigures to redundant subsystems upon detection of a failure in the on-line channel. 4. SYSTEM CONTROL AND MONITORING. The ASR-11 is capable of:
a. Local (SCDI A, SCDI B, and OMT) and remote (OMT) monitoring of the PSR and MSSR, including receiver sensitivity, transmitted power, and reflected power.
b. Local and remote control, monitoring, and troubleshooting from any Operator Maintenance Terminals (OMTs).
For more details on system control and monitoring, refer to TI 6310.57A, ASR-11 S-Band, Solid State Primary Surveillance Radar Technical Manual 4-1 ASR-11 RADAR CONTROL PANELS. The ASR-11 provides identical radar control panels (Figure 1) and associated software at all Air Traffic Control (ATC) sites (radar site, Terminal Radar Approach Control Center (TRACON)/Radar Approach Control Center (RAPCON) and ATC towers). These panels include all controls, switches, and indicators required for control and status functions as defined in paragraph 4-2. Controls and indicators are clearly visible in the tower cab and TRACON/RAPCON lighting environments. Each panel has an audible alarm. The panels are flush-mounted and all external connections to the panels are made by quick-disconnect jacks and plugs. 4-2 SYSTEM CONTROL AND MONITORING. System controls and status indications are provided on each radar control panel. Table 1 provides a list of the control panel functions and indications. If redundant elements are used, control and status indication functions for both elements are displayed.
* *
XX/XX/XXXX SDR-ASR11-057 TI 6310.47 WP 004 02
5
Figure 1. Withdrawn by sdr-asr11-057.
Figure 2. Radar Control Panel *
* *
*
XX/XX/XXXX SDR-ASR11-057 TI 6310.47 WP 004 02
6
Table 1. System Control Panel Functions
Function Control Function Status Indication
System Alarm
System On-line
PSR A (On-line)
PSR B (On-line)
(PSR) Selected A/B
SSR A (On-line)
SSR B (On-line)
(SSR) Selected A/B
SCDI A (On-line)
SCDI B (On-line)
(SCDI) Selected A/B
UPS Status
EGEN
(Site) Power Status
Antenna
Polarizer Lin/Circ
Polarizer Control
Transmitter Status
Release Control
Take Control
A/C & Hazard
Security
No
No
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
No
Yes
No
Yes
Yes
Yes
No
Yes
Yes
No
No
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
4-3 LOCAL SCDI REQUIREMENTS. The local System Control and Data Interfaces (SCDIs) at the radar site house the RMS (including site control and monitoring), perform the PSR/MSSR combining function, house the surveillance display and serve as the operator interface to the radars. As such, the ASR-11 has dual-redundant SCDIs and associated interfaces to the PSR and MSSR. In the event of a failure of one of the communication interfaces, the SCDI reconfigures to use the other. The redundancy ensures that a single failure of a SCDI does not result in the loss of radar data or control and status data to the user. It is possible to perform maintenance on a SCDI or its interfaces without degradation of normal operation of the ASR-11. It is also possible to turn off and then disconnect the SCDI in a maintenance role without disrupting the operation of the on-line SCDI.
*
*
XX/XX/XXXX SDR-ASR11-057 TI 6310.47 WP 004 02
7
Each SCDI is identified as either Channel A or as Channel B to allow for role determination, reconfiguration etc. Each SCDI interfaces with its dedicated Facilities Monitoring And Control (FMAC) unit.
4-4 ROLES OF OPERATION.
The SCDI subsystem has two roles of operation. These are on-line and maintenance. The on-line role is subdivided into two modes of operation. These are On-line Selected and On-line Standby. The on-line role is the normal role of operation of the SCDI. The On-line Selected SCDI accepts radar data streams from on-line channels of the PSR and MSSR, combines them and outputs the resultant combined data stream to the radar data remoting subsystem. The selected SCDI also provides the maintenance operator with the capability to monitor and control all the radar site equipment and serves as the On-line Selected RMS. The On-line Selected SCDI provides a radar surveillance display.
The On-line Standby SCDI accepts radar data streams from on-line channels of the PSR and MSSR. The On-line Standby SCDI also maintains the same configuration as the On-line Selected SCDI in order to provide the maximum transparency to the user in the event of a reconfiguration. An On-line Standby SCDI provides the maintenance operator with the capability to monitor but not control any radar site equipment. The On-line Standby SCDI provides a Radar Data Display (RDD). Only one SCDI can be in the On-line Selected or On-line Standby mode at a given time. It is an invalid state for two on-line SCDIs to be in the same mode at the same time. Only operational commands will be actioned by SCDIs in the on-line role. The maintenance role is used to perform maintenance activities on the SCDI and on a maintenance role REX/SDP, i.e., maintenance testing and diagnostic testing. The standby SCDI does not control any on-line radar site equipment. The maintenance role combiner/formatter function is under the maintenance operator's control. Operational and maintenance SCDI commands will be actioned by SCDIs functioning in the maintenance role. 4-5 LOCAL SCDI CONTROL. Control and monitoring of the local SCDI will be performed through the site control and monitoring function in the RMS.
4-5.1 Maintenance Role Commands. The following commands are available in the maintenance role:
a. Transition-to-On-line Selected from maintenance selected.
b. Transition-to-On-line Standby from maintenance standby.
c. Enable/disable Auto reconfiguration.
4-5.2 On-line Role Commands. The following commands are available in the on-line role:
a. Transition-to-maintenance.
b. Swap (between selected and standby).
XX/XX/XXXX SDR-ASR11-057 TI 6310.47 WP 004 02
8
c. Enable/disable auto reconfiguration.
d. Enable/disable surveillance radar display.
4-6 LOCAL SCDI MONITORING.
The status of the SCDI can be monitored in maintenance and on-line roles. A serviceable/failed indication will be provided to the site control and monitoring function in the RMS at least once per second. Results of fault detection/fault isolation testing is forwarded to the RMS function. The diagnostic results are displayed so they can be understood without reference to other documentation.
4-7 LOCAL SCDI RECONFIGURATION.
Upon detection of a failure condition, a local SCDI will be declared failed by either itself or the other SCDI. If the SCDI is in an on-line role with the alternate channel in an on-line role, and if auto reconfiguration is enabled, the failed channel will assume the maintenance role and the alternate channel assumes or remains in, the on-line-selected role. If automatic reconfiguration is disabled, then a failed SCDI does not reconfigure automatically. If there is no On-line Standby SCDI available, then an On-line Selected SCDI does not reconfigure to maintenance in the event of a failure. Combiner-generated correlated/Track File Numbers (TFNs) identifying targets will be maintained in such a manner that there is no change in TFNs to the end user at the Automation system in the event of a reconfiguration. Equipment control selections issued to the on-line-selected SCDI will be duplicated in the on-line-standby SCDI so that the equipment configuration is maintained in the event of a reconfiguration. 4-8 REMOTE OMTs.
The remote OMTs contain the same maintenance screens and site control functions as the local SCDIs. The remote OMTs do not have the RDD capability, VSP data files access capability, Map Admin, or Azimuth Alignment. 4-9 POINT OF CONTROL.
The Radar Control Panel (RCPs), OMT, and future National Airspace System (NAS) Infrastructure Management System (NIMS) proxy agent are ASR-11 points of control:
a. Only one control point will be designated as the primary point of control (locking out all others) for the radar site equipment.
b. The capability is provided for transfer of control between designated control points.
c. The transfer of control between two control points require deliberate and coordinated action at each of those control points.
d. Visual signals are provided at both control points during control transfers (except for the future NIMS proxy agent).
e. The system status does not change due to a control point transfer. Each control point provides a visual indication of its status. If an RCP is in control, system status will still be provided to the other OMTs and future NIMS proxy agent.
* *
XX/XX/XXXX SDR-ASR11-057 TI 6310.47 WP 004 02
9
4-10 RADAR DATA DISPLAY. The radar data display is a software interface display that allows the SCDI at the radar site to display selected PSR and MSSR target reports and weather. The display, which is capable of displaying PSR, MSSR, and combiner radar data together with PSR signal processor data, is provided for maintenance purposes at each radar site. It is possible to select the various ranges, PSR, MSSR, combiner, and signal processor input signals by means of control panel display selections. The positional accuracy of displayed data is better than one percent of the screen width.
The display formats for the radar data display are:
a. A-Scope - The A-Scope is a presentation of engineering units versus range in a coordinate (x-y) presentation format for weather level (dB), or Beam (High or Low) where the x-coordinate is the range and the y-coordinate is the engineering unit. The engineering units are amplitude (dB), filter number, and weather coefficient. The range is in nautical miles (nmi) or kilometers (km).
b. B-Scope - The B-Scope is a presentation of range versus azimuth information in a coordinate (x-y) presentation format where the x-coordinate is azimuth in degrees and the y-coordinate is the range from the radar site.
c. Plan Position Indicator (PPI) - The PPI is a presentation of range versus azimuth information in a polar coordinate (r, Q) presentation format where the r-coordinate is range and the Q-coordinate is azimuth measured in degrees clockwise from north.
Subsystem test points signals are selectable for display in one or more of the specified display formats as follows:
a. PSR plot processor output reports (either PPI or B-Scope).
b. PSR track processor output reports (either PPI or B-Scope).
c. PSR edited targets (either PPI or B-Scope).
d. SSR plot extractor output reports (either PPI or B-Scope).
e. Combiner output (either PPI or B-Scope).
f. Signal processor data:
1. Target channel test points per Table 2.
2. Weather channel test points per Table 3.
3. Preprogrammed test points per Table 4. Pan and zoom capabilities are provided for each display format. Panning has the capability of offsetting the PPI to any range/azimuth area at maximum zoom. The SDP provides a data list with range and azimuth identified for all non-vector data items to be displayed on PPI or B-Scope formats. The SCDI display software converts the list data to x-y coordinates and displays them in the selected PPI or B-Scope format. The PPI and B-Scope display of the list data can be updated at a rate compatible with the rate of change of data. The PPI and B-Scope display of vector data is updated at a rate compatible with the rate of change of data.
*
*
XX/XX/XXXX SDR-ASR11-057 TI 6310.47 WP 004 02
10
The A-Scope display of vector data is updated at a minimum rate of 30 Hz. The fixed azimuth A-Scope is the same as continuous A-Scope, except that the operator selects the azimuth, and the display is updated each time the scan passes that azimuth. The adaptive target STC and clutter map is updated at least once every four to five scans and the weather map is updated when the integration cycle is complete (every six scans).
Preprogrammed data does not have to keep up with the scanning of the radar, but can be read from the disk each time the operator makes a request. Display of this data is available for all on-line and maintenance roles/modes of the radar equipment. The display provides a cursor. The PPI cursor is calibrated in rho, theta coordinates. Using the cursor, it is possible to delineate any sector that can be expanded to full resolution. It is also possible to offset the center of the display to any position delineated by the cursor. The display is capable of displaying 900 synthetic targets. It is possible to display alphanumeric data associated with up to 500 tracks (e.g., speed, heading, Mode-3/A code, altitude, etc.). This data can be displayed for all tracks, for no tracks, and for specific tracks which may be selected by cursor position. The use of color or unique symbols is used to more easily identify different target types.
Table 2. ASDP Target Channel Display Test Points/Display Options
Test Point PPI B-Scope A-Scope
Compressed Pulse Video Input Magnitude
Doppler Filter* Video Output Magnitude*
Composite CFAR Threshold Magnitude*
CFAR Detection* Vector Magnitude
Doppler Merge Magnitude
Doppler Merger Filter Number
Binary Integ Output Magnitude
Binary Integrator Filter Number
Clutter Map
Adapt, STC Map,
Merged STC Map
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
* Test point can select any one of five Doppler filters.
* *
*
*
XX/XX/XXXX SDR-ASR11-057 TI 6310.47 WP 004 02
11
Table 3. ASDP Weather Channel Display Test Points/Display Options
Test Point PPI B-Scope A-Scope
Compressed Pulse Video Input Magnitude
Low Pass Filter Video Magnitude
All Pass Filter Video Magnitude
Rejection Filter Video Magnitude
Filter Video Output Magnitude
Weather Clutter Map
PRF Diverse Weather Map*
Merged Weather Map
Weather Contour Thresholds**
Weather Change Points
Circular Weather Coefficient Select
Linear Weather Coefficient Select
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
*Test Point can select any one of four PRFs. **Test Point can select any one of six NWEWS thresholds.
Table 4. ASDP Preprogram Map Display Test Points/Display Options
Test Point PPI B-Scope A-Scope
Target Pre-programmed STC
Target Beam, Hi Res Portion
Target Beam
Weather Pre-programmed STC
Weather Beam
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
It is possible to display a history trail for each target. The history trail is selectable as either infinite length, six scans or off. A clear function is provided to allow the operator to clear the display and refresh the screen with new radar data. It is possible to continuously transfer to magnetic media the data that is being displayed on the display screen. It is then possible to replay stored data back to the display screen. It is also possible to record snapshots of the display screen onto the magnetic media and subsequently replay to the display screen.
*
*
* *
XX/XX/XXXX SDR-ASR11-057 TI 6310.47 WP 004 02
12
4-11 PERFORMANCE VERIFICATION TARGET(S). The ASR-11 provides the following performance monitoring capabilities:
a. In order to provide the quality of radar reports being received from the ASR-11 radar, the following search and beacon Real-Time Quality Control (RTQC) test target messages are provided:
1. Search RTQC (SRTQC) Uncorrelated Test Target - The PSR outputs an internally generated SRTQC uncorrelated once per scan. The formatted message includes position, characteristic and unique (SRTQC) ID information. The SRTQC range and azimuth position is programmable anywhere within the instrumented volume.
2. Search RTQC Correlated Test Target - The PSR passes the uncorrelated RTQC test target through the track process and output a formatted correlated search RTQC message once per scan at the same location but with a unique ID.
3. Beacon RTQC (BRTQC) Test Target - The MSSR outputs an internally generated BRTQC message once per scan. The message is formatted the same as a beacon report message but with a unique (BRTQC) ID.
b. The operator may select the number of reflectors by selecting a VSP. This provides for up to 25 individual reflectors, depending on the number of permanent echoes selected, for establishing the centerline of the runways and known geographical reference points required for radar surveillance approaches.
c. Provide a MSSR Remote Site Monitor (MRSM) consisting of redundant ground-based transponders and antennas included as an integral part of the beacon monitoring function at each site. This allows the system to reply to Modes-3/A, B and C and permits the introduction of a calibrated variable range delay.
4-12 SYSTEM STARTUP. On initial application of power to the MSSR and the PSR, the equipment will independently perform a startup diagnostic sequence prior to assuming an on-line role. Upon successful completion of these sequences, status and configuration of the equipment is reported to the RMS. In the event that a failure is detected by the startup sequence, a diagnostic message is provided to the RMS. The equipment assumes an operational role within seven minutes of application of power for external temperatures from -5 to +70 ° C. Where equipment has been cold soaked (e.g., no power available on site) at temperatures below -5 to -50 ° C, the start-up time will be longer to allow for pedestal pre-heating. This requirement is true for any order or regime of turn-on sequences (e.g., one channel or two channels at a time and after power interruptions). Once powered-up, no further action is required to make serviceable equipment operational. 5. SYSTEM EXTERNAL INTERFACES. The ASR-11 provides external system interfaces to the following subsystems:
a. Existing automation systems (ARTS-IIE and ARTS-IIIE (including DBRITE)).
b. STARS.
c. NIMS proxy agent.
XX/XX/XXXX SDR-ASR11-057 TI 6310.47 WP 004 02
13
5-1 AUTOMATION INTERFACE. The ASR-11 provides four digital data ports to provide independent outputs simultaneously in any combination of the formats listed below. The ASR-11 is capable of being expanded up to 16 digital data ports. A port consists of all necessary hardware and software required to interface with a single automation site (i.e., the necessary OMT interface equipment, software, combinations of LANs, SIUs, fiber optic lines, modems, SDTs and/or telephone lines, etc). 5-1.1 Modified Common Digitizer (CD-2) Format (for STARS).
a. Beacon reports merged with PSR reports.
b. PSR reports that do not merge with beacon reports.
c. Beacon reports that do not merge with PSR reports.
d. PSR test target (RTQC) report.
e. Beacon test target (RTQC) report.
f. Permanent Echo (PE)/MTI reflectors (as unmerged PSR report).
g. Parrot (as unmerged beacon report).
h. Radar site status messages (one per scan or change of status).
i. Sector mark messages. 5-1.2 Digital Surveillance Format. 5-1.2.1 ARTS-IIE.
a. Beacon reports merged with PSR reports.
b. PSR reports that do not merge with beacon reports.
c. Beacon reports that do not merge with PSR reports.
d. PSR test target (RTQC) report.
e. Beacon test target (RTQC) report.
f. PE/MTI reflectors (as unmerged PSR reports).
g. Parrot (as unmerged beacon report).
h. Radar site summary status messages (one per scan or change of status).
i. Sector mark messages. 5-1.2.2 ARTS-IIIE.
a. Beacon reports merged with PSR reports.
b. PSR reports that do not merge with beacon reports.
c. Beacon reports that do not merge with PSR reports.
d. PSR test target (RTQC) report.
XX/XX/XXXX SDR-ASR11-057 TI 6310.47 WP 004 02
14
e. Beacon test target (RTQC) report.
f. PE/MTI reflectors (as unmerged PSR reports).
g. Parrot (as unmerged beacon report).
h. Radar site summary status messages (one per scan or change of status).
i. Sector mark messages.
5-1.2.3 Reconstituted Search and Beacon Video.
a. Beacon reports merged with PSR plots which are split and displayed as PSR reports and Beacon reports - off set with distinguishing slash indicators.
b. PSR reports that do not merge with beacon reports - Distinguishing slash indicator.
c. PSR reports that do not merge with beacon reports - Distinguishing slash indicator.
d. Beacon reports that do not merge with PSR reports - Distinguishing slash indicator.
e. PSR test target (RTQC) report.
f. Beacon test target (RTQC) report.
g. PE/MTI reflectors (as unmerged PSR reports).
h. Parrot (as unmerged beacon report).
i. Six level weather - Two levels displayed - Operator selectable.
j. ACP/ARPs.
5-1.3 ASTERIX Format (for STARS).
a. Beacon reports merged with PSR reports.
b. PSR reports that do not merge with beacon reports.
c. Beacon reports that do not merge with PSR reports.
d. PSR primitives merged with beacon primitives.
e. PSR primitives that do not merge with beacon primitives.
f. Beacon primitives that do not merge with PSR primitives.
g. Beacon primitives merged with PSR reports.
h. Beacon reports merged with PSR primitives.
i. PSR test target (RTQC) primitives and reports.
j. Beacon test target (RTQC) reports (including primitives).
k. PE/MTI reflectors (as unmerged PSR reports).
l. Parrot (as unmerged beacon report).
m. Six Level Weather.
n. Radar site summary status.
o. Sector messages.
XX/XX/XXXX SDR-ASR11-057 TI 6310.47 WP 004 02
15
5-1.4 Other Formats. The ASR-11 is also upgradeable to accommodate other automation systems in modified digitizer (CD-2) format:
a. Beacon reports merged with PSR reports.
b. PSR correlated reports that do not merge with beacon reports.
c. PSR reports that do not merge with beacon reports.
d. Beacon reports that do not merge with PSR reports.
e. PSR test target (RTQC) report.
f. Beacon test target (RTQC) report.
g. PE/MTI reflectors (as unmerged PSR reports).
h. Parrot (as unmerged beacon report).
i. Weather messages, including six-level weather reports.
j. Radar site status messages (one per scan or change of status).
k. Sector mark messages.
XX/XX/XXXX SDR-ASR11-057 TI 6310.47 WP 004 02
16
This page intentionally left blank.
XX/XX/XXXX SDR-ASR11-057 TI 6310.47 WP 004 03
1
WORK PACKAGE
SYSTEM INSPECTION
DIGITAL AIRPORT SURVEILLANCE RADAR ASR-11
EFFECTIVITY: ASR-11 Configurations 1 thru 5
TABLE OF CONTENTS
Paragraph Page
1. PURPOSE ............................................................................................................ 3 2. SCOPE ................................................................................................................. 3 3. INITIAL SYSTEM INSPECTION ........................................................................... 3 4. PRE-OPERATION, POST OPERATION, AND PREVENTIVE
TI 6310.56 Digital Airport Surveillance Radar ASR-11 System Manual for MSSR System
TI 6310.53 Digital Airport Surveillance Radar ASR-11 Equipment Manual for Condor MSSR Interrogator
TI 6310.54 Digital Airport Surveillance Radar ASR-11 Equipment Manual for Dual Channel Site Monitor
TI 6310.59 Digital Airport Surveillance Radar ASR-11 Antenna and Drivetrain TI 6310.55 Digital Airport Surveillance Radar ASR-11 Equipment Manual for
Condor LVA Antenna TI 6310.57AA Digital Airport Surveillance Radar, ASR-11 S-Band, Solid State Primary
Surveillance Radar Technical Manual
APPLICABLE TCTOS
None
*
*
TI 6310.47
1 DECEMBER 2003 WP 004 03
3
1. PURPOSE.
The purpose of this Work Package (WP) is to provide detailed system level inspection criteria for the Digital Airport Surveillance Radar (ASR-11).
2. SCOPE.
This WP is intended to be used for the initial system-level inspection for the ASR-11 equipment. For a detailed description of the ASR-11 equipment, refer to Reference Material Required section.
WARNING
PERSONNEL PERFORMING MAINTENANCE SHOULD READ AND BECOME FAMILIAR WITH THE SAFETY SUMMARY LOCATED IN THE FRONT OF THIS MANUAL.
3. INITIAL SYSTEM INSPECTION.
Initial inspection is accomplished by performing the following steps:
a. Inspect S-Band Antenna per Antenna Manual listed in Reference Material Required List.
b. Inspect Antenna Pedestal per Antenna Pedestal Manual listed in Reference Material Required List.
c. Inspect MSSR Interrogators A and B per MSSR Manual Set listed in Reference Material Required List.
d. Inspect PSR equipment per Section 5 of the PSR Manual listed in Reference Material Required List.
e. Inspect remaining units of ASR-11 and assemblies of those units (UPS, HVAC, Compressor/Dehydrator, Engine-Generator, load bank, and fuel storage tank) as follows:
1. Prepare to inspect selected unit by ensuring input power circuit breakers or switches of unit are OFF, and by ensuring associated input power circuit breaker is OFF, tagged out, and locked out in accordance with locally approved procedures.
2. Open up selected unit by opening doors and removing covers as necessary to view assemblies of unit.
3. Visually inspect each listed assembly of selected unit for missing parts, damage, degradation, and looseness.
4. Perform immediate corrective action for each discovered deficiency, or record discovered deficiencies for future corrective action.
5. Record serial numbers for each listed assembly.
6. Close up inspected unit.
7. Remove tagout/lockout devices, if used, and operate input power circuit breakers and switches as required.
8. Repeat steps 1 thru 7 for each unit.
09/11/2007 SDR-ASR11-009 TI 6310.47 WP 004 03
4
4. PRE-OPERATION, POST OPERATION, AND PREVENTIVE MAINTENANCE INSPECTIONS.
These inspections are performed per instructions and schedules contained in the respective manual for each item of equipment.
MMH356943 Receiver Health Monitor for use with DASR ASR-11
APPLICABLE TCTOS
None
07/01/2009 SDR-ASR11-020 TI 6310.47
WP 004 04
3
1. PURPOSE.
The purpose of this Work Package (WP) is to provide detailed fault isolation procedures for the Digital Airport Surveillance Radar (ASR-11). These procedures include fault isolation from remote Operator Maintenance Terminals (OMTs) as well as local OMTs.
2. SCOPE.
This WP is intended to be used for fault isolation of the ASR-11 equipment. For a detailed description of the ASR-11 equipment, refer to Reference Material Required section.
3. FAULT ISOLATION PROCEDURES.
3-1 AUTOMATIC FAULT ISOLATION.
Fault isolation is automatically performed during the normal operation of the equipment. If a fault occurs, the subsystem affected will be put in Standby mode and the Main Status Screen box will turn red. A fault alarm window located at the top right of the OMT Main Status Screen displays system fault messages. These fault messages are discussed further in Section 4 of G584380, ASR11 S-Band Primary Surveillance Radar Equipment Manual.
To determine if automatic fault isolation has determined the faulty item, perform the following:
a. Log on and take control of system.
b. Acknowledge alarm condition by clicking on ACK button to right of fault alarm window.
c. Verify which subsystem has fault by viewing Main Status Screen.
d. Review detailed status screen for faulted subsystem.
e. If detailed status screen failed to indicate a specific faulted LRU, or the results were ambiguous, perform Manual Fault Isolation, paragraph 3-2.
f. Once the defective module is identified, turn off power to defective module and replace with serviceable module.
g. Turn on power to module and run diagnostics to confirm operational status.
h. If automatic fault isolation and module substitution does not clear fault condition, check interconnections between modules or between modules and cabinets.
3-1.1 Receiver Health Monitor
The Receiver Health Monitor (RHM) is an optional unit provided with specific versions of the Digital Airport Surveillance Radar (DASR). The RHM is capable of detecting and reporting degraded performance in the Target High Beam and Weather High/Low Beam receive paths, including components such as the Rotary Joint and Weather Polarizer switch. Refer to MMH356943 for further information.
07/01/2009 SDR-ASR11-020 TI 6310.47
WP 004 04
4
3-2 MANUAL FAULT ISOLATION.
Manual fault isolation is performed by running a series of fault isolation tests. If fault is in the PSR system, refer to Corrective Maintenance procedures located in Section 6 of G584380 ASR11 S-Band Primary Surveillance Radar Equipment Manual. If fault is in the MSSR system, refer to WP 006 00.
990-4202 Quick Reference Guide (APC) 2100-678 Economizer Replacement Parts Manual (Bard) (DOD Only) 2100-391 Installation Instructions Economizers with Exhaust (Bard) (DOD Only) 2100-034 Owner’s Manual Heat Pump and Air Conditioner (Bard) (DOD Only) 2100-002 Servicing Procedure (Bard) (DOD Only) 2110-613 Replacement Parts Manual - Wall Mount Heater Package (Bard) (DOD Only)
79680 Installation and Maintenance Manual for Model 174100 ASR11 S-Band Antenna (Andrews), in Section 11 of PSR Manual.
79691 Operation and Maintenance Manual ASR-11 Antenna Pedestal Model 174670 (Andrews), in Section 11 of PSR Manual.
164201014 Installation Manual for International Power Machines Balanced Power 30 - 80 KVA Uninterruptible Power System
164201016 Operation Manual for International Power Machines Balanced Power 30 - 160 KVA Uninterruptible Power System
164201017 Installation Manual for International Power Machines Balanced Power Model 27 and Model 43 Auxiliary Battery Cables
167200726 Exide Electronics Powerware Plus International Power Machines (IPM) Balanced Power III 30-160 KVA Uninterruptible Power System Service Manual
126P033120 MPS800 Multi-Protocol Communications Server Hardware Reference Manual (UCONIX)
15-00002-00 Multiport 400S/800S A/Sync Series User's Manual (Aurora) 2100-277c Installation Instructions - Wall Mount Packaged Air Conditions (Bard) (DOD Only)
2110-419C Replacement Parts Manual - Wall Mount Air Conditioner (Bard) (DOD Only)
3-800-980-21(1) Color Monitor Guide - SUN GDM 17/20 E20N 3AFY 61201360 R0225 ACS 601 Frequency Converters 2.2 to 110 KW Installation and Startup Manual (ABB)
6000-004 Site Technical Manual and Assembly Procedures for the Digital Airport Surveillance Radar (DASR) Tower (COMSAT)
07/01/2009 SDR-ASR-11-020 TI 6310.47 WP 004 05
3
LIST OF RELATED PUBLICATIONS - CONTINUED
Publication Number Publication Title 730-007174 Installation, Operation and Maintenance Manual for the Surveillance Data Translator (SDT) of the Airport Surveillance Radar (ASR-11) Data Translator Equipment (DTE) (Sensis)
730-009116 Installation, Operation and Maintenance Manual for the Digital Airport Surveillance Radar (DASR) Data Translator Equipment System (Sensis)
780-004232 Installation, Operation, and Maintenance Manual for the System Interface Unit (SIU) of the ASR-11 Data Translator Equipment (DTE) (Sensis)
K675D24628 AVTRON Model K675A Outdoor Resistive Load Bank Part Number K675D24628, 100KW 480 VAC 5 KW Resolution Load Steps: 5, 10, 10, 25, 50 KW
MA150A Technical Manual for Moving Target Indicator (MTI) Reflector, S Band PSI Model A-150a (RPM/PSI)
MICRO-M-2D Microelectronic Operation and Unit Troubleshooting (18-HH60E2-4)
NA Raytheon Four Unit Control System Manual (ASI Controls) None Engine Generator Building Technical Manual - Digital Airport Surveillance Radar (DASR) (CSI)
None Equipment Building Technical Manual - Digital Airport Surveillance Radar (DASR) (CSI)
APPLICABLE TCTOS LIST OF RELATED PUBLICATIONS - CONTINUED
None
07/01/2009 SDR-ASR11-020 TI 6310.47
WP 004 05
8
1. PURPOSE. Maintenance Handbooks provide direction for scheduling and performing maintenance on all FAA systems. This Work Package (WP) provides a list of all Maintenance Handbooks that apply to the Airport Surveillance Radar/Digital Airport Surveillance Radar (ASR-11/DASR) system. These handbooks should be referenced for direction on all periodic maintenance activities. 2. SCOPE. This WP is intended to be used for system-level maintenance for the ASR-11 equipment. For a detailed description of the ASR-11 equipment, refer to Reference Material Required section. 3. INTRODUCTION. This section provides references to system-level performance procedures, preventive maintenance procedures, and special maintenance procedures that must be performed on a recurring basis. Performance of these system-level procedures at the recommended intervals and performance of the unit-level procedures at the recommended intervals ensure optimum operation of ASR-11. 4. PREVENTIVE MAINTENANCE PROCEDURES. Preventive maintenance procedures are performed to prevent deterioration and maintain proper operation of various system-level units and items. Preventive maintenance procedures are identified in the appropriate Maintenance Handbook. If any difference exists between the time-interval for preventive maintenance called for in vendor manuals and in the appropriate Maintenance Handbook, the Maintenance Handbook intervals take precedence. 5. LIST OF MAINTENANCE HANDBOOKS FOR ASR-11 SYSTEM Reference these manuals for direction on periodic maintenance. These manuals are available on; TechNet/Reference/Maintenance Handbooks/Maint. Handbooks (AJW-
TABLE 1. ASR-11 Maintenance Handbooks EQUIPMENT ORDER
Antenna Systems 6310.30 Batteries for Standby Power 6980.25c Electrical Distribution Systems 6950.18a Electrical Power and Control Cables 6950.22 Electrical Systems in Buildings 6950.17a Engine Generators 6980.11d Environmental Systems 6970.3a Primary Surveillance Radar 6310.30 Secondary Surveillance Radar 6310.30 Uninterruptible Power Systems (UPS) 6980.29a
3-1 ANTENNA AND PEDESTAL POWER-DOWN ........................................................ 3
3-2 SYSTEM POWER-DOWN. ...................................................................................... 7
08/06/2014 SDR-ASR11-048 TI 6310.47
2
LIST OF ILLUSTRATIONS
Figure Page
1 Main Status Screen ..................................................................................................... 3
2 MSSR Control Screen ................................................................................................. 4
3 Transmitter Control Screen .......................................................................................... 5
4 Antenna Pedestal Group Status and Control Screen .................................................. 6
5 Antenna Safety Switch in Off Position, Ready for lockout/tagout ................................. 7
6 Antenna in Stow Position ............................................................................................. 7
7 Simplified Power Drawing ............................................................................................. 9
LIST OF TABLES
Table Page
None
REFERENCE MATERIAL REQUIRED
Publication Number Publication Title
None
APPLICABLE TCTOS
None
08/06/2014 SDR-ASR11-048 TI 6310.47
WP 004 06
3
1. PURPOSE.
The purpose of this Work Package (WP) is to provide detailed power-down procedures for the Digital Airport Surveillance Radar (ASR-11). These procedures include Antenna and System power-down. 2. SCOPE. This WP is intended to be used for power-down of the ASR-11 equipment. There are two parts to this procedure. Paragraph 3-1 is Antenna Power-Down and is used for antenna maintenance and does not shut down the PSR or MSSR equipment. Paragraph 3-2 is system power down and is used for a total site shutdown. If you are performing a Total site shutdown, paragraph 3-2, you must perform paragraph 3-1 first and then continue on to paragraph 3-2.
3. POWER-DOWN PROCEDURES. Notify all affected personnel that the equipment will be taken out of service and that lockout/tag out procedures will be employed 3-1 ANTENNA AND PEDESTAL POWER-DOWN.
a. At SCDI Main Status Screen (Figure 1), click on selected MSSR.
Figure 1. Main Status Screen
08/06/2014 SDR-ASR11-048 TI 6310.47
WP 004 06
4
b. At MSSR Pop-up Menu, select Equipment Control.
c. At MSSR Control Screen (Figure 2):
(1) Set Interrogator RF Enable to Off.
(2) Select CONFIRM on Confirm Action Dialog Box.
(3) Select CLOSE to return to Main Status Screen.
Figure 2. MSSR Control Screen
WARNING: Disabling RF Will Cause Alarms and Alerts to Be Reported By the System to the SCDI. These Are Normal Because the System Is In A Non-Operational State.
d. At SCDI Main Status Screen, click on Tx.
e. At Transmitter Pop-up Menu, select Equipment Control.
f. At Transmitter Control Screen (Figure 3):
(1) Set all amplifiers and amplifier power supplies to off.
(2) Select CONFIRM on Confirm Action Dialog Box.
(3) Set to OFF both drivers and driver power supplies manually.
(4) Select CLOSE to return to SCDI Main Status Screen
08/06/2014 SDR-ASR11-048 TI 6310.47
WP 004 06
5
Figure 3. Transmitter Control Screen
WARNING: Disabling RF Will Cause Alarms and Alerts to be Reported By the System to the SCDI. These are Normal Because the System is in a Non-Operational State.
g. At SCDI Main Status Screen, click on standby MSSR box. Verify MSSR Pop-up Menu appears.
h. At MSSR Pop-up Menu, select Change Equipment Role → Change to Maintenance. Verify MSSR box color changes to orange.
i. At SCDI Main Status Screen, click on Selected MSSR box. Verify MSSR Pop-up Menu appears.
j. At MSSR Pop-up Menu, select Change Equipment Role → Change to Maintenance. Verify MSSR box color changes to orange.
k. Select CONFIRM on Confirm Action Dialog Box.
l. At SCDI Main Status Screen, click on standby REX/SDP box. Verify REX/SDP Pop- up Menu appears.
m. At REX/SDP Pop-up Menu, select Change Equipment Role → Change to Maintenance. Verify REX/SDP box color changes to orange.
n. At SCDI Main Status Screen, click on selected REX/SDP.
o. At REX/SDP Pop-up Menu, select Change Equipment Role -+ Change to Maintenance. Verify REX/SDP box color changes to orange.
08/06/2014 SDR-ASR11-048 TI 6310.47
WP 004 06
6
p. At SCDI Main Status Screen, click on APG.
q. At APG Pop-up Menu, select Detailed Status & Control. Verify Antenna Pedestal Group Status and Control Screen (Figure 4) appears.
Figure 4. Antenna Pedestal Group Status and Control Screen
r. At Antenna Pedestal Group Status and Control Screen: (Figure 4)
(1) Set Rotation to Stop to stop antenna. Verify "Command In Progress" message appears and after several seconds, command is successful.
WARNING: While Antenna Rotation is stopped, there will be many PSR and MSSR Alarms and Alerts Reported by the System at the SCDI. These are Normal because the System is in a Non-Operational State.
(2) Verify Motor A and Motor B switch from Run to Stop.
(3) Press CLOSE to return to Main Status Screen.
s. If performing system shutdown skip the next two steps and proceed to paragraph 3-2.
t. At Antenna Pedestal Mezzanine room, turn Pedestal Safety Switch (figure 5) to off position and insert lockout/tagout device.
08/06/2014 SDR-ASR11-048 TI 6310.47
WP 004 06
7
Figure 5. Antenna Safety Switch in Off Position Ready for Lockout/Tagout
u. If maintenance is to be performed on antenna, insert stow pin (figure 6), prior to starting.
Figure 6. Antenna in Stow Position
3-2 SYSTEM POWER-DOWN.
a. Perform Antenna Power-Down procedure (paragraph 3-1) through step r.
b. At standby SCDI Main Status Screen (figure 1), click on any open background area to open site Pop-up Menu.
c. At Site Pop-up Menu, select Local Workstation Actions.
(1) Verify Local Workstation Actions Screen appears.
(2) At Local Workstation Actions Screen:
a) Select SCDI Shutdown.
b) Enter proper password and select OK.
d. At selected SCDI Main Status Screen, click on any open background area to open site Pop-up Menu. Verify Site Pop-up Menu appears.
e. At Site Pop-up Menu, select Local Workstation Actions.
08/06/2014 SDR-ASR11-048 TI 6310.47
WP 004 06
8
(1) Verify Local Workstation Actions Screen appears:
(2) At Local Workstation Actions Screen:
a) Select SCDI Shutdown. The SCDI will the power down and shut off.
f. PSR Power Supply Cabinet (Unit 4), set circuit breakers on all PSR Transmitter power supplies to OFF position.
g. At REX/SDP Cabinets (Units 1 and 2), locate REX power supplies (A11A2) and set circuit breakers to OFF position.
h. At REX/SDP Cabinets (Units 1 and 2), locate ASDP Chassis Power switch and turn off both ASDP Power supplies.
i. At REX/SDP Cabinets (Units 1 and 2), locate UPS (A10) and press ENABLE OUTPUT Off button (box with circle).
j. At MSSR Interrogator Cabinets (Units 8 and 9), switch MAIN POWER switches to POWER OFF.
k. At Power Distribution Panel DP5 (Channel B REX), set MAIN circuit breaker to OFF position. See WP010 00 FP-1 for power one line diagram for DoD and FP-11 for FAA.
l. At Power Distribution Panel DP4 (Channel A REX), set MAIN circuit breaker to OFF position.
m. At Site UPS, follow instructions on inside panel and “shut down the UPS from Normal Mode” and verify on screen display that UPS is bypassed internally.
08/06/2014 SDR-ASR11-048 TI 6310.47
WP 004 06
9
Figure 7. Simplified Power Drawing
XX/XX/XXXX SDR-ASR11-057 TI 6310.47
WP 004 06
10
n. On the UPS Maintenance Bypass Panel (MBP):
(1) Turn the MODE SWITCH from “UPS NORMAL” to the external “UPS IN BYPASS” position.
(2) The external “UPS IN BYPASS” red indicator light illuminates and the “UPS NORMAL” green lamp goes out
Note: There may be times when you believe that you can keep the Air Handlers operational because the weather event requires radar shutdown, but may not be strong enough to justify killing site power. To keep the Air Handlers operational, stop the shutdown procedure here.
o. For FAA Installations, at ECU-1 and ECU-2, set ON/OFF switches to OFF positions. For DOD Installations, at DP1 power down the ECUs by turning off CB 1, 3, 5 (ECU1); CB 7, 9, 11 (ECU2); CB 8, 10, 12 (ECU3); and CB 15, 16, 18 (ECU4). Also at DP1, power down the ECU controller by turning off CB 2, 4.
p. In EG Shelter, disable Engine Generator (EG) from starting by placing the run/off/auto switch to the OFF position, main Kohler Engine Control panel. An alarm will sound that cannot be silenced but this action will prevent the Engine Generator from starting in the event of a power failure.
q. All lights will be off, have flashlight nearby. In EG Shelter at Main Service Disconnect, switch the main commercial power feed to the OFF position.
070011UC User Manual Model 2014 Interface Powered RS-530 to V.35 Converter
07M2014C Model 2014 Interface Powered RS-530 to VF.35 Converter User Manual (Patton Electronics)
126P033120 MPS800 Multi-Protocol Communications Server Hardware Reference Manual (UCONIX)
730-009116 TI 6310.50, Digital Airport Surveillance Radar ASR-11 Installation, Operation and Maintenance Manual for the DASR Data Translator Equipment (DTE) System
TO-129-02, Rev. D Hardware Advisory Notice, MR64 Installation and Operation User’s Manual Addendum, MR64 with Advanced Rate Enhancement Functions (Motorola)
* *
*
*
09/11/2007 SDR-ASR11-009 TI 6310.47
WP 004 07
5
1. PURPOSE. The purpose of this Work Package (WP) is to provide detailed system level interconnections for the Digital Airport Surveillance Radar (ASR-11) sites. 2. SCOPE.
This WP is intended to be used to detail the system interconnections of the ASR-11 equipment.
3. SYSTEM INTERCONNECTION. The ASR-11 is comprised of various Commercial Off-The-Shelf (COTS) equipment. The system is interconnected by various cable assemblies. The following paragraphs describe the interconnections of the system. 3-1 INTERCONNECTION DIAGRAMS. Figure FO-1show the System interconnections diagram for a typical ASR-11 Site. Figure FO-2 provides the DASR Generic Communications System diagrams for typical ASR-11 Sites. Figure FO-3 shows the IP addressing scheme for the system, and Figure FO-4 has Fault Isolation Diagrams. Additional information for communications interconnects is available in the Site Acceptance Test Plan, Appendix C (FAA Sites) or Appendix D (DoD) sites. 3-2 INTERCONNECTION CABLES. The majority of the ASR-11 cable set are cables provided with the different COTS equipment. The cable set is divided into three groups:
a. Radar Electronic Housing Interconnection Cables, Table 1
b. Tower and Pedestal Room Interconnection Cables, Table 2
c. Engine Generator Room Interconnection Cables, Table 3 The following paragraphs provide information on the cable groups. 3-2.1 Radar Electronic Housing Interconnection Cables. Table 1 lists the interconnection cables in the radar electronic housing and briefly describes their purposes. 3-2.2 Tower and Pedestal Room Interconnection Cables. Table 2 lists the interconnection cables in the tower and pedestal room and briefly describes their purposes.
3-2.3 Engine Generator Room Interconnection Cables. Table 3 lists the interconnection cables in the engine generator room and briefly describes their purposes.
Cable From Unit From To Unit To No. Cable Function Nomenclature Unit No. Nomenclature Unit No.
W7201B E-G Housing Status Transient 7 Radar Transient 14 And Control Protection Box Protection Box
W7203 E-G Status EG Set 6 Transient Protection Box
7
W7214 Fuel Leak Day Tank 5 Transient Protection Box
7
W7215 Intrusion Alarm Door 2 Switch S2 Transient Protection Box
7
W7216 Power STATUS ATS 1 Transient Protection Box
7
W7217 Main Breaker Status Main Power Panel K1 Transient Protection Box
7
W7218 Fire Detection Heat Sensor And S3 & A8 Transient 7 Smoke Detector Protection Box
W7219 Intrusion Alarm Door 2 Switch S1 Transient Protection Box
7
Cable From Unit From To Unit To No. Cable Function Nomenclature Unit No. Nomenclature Unit No.
W1802B Lube System Status Antenna Transient 31A12 J2 Surge Suppression 34A1 J1 Protection Box Panel U34A1
W1802C Lube System Status Surge 34A1 J4 Local Pedestal 34 J18 Suppression Panel Control Panel
W9601B Encoder X Azimuth Antenna Transient 31A12 J3 Surge Suppression 35A7 J2 Data Protection Box Panel U35A7 & Local Control Panel 34 J6
W9601C Encoder X Azimuth Data
Surge Suppression Panel
35A7 J6 Encoder X 35A6B3 J1
W9602B Encoder Y Azimuth Antenna Transient U31A12 J4 Surge Suppression 31A12 J3 Data Protection Box Panel U35A7 & Local Control Panel 34 J7
W9602B Encoder Y Azimuth Data
Surge Suppression Panel
U35A7 J7 Encoder Y 35 A6B4 J1
09/11/2007 SDR-ASR11-009 TI 6310.47
WP 004 07
13
3-3 COMMUNICATIONS SYSTEM WIRING. Figure 1 provides the cable pinouts for the Short Haul Modem Cable Assembly. Figure 2 provides the cable pinouts for the Cross Connect Cable Assembly. Figure 3 provides the cable pinouts for the CAT-5 Cable Assembly. 4. DASR COMMUNICATIONS. 4-1 WITHIN THE RADAR SHELTER. There are two 10 Mbps Ethernet outputs from the PSR. Each PSR Ethernet output connects to a separate Ethernet switch. The Ethernet switches distribute the PSR data to both SCDIs over 10Base-T Ethernet, such that each SCDI receives data from both PSRs. 10Base-2 Ethernet uses 50 ohm coaxial cable and 10Base-T Ethernet uses eight conductor Unshielded Twisted Pair (UTP) cable. Each SCDI receives data (RS-422) from both MSSRs via the offsite LAN. MSSRs feed serial data to the MPS, which is connected to the offsite LAN. A single RCP interfaces to both SCDIs via the MPS server. For testing, an RS-232 A/B switch is used to select between the SCDIs connecting to the RCP. The RCP interface is described in section 2.1. The DASR communications system is comprised of two parallel (redundant) paths. To assist with the following descriptions and aid understanding, the two paths will arbitrarily be referred to as primary and alternate. In most instances, each major information processing unit connects to both the primary and the alternate path. 4-2 BETWEEN THE RADAR SHELTER AND THE TRACON/RAPCON.
Refer to Figure FO-2, sheet 4.
Two separate Ethernet ports on each SCDI output data for the TRACON/RAPCON. One port of each SCDI connects to an Ethernet switch on the primary LAN (OFFSITE LAN A), and the other port of each SCDI connects to a second switch on the alternate LAN (OFFSITE LAN B). The physical implementation of the connections between the radar shelter and the TRACON/RAPCON, as well as the selection of hubs versus switches is determined by the wire distance between the radar shelter and the TRACON/RAPCON. For installations where the cable length between the radar shelter hub and the automation system is less than 100 meters, a UTP cable can connect the automation system directly to the radar shelter hub. When the cable length between the radar shelter hub (or switch) and the TRACON/RAPCON hub (or switch) is less than 2 km, the end devices may be Ethernet switches connected by multimode fiber optic cable. Ethernet switches and single mode fiber optic cable will also work in this configuration. When the distance is greater than 2 km, the end devices must be Ethernet switches connected over single mode fiber optic cable. Ethernet hubs and multimode fiber optic cable cannot be used for distances greater than 2 km.
*
*
09/11/2007 SDR-ASR11-009 TI 6310.47
WP 004 07
14
PART NUMBER VENDOR DESCRIPTION
JPM051 A BLACK BOX CROSS-CONNECT BLOCK, RJ-45 / TYPE 110 CONTACTS
4-3 DASR to TRACON/RAPCON (Refer to Figure FO-2, sheet 8.) DASR interfaces to existing automation systems such as ARTS IIE, STARS automation systems, and the ARTS-IIIE. Normally the ASR-11 connects to the remote facility with * fiber, but when the distances between the two facilities are too great, then routers and modems are used to connect the facilities. There are other configurations where the routers or modems must be used such as:
OMT terminal is not located in close proximity to the remote site Ethernet switches SIU outputs are remoted to TRACONs Radar Control Panels (RCPs) are not near the OMT. SDTs cannot be connected with Fiber
Tower RCP. (Refer to Figure FO-2, sheet 6.) The RCP interface is through an RS-232 asynchronous serial connection. In normal operation the SCDI (or OMT) sends an 8 byte status message to the RCP once per second. The RCP responds with a 2 byte service message. Both bytes in the service message are identical. The service message contains commands from the RCP to the SCDI (or OMT). The RCP has a DB-25M connector. Pin 2 is the transmit data out of the RCP. Pin 3 is the receive data and pin 7 is the signal ground. The serial data format is: 9600 bps, 1 start bit, 1 stop bit, no parity, and 8 data bits. The OMT interfaces to the RCP over a serial line. When the distance between the OMT and the RCP is less than 15.2 m, the OMT can be directly wired to the RCP using a standard EIA-232 cable as shown in Figure 4.
Figure 4. RCP Electrical Interface and Configuration - Direct Connection
*
*
08/06/2014 SDR-ASR11-048 TI 6310.47 WP 004 07
17
For distances greater than 15.2 m and less than 5.5 km, the connection between the OMT and RCP may use back to back short haul modems (RAD SRM-5 at the OMT end, RAD SRM-5 with power supply at RCP end) as shown in Figure 5.
Figure 5. RCP Electrical Interface and Configuration - Modem Connection
For distances greater than 5.5 km and less than 11 km, CSU/DSUs must be used. The back to back CSU/DSUs may also be used for any distance less than 5.5 km, but the short haul modems offer a more cost effective solution.
4-3.1 DASR to STARS Interface, Surveillance Interface Unit (SIU). (Refer to Figure FO-2, sheet 2.) The DASR ASR-11 outputs radar data in the ASTERIX format on Ethernet LANs. The current STARS system receives modified CD-2 radar data on serial input ports. The radar data is converted from the ASTERIX format to the modified CD-2 format by SIUs. The SIU receives the radar data through an Ethernet port and outputs the data on a 56 kbps synchronous EIA-530 serial link to the STARS automation system. The SIUs can also reformat ASTERIX radar data, as IP datagrams encapsulated in HDLC frames and pass the ASTERIX data through. Two SIUs, one for each LAN, and an OMT are located in the TRACON/RAPCON. The OMT interfaces to up to two RCPs, which may be located in the TRACON/RAPCON or in the Tower. The RCPs interface with the OMT through back to back modems when the distance is greater than 50 feet (15.2 meters). When the distance between the SIU and the automation system is less than 1.2 km, the SIU output can be wired directly to the automation system input using a standard EIA-530 null modem cable. When the distance between the SIU and the STARS automation system is greater than 1.2 km, back to back Channel Service Unit/Data Service Units (CSU/DSUs) are used to connect the SIU to the automation system. For distances less than 7.5 km, the CSU/DSUs can be directly connected to each other. For distances greater than 7.5 km, the CSU/DSUs must be connected over 56 kbps Category A, 4-wire Dataphone Data Service (DDS-56). When the CSU/DSUs are wired back to back, the interconnections between the CSU/DSUs are described in FO-2 Sheet 7. Sheet 7 assumes the majority of the cable is existing premise wiring. Since both CSU/DSUs have the same connector pinouts, a crossover cable is required. The crossover cable is described in Figure 2. The CSU/DSUs only require four conductors to communicate. Pins 3 and 4 are crossed and pins 5 and 6 are crossed. When the CSU/DSU cannot be located within six feet of the remote automation system, active EIA-
08/06/2014 SDR-ASR11-048 TI 6310.47 WP 004 07
18
530 buffers/drivers are inserted between the CSU/DSU and the automation system.
11/17/2016 SSM-ASR11-124 TI 6310.47 WP 004 07
19
4-3.2 DASR to ARTS-IIE, Surveillance Data Translator (SDT). (Refer to Figure FO-2, sheet 4.) DASR interfaces to existing automation systems through redundant Surveillance Data Translators (SDT). The SDT receives and processes the ASTERIX Ethernet radar data and provides digital data in the appropriate format to existing automation systems. DASR provides data to existing automation systems using either fiber cable or routers. If routers are used, the serial data is transmitted over wires or commercial telephone lines using Fractional T1 (integral with the routers). A router at the remote automation system end converts the serial data back to a LAN to be used by the SDT. The ASTERIX radar data on each of the LANs at the radar site feeds a small router. The main function of the routers is to place the radar data onto a Fractional T-1 line provided by telco. The receiving router takes the data from the T-1 lines and outputs the data through a 10Base-T Ethernet port. Switches are provided at each router LAN output. Each switch sends the radar data to both SDTs for the automation system. To maintain redundancy, the primary and the alternate LANs in the TRACON each connect to a separate router. The receiving routers are also separate and redundant. The two redundant LANs (primary and alternate) have different subnet addresses. The Ethernet port on each router is assigned an IP address based on the subnet connected to it. It is important the correct routers are connected to each LAN and that the IP address of the routers Ethernet ports be contained in the LAN subnet. The routers at the TRACON/RAPCON end are configured to block any traffic with incorrect subnet addresses. The DASR interface to the existing automation system allows for an interface to an OMT located with the automation system. When the distances between the DASR TRACON/RAPCON equipment and the existing automation system is small, the automation system and OMT can connect to the DASR system over wire or fiber optic connections. Remote connections over Telco are made using routers with one Ethernet and one FT-1 connection.
Table 4. SDT Router IP Address Scheme with Host/Script Names
CISCO SDT Router PN H331078-2 / H409507-1
Equipment LAN Location IP Addr SUBNET Host/Script Name
SDT A Radar Site 10.1.1.88 255.255.255.0 sdt_local_router_a
SDT B Radar Site 10.1.2.88 255.255.255.0 sdt_local_router_b
SDT A Remote Site 10.1.1.89 255.255.255.0 sdt_remote_router_a
SDT B Remote Site 10.1.2.89 255.255.255.0 sdt_remote_router_b
* *
11/17/2016 SSM-ASR11-124 TI 6310.47 WP 004 07
20
SD
Cisco 1720
BRIS/T
CONSOLE
AUXWIC 0 OK
OK
B2
B1
WIC 1 OK
DSUCPU
LNK100FDX
S3
LOOP
LP
SD
Cisco 1720
BRIS/T
CONSOLE
AUXWIC 0 OK
OK
B2
B1
WIC 1 OK
DSUCPU
LNK100FDX
S3
LOOP
LP
SD
Cisco 1720
BRIS/T
CONSOLE
AUXWIC 0 OK
OK
B2
B1
WIC 1 OK
DSUCPU
LNK100FDX
S3
LOOP
LP
SD
Cisco 1720
BRIS/T
CONSOLE
AUXWIC 0 OK
OK
B2
B1
WIC 1 OK
DSUCPU
LNK100FDX
S3
LOOP
LP
Figure 7. SDT Router Configuration Using FT-1 Line
4-3.2.1 Operator Maintenance Terminal (OMT) Interface. The connection to the existing automation system also provides an interface to an Operator Maintenance Terminal (OMT). When the OMT is not located close to the hub or switches on the LANs, the connection to the OMT is through a pair of routers. The OMT routers are different from the SDT routers. The data for the OMTs is not considered mission critical. It is not carried on redundant paths. The data rate for the single OMT link is 56 kbps. One OMT router receives data from both primary and alternate LAN. The router merges the data onto a single 56 kbps serial line. The receiving router receives the data for both LANs on a single serial port. The router forwards the data to the appropriate LAN marker. Table 5 shows the IP addresses and script file names to be used for OMT configurations. The Multi-Site OMTs located in the large TRACONs are handled by a different router configuration covered later in this work package.
Table 5. OMT Router IP Address Scheme with Host/Script Names
CISCO OMT Router, PN G780342-2B / H409507-2B Equipment SITE LAN Location IP Address Host/Script Name
OMT1 1 A/B Radar Site 10.1.1.74/10.1.2.74 omt1_local_router
OMT1 1 A/B Remote Site 10.1.1.75/10.1.2.75 omt1_remote_router
OMT2 1 A/B Radar Site 10.1.1.76/10.1.2.76 omt2_local_router
OMT2 1 A/B Remote Site 10.1.1.77/10.1.2.77 omt2_remote_router
OMT3 1 A/B Radar Site 10.1.1.80/10.1.2.80 omt3_local_router
OMT3 1 A/B Remote Site 10.1.1.81/10.1.2.81 omt3_remote_router
OMT4 1 A/B Radar Site 10.1.1.82/10.1.2.82 omt4_local_router
OMT4 1 A/B Remote Site 10.1.1.83/10.1.2.83 omt4_remote_router
4-3.3 DASR to ARTS IIIE SIU. (Refer to Figure FO-3 sheet 2.) The SIU to ARTS-IIIE Interface provides RADAR data to a TRACON or remote facility via CSU/DSUs. Radar data is converted by the SIU located at the radar facility and is then remoted to the TRACON using modems. The data is then sent through an EIA-530-A/B switch and the selected LAN data is fanned out through two EIA-530 splitters. The interface is capable of providing up to ten outputs. All of the equipment is installed on a Government Furnished Equipment (GFE) rack. Status and Control data will be remotely monitored at the large TRACONs using Multi-site OMTs. MSOMTs will use routers to connect from the radar facility to the TRACON. 4-3.3.1 Multi-site OMT (MsOMT). Multi-Site OMTs are used in large TRACONs where they accept feeds from more than one ASR-11. The MsOMT (figure 4) is an OMT capable of receiving inputs from up to 8 ASR-11 RADAR sites. At the top of the MsOMT screen are icons for each ASR-11 site reporting to the TRACON or remote location.
*
*
11/17/2016 SSM-ASR11-124 TI 6310.47 WP 004 07
22
Figure 9. Multi-Site OMT Main Screen
Multi-Site OMTs are connected to the radar sites by Cisco routers (figure 7). There is a LAN A and LAN B connection for redundancy. All sites are combined at the large TRACON by a LAN A and LAN B Ethernet switch and then routed to the OMTs.
Site Selection ICONS
* *
11/17/2016 SSM-ASR11-124 TI 6310.47 WP 004 07
23
Figure 10. Multi-Site OMT (MsOMT)
Note: OMT-1 is located at a local maintenance facility as determined by radar site personnel. Since several sites connect to the MsOMT, it is placed on a new, separate network (in the 10.240.0.0 space). The MsOMT routers connect each site to the MsOMT network. See Table 4 for IP addresses of the MsOMT Routers.
Table 6. MSOMT Router IP Address Scheme with Host/Script Names
CISCO MSOMT Router PN PDH409507-B Equipment LAN Location IP Address Host/Script Name MSOMT Site 1 A Radar Site 10.1.1.78 msomt_local_1a
MSOMT Site 1 B Radar Site 10.1.2.78 msomt_local_1b
MSOMT Site 1 A Remote Site Large TRACON 10.240.1.78 msomt_remote_1a
MSOMT Site 1 B Remote Site Large TRACON 10.240.2.78 msomt_remote_1b
MSOMT Site 2 A Radar Site 10.1.1.78 msomt_local_2a
MSOMT Site 2 B Radar Site 10.1.2.78 msomt_local_2b
MSOMT Site 2 A Remote Site Large TRACON 10.240.1.79 msomt_remote_2a
*
*
*
*
* *
11/17/2016 SSM-ASR11-124 TI 6310.47 WP 004 07
24
Table 6. MSOMT Router IP Address Scheme with Host/Script Names, Continued
CISCO MSOMT Router PN PDH409507-B
Equipment LAN Location IP Address Host/Script Name
MSOMT Site 2 B Remote Site Large TRACON 10.240.2.79 msomt_remote_2b
MSOMT Site 3 A Radar Site 10.1.1.78 msomt_local_3a
MSOMT Site 3 B Radar Site 10.1.2.78 msomt_local_3b
MSOMT Site 3 A Remote Site Large TRACON 10.240.1.80 msomt_remote_3a
MSOMT Site 3 B Remote Site Large TRACON 10.240.2.80 msomt_remote_3b
MSOMT Site 4 A Radar Site 10.1.1.78 msomt_local_4a
MSOMT Site 4 B Radar Site 10.1.2.78 msomt_local_4b
MSOMT Site 4 A Remote Site Large TRACON 10.240.1.81 msomt_remote_4a
MSOMT Site 4 B Remote Site Large TRACON 10.240.2.81 msomt_remote_4b
An example of a site 1 MsOMT router configuration is shown in figure 11. See FO-3 Sheet 2 in the back of this work package for a more detailed drawing.
SD
Cisco 1720
BRIS/T
CONSOLE
AUXWIC 0 OKO
K
B2
B1
WIC 1 OK
DSUCPU
LNK100FDX
S3
LOOP
LP
SD
Cisco 1720
BRIS/T
CONSOLE
AUXWIC 0 OK
OK
B2
B1
WIC 1 OK
DSUCPU
LNK100FDX
S3
LOOP
LP
SD
Cisco 1720
BRIS/T
CONSOLE
AUXWIC 0 OK
OK
B2
B1
WIC 1 OK
DSUCPU
LNK100FDX
S3
LOOP
LP
SD
Cisco 1720
BRIS/T
CONSOLE
AUXWIC 0 OK
OK
B2
B1
WIC 1 OK
DSUCPU
LNK100FDX
S3
LOOP
LP
Figure 11. MsOMT Site 1 Router Configuration
4-3.3.2 SIU Maintenance Port. The SIU Maintenance port is an optional system that allows for an uninterrupted connection to the DASR RADAR system for the purpose of recording and/or monitoring data using 4:1 splitters. The SIU Maintenance port must be located in the same rack or same location as the SIUs.
*
*
*
*
*
*
* *
11/17/2016 SSM-ASR11-124 TI 6310.47 WP 004 07
25
5. Router Configurations and IP Addressing. 5-1. IP Addressing. When installing the ASR-11, there were several IP addressing schemes used and therefore not all sites are following the standard IP addressing scheme that was established sometime after the first few sites were installed. The standard scheme is as follows:
Table 7. SIU/SDT IP Addressing
It is imperative that site personnel and AJW know their current IP addressing scheme and have this documented in the Facility Reference Data File (FRDF). 5-1.1 Determining your sites IP Addressing scheme
Procedures to identify your site IP Addressing Scheme:
a. Go to either SCDI Terminal.
b. Click on Local Workstation actions. DoD facilities contact your System Administrator for root access.
c. Click On UNIX Admin. Click in new UNIX window.
d. At Login: prompt type ray
SITE UNIT IP ADDRESS
LAN A LAN B 1 SIU 1 10.1.1.32 10.1.2.32
2 SDT 1 10.1.1.33 10.1.2.33
10.1.1.49 10.1.2.49
3 SIU 2 10.1.1.34 10.1.2.34
4 SDT 2 10.1.1.35 10.1.2.35
10.1.1.51 10.1.2.51
5 SIU 3 10.1.1.36 10.1.2.36
6 SDT 3 10.1.1.37 10.1.2.37
10.1.1.53 10.1.2.53
7 SIU 4 10.1.1.38 10.1.2.38
8 SDT 4 10.1.1.39 10.1.2.39
10.1.1.55 10.1.2.55
9 SIU 5 10.1.1.40 10.1.2.40
10 SDT 5 10.1.1.41 10.1.2.41
10.1.1.57 10.1.2.57
11 SIU 6 10.1.1.42 10.1.2.42
12 SDT 6 10.1.1.43 10.1.2.43
10.1.1.59 10.1.2.59
13 SIU 7 10.1.1.44 10.1.2.44
14 SDT 7 10.1.1.45 10.1.2.45
10.1.1.61 10.1.2.61
15 SIU 8 10.1.1.46 10.1.2.46
16 SDT 8 10.1.1.47 10.1.2.47
10.1.1.63 10.1.2.63
**
11/17/2016 SSM-ASR11-124 TI 6310.47 WP 004 07
26
e. At Password prompt type ray.
f. # prompt should appear, type autosu.
g. Expand the window to fill the screen (Click in the lower right corner and drag)
h. Left click the mouse in the window.
i. Type tcpdump –t -q –i eth3 port 3200
Note: eth3 is LAN A, port 3200 is status messages
j. You should see a screen similar to the one in figure 12.
Figure 12. Tcpdump Command Results LAN A
*
*
*
11/17/2016 SSM-ASR11-124 TI 6310.47 WP 004 07
27
k. Allow the tcpdump command to run until the window is full then press Ctrl+C to stop.
l. Determine and record the results for connected SIUs and SDTs in your sites FRDF for future reference.
In this case, you would fill in the IP Addresses for LAN A:
SIU-A 10.1.1.32 SDT-A LAN A 10.1.1.33 SDT-B LAN A 10.1.1.34
m. In the window type tcpdump –t –q –i eth4 port 3200
Note: eth4 is LAN B, port 3200 is status messages
n. You should see a screen similar to below:
Figure 13. Tcpdump Command Results LAN B o. Allow the snoop command to run until the window is full then press Ctrl+C to stop.
p. Record the results with your sites FRD. For figure 12, the following IP Addresses would be recorded for LAN B
SIU-B 10.1.2.32 SDT-A LAN B 10.1.2.33 SDT-B LAN B 10.1.2.34
*
*
*
11/17/2016 SSM-ASR11-124 TI 6310.47 WP 004 07
28
:
11/17/2016 SSM-ASR11-124 TI 6310.47 WP 004 07
29
5-2 Determining your site’s Router Configuration (If Needed)
Not all sites will use Cisco routers. Use this procedure to determine the script files your site uses for each router. If Cisco routers are used at your facility, locate all Cisco routers. There may be several models such as 1605, 1721, 2811. This procedure will work on all models. Go to each router and perform the following:
a. Using the light blue serial cable supplied with the router, connect a PC that has
HyperTerminal capabilities to the Console port of the router.
b. At the PC click on START
c. Click on All Programs
d. Click on Accessories
e. Click on Communications
f. Click on HyperTerminal icon
g. Click on File
h. Click on New Connection
i. Type in “ROUTER” for Name and click “OK”
j. Select “Comm 1” under the “Connect using:” option
k. Click OK
l. In the Port Settings Menu Enter:
m. Bits per second: 9600
n. Data bits: 8
o. Parity: None
p. Stop bits: 1
q. Flow control: None
r. Click OK
s. Hit the enter key.
t. A screen similar to the one in figure 14 should appear
The prompt displayed in the Hyper Terminal box will tell you the script that was loaded into this router. In this example:
sdt_remote_router_b
*
*
*
*
* *
11/17/2016 SSM-ASR11-124 TI 6310.47 WP 004 07
30
Figure 14. Hyper Terminal Screen
From this you can determine:
This router is used for SDT communications This router is located at the remote site This router is used on LAN B
u. Make a label that says “sdt_remote_router_b” and affix to the router in an obvious location. This information will be needed should you have to replace the router.
v. Close the hyperterminal application.
w. Repeat this procedure for each router at your facility.
11/17/2016 SSM-ASR11-124 TI 6310.47
WP 004 07
31
6. Remove and Replace Procedures 6.1 Remove and Replace Routers.
Note: Although extremely remote, there is a possibility of taking the radar out of service when you connect an Ethernet cable into the offsite LAN. Coordination with Air Traffic Control is essential. Advise them that you will be connecting 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.
Note: Router failures are commonly attributed to the WAN Interface Cards (WIC) cards. Site configuration will determine which WIC card(s) are installed at the facility. These cards are available through the Depot.
1. Ethernet 51/A1/A2 WIC 1 for OMT (1721 Only) 2. 56kDDS 51/A1/A1 WIC 0 for OMT/MsOMT 3. T1 51/A2/A1 WIC 0 for SDT
Procedures to remove and replace WIC cards are contained in paragraph 6.1.2.
Before proceeding you need to know the routers Host/Script name for the router you are replacing. This should be recorded in the site’s FRDF. It is best to determine your router configuration when everything is operating normal. See para 5.2 for procedures to determine current script file names.
For sites that require custom router scripts, procedure 6.1.1 should be performed to load the custom scripts onto the router.
If the current router configuration is not known, use the tables and figures located in para 4 of this work package to determine the correct script name and IP address. There are three separate tables used for three different router configurations. Be sure to use the correct table for your configuration.
SDT Routers
Use Table 4 for Script Name.
See Figure 7 for overview.
OMT Routers
Use Table 5 for Script Name.
See Figure 8 for overview.
MSOMT Routers
Use Table 6 for Script Name.
See Figure 10 for overview.
This procedure will apply to all router configurations (OMT, SDT, MsOMT). You must know the Script name before proceeding. See the appropriate table to obtain the correct script name.
*
WIC 0 WIC 1
Ethernet 10/100
ROUTER
*
*
*
*
**
*
11/17/2016 SSM-ASR11-124 TI 6310.47
WP 004 07
32
a. Power off old router and remove all cables.
b. Remove old router.
c. Install new router and secure in the same location
d. Connect only the power cord to the router and turn power ON.
e. Connect the light blue cable provided with the router to the CONSOLE PORT of the router and 9 pin serial port of the PC.
f. Establish a Hyperterminal session. Connect using COM1, 9600 bps, 8 data bits, no parity, 1 stop bit, and no flow control for settings. (If using a serial to USB converter the COM port may differ.)
g. Once the router has finished booting, it will prompt the user to press ENTER to begin. Press ENTER and the default prompt default_filename> should appear. Refer to figure 14.
h. Type enable.
i. When prompted for password type dasr. The prompt will change to default_filename#.
j. Type show flash to display all of the script files loaded into this router. It should match one of the tables located in paragraph 4 of this Work Package.
k. Type copy flash:script_filename startup. Substitute the script filename obtained in one of the tables.
l. Router will respond with Destination filename [startup-config]?. Hit ENTER.
m. Router will respond with a prompt default_filename# after several seconds.
n. Type reload.
o. Router responds with Proceed with Reload? [confirm]
p. Press ENTER. Router will restart.
q. Once router reloads, the new prompt should read script_filename>.
r. Once the configuration has been completed, remove the light blue serial cable.
s. Turn the router OFF and reconnect all remaining data cables.
t. Turn Power ON.
*
*
32
6.1.1 Load Site Specific Cisco Router Scripts.
This procedure is to be performed only when your site requires a custom router script to be loaded onto the router. Most sites will function properly with the default router scripts, which are pre-loaded from the Depot. Your site’s FRDF should document if a site specific router script is required.
If a site specific script is required, it should be archived on CD-ROM media. Locate the CD before starting this procedure.
a. Disconnect all cables from the router except the power cord.
b. Power on the router.
c. Configure the PC’s IP Address to be 10.1.1.100 subnet 255.255.255.0
d. Load the CD-ROM with site specific router files into the PC.
e. Copy the site specific router files from the CD-ROM to the Cisco TFTP Server root folder (typically C:\Program Files\Cisco Systems\Cisco TFTP Server).
f. Remove the CD-ROM from the PC.
g. Disable the PC’s Windows Firewall.
h. Connect the light blue cable provided with the router to the CONSOLE PORT of the router and 9 pin serial port of the PC (use a serial to USB converter if the PC does not have a serial port).
i. Connect a crossover Ethernet cable between the Ethernet 0 interface on the router and the PC.
j. Start Cisco TFTP Server on the PC. Ensure the IP address of 10.1.1.100 appears in the title bar of the program.
k. Establish a Hyperterminal session. Connect using COM1, 9600 bps, 8 data bits, no parity, 1 stop bit, and no flow control for settings. (If using a serial to USB converter the COM port may differ)
l. Once the router has finished booting, it will prompt the user to press ENTER to begin. Press ENTER and the default prompt default_filename> should appear. Refer to figure 14.
m. Issue the following commands in HyperTerminal (the router name in the prompt may differ from what you see):
[Return] (to view banner message and obtain the prompt)
default_filename> en
Password: dasr
default_filename# show run*
*
32A
n. Identify the name of the first Ethernet interface. It will be Ethernet0 for 1605, FastEthernet0 for 1721, FastEthernet0/0 for 2811. You may need to press space to cycle through the entire listing.
o. Look for the Ethernet0 or FastEthernet0 interface characteristics. Identify bridge-group input patterns or access-groups and their number identifiers. Press the space bar until the list ends. Example:
interface FastEthernet0 ip address 10.1.1.88 255.255.255.0 no ip route-cache speed 10 half-duplex priority-group 1 bridge-group 1 bridge-group 1 input-pattern-list 1100 ip access-group 101 in ip access-group 101 out
p. Temporarily disable these input patterns or access-groups (example for access-group 101 and bridge-group 1100 shown, you will want to disable all present. Note that access-groups and bridge-groups are disabled with the similar access-list command).
default_filename# conf t
default_filename(config)# no access-list 101
default_filename(config)# no access-list 1100
default_filename(config)# exit
q. Assign the first Ethernet interface IP Address.
default_filename# conf t
default_filename(config)# interface FastEthernet0/0 (Ethernet0 for 1605, FastEthernet0 for 1721, FastEthernet0/0 for 2811)
default_filename(config-if)# ip address 10.1.1.1 255.255.255.0
default_filename(config-if)# exit
default_filename(config)# exit
default_filename# ping 10.1.1.100
r. Only proceed if the ping command succeeds at least once out of five attempts. If ping fails all attempts then troubleshoot the Ethernet connection until ping works.
s. Copy the file from the laptop to the router
default_filename# copy tftp flash
Address of remote host [255.255.255.255]? 10.1.1.100
Answer “n” to erasing the flash. Note: If you erase the flash you will need to order a new router.
t. The router should return the byte count and the time required for the transfer; this indicates it was successful. Do not proceed until the file transfer is successful.
u. Copy the new configuration file to the startup configuration:
w. When it comes back online press Enter to display the banner. Ensure the banner message and the prompt indicate the desired script file was loaded.
x. Power off the router.
y. Disconnect Ethernet and Console cables from router and PC.
z. Install data cables to the router.
aa. Power on the router.
6.1.2 Remove and Replace Cisco Router WIC Cards.
Note: Although extremely remote, there is a possibility of taking the radar out of service when you connect an Ethernet cable into the offsite LAN. Coordination with Air Traffic Control is essential. Advise them that you will be connecting 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.
This procedure will apply to all router configurations (OMT, SDT, MSOMT). The three WIC cards currently in use are:
1. Ethernet 51/A1/A2 WIC 1 for OMT (1721 Only)
2. 56kDDS 51/A1/A1 WIC 0 for OMT/MSOMT
3. T1 51/A2/A1 WIC 0 for SDT
a. On back of Router, shut off power.
b. Disconnect any cables connected to the WIC card.
c. Loosen the two screws that secure the WIC card.
d. Remove the WIC card from the slot.
e. Insert new WIC card into blank slot and insert cables into appropriate slots
f. Power up router and wait for reboot to complete (“WIC 0 OK” led lit). The OK LED on the front of the router will flash while the router is rebooting. This may take several minutes.
WIC 0 WIC 1
Ethernet 10/100
ROUTER
*
*
**
* *
09/11/2007 SDR-ASR11-009 TI 6310.47 WP 004 07
33
6.2 Remove and Replace the DA56 DSU/CSU.
The DA56 DSU/CSU is configured for DASR through seven of the 11 switches on the rear of the unit. The other four switches are for diagnostics. The switches should be configured as illustrated below.
Figure 16. DA56 Switch Settings
*
*
09/11/2007 SDR-ASR11-009 TI 6310.47 WP 004 07
34
6.3 Remove and Replace Motorola MR64 6.3.1 Remove and Replace Motorola MR64 with External clocks used with DDS lines as referenced in your sites FRDF The MR64 is required to remote ASR-11 data to the TRACON location. The following procedure describes removing and replacing the MR64 Modem (SIU CSU/DSU).
Figure 17. MR64 Modem
a. Remove AC power from unit.
b. Ensure identification of cables.
c. Remove cables from unit.
d. Install unit into communication rack.
e. Apply power to modem.
*
*
09/11/2007 SDR-ASR11-009 TI 6310.47 WP 004 07
35
f. Press Home key. Load factory defaults by proceeding through Table 8.
NOTE: In order to configure the MR64 Modem, you must have factory defaults loaded as a starting point. Load factory defaults by answering the questions in Table 8. When you have completed Table 8 you will proceed to Table 9. Depending on the Modem's current configuration, some of these configuration questions may not appear.
Configuration Question
User Response
Select test? No
Sync DTE Change? No
Rate Adapter Disabled-Change No
Change Timing? DDS No
Change Line Rate? 56K BPS Line
No
Change Control Options? Yes
Change RTS Control? No
Change Sync Buffer Opt? No
Change Remote LB Opt? Yes
RMT LB Enabled Change? Yes
RMT LB Disabled Change? No
Change DSR Opt? No
Change Sys Status Opt? No
Change CA Option? No
Change RTS-CTS Delay? Yes
DLY CTS 30 mSec Change? Yes
DLY CTS 60 mSec Change? Yes
RTS-CTS Normal Change? No
Change DTE RL Opt? No
Change DTE LL Opt? No
Change DTE TP Opt? No
Change DTE RT Opt? No
Change 64k Scram Opt? No
Load Factory Option Set? Yes
Table 8. MR64 DASR Modem First Run Through Table, Setting Factory Defaults
*
*
09/11/2007 SDR-ASR11-009 TI 6310.47 WP 004 07
36
g. Press Home key. Load site specific settings by proceeding through Table 9. Answer all questions as shown below.
Configuration
Question User Response
Select test? No
Sync DTE Change? No
Rate Adapter Disabled-Change No
Change Timing? DDS No
Change Line Rate? 56K BPS Line
No
Change Control Options? Yes
Change RTS Control? No
Change Sync Buffer Opt? No
Change Remote LB Opt? Yes
RMT LB Enabled Change? Yes
RMT LB Disabled Change? No
Change DSR Opt? No
Change Sys Status Opt? No
Change CA Option? No
Change RTS-CTS Delay? Yes
DLY CTS 30 mSec Change? Yes
DLY CTS 60 mSec Change? Yes
RTS-CTS Normal Change? No
Change DTE RL Opt? No
Change DTE LL Opt? No
Change DTE TP Opt? No
Change DTE RT Opt? No
Change 64k Scram Opt? No
Load Factory Option Set? No
Save New Configuration? Yes
Table 9. MR64 DASR Modem Second Run through Table
*
*
09/11/2007 SDR-ASR11-009 TI 6310.47 WP 004 07
37
6.3.2 Remove and Replace remote site Motorola MR64 with Internal clocks (No telco) The MR64 is required to remote ASR-11 data to the TRACON location. The following procedure describes removing and replacing the MR64 Modem (SIU CSU/DSU) when dedicated copper is used between facilities and the modems must provide their own clock. Only the remote modem should be set up according to these procedures. The local modem should use paragraph 6.3.1 for its setup.
Figure 18. MR64 Modem
a. Remove AC power from unit.
b. Ensure identification of cables.
c. Remove cables from unit.
d. On New Unit, Remove Cover
Place the unit on its side on a flat surface.
Using a flat blade screwdriver, insert into slot while twisting lightly back and forth.
*
*
09/11/2007 SDR-ASR11-009 TI 6310.47 WP 004 07
38
Assist removal by prying the cover from the chassis with your fingers on the units rear edge.
Repeat this procedure on the remaining three latch slots to remove the cover.
Figure 19. MR64 Cover Removed
e. Set the four position dip switch to the following configuration to set Source Sealing Current:
f. Put both V.35/RS232 switches to the RS232 position. All other switches and jumpers should match figure 16.
g. Replace cover on MR64.
h. Install new unit into communication rack.
i. Apply power to modem. Verify during bootup that screen displays
DDS/MR64 INTERFACE=RS232
*
*
09/11/2007 SDR-ASR11-009 TI 6310.47 WP 004 07
39
j. Press Home key. Load factory defaults by proceeding through Table 10.
NOTE: In order to configure the MR64 Modem, you must have factory defaults loaded as a starting point. Load factory defaults by answering the questions in Table 10. When you have completed Table 10 you will proceed to Table 11. Depending on the Modem's current configuration, some of these configuration questions may not appear.
Configuration Question
User Response
Select test? No
Sync DTE Change? No
Rate Adapter Disabled-Change No
Change Timing? DDS No
Change Line Rate? 56K BPS Line
No
Change Control Options? Yes
Change RTS Control? No
Change Sync Buffer Opt? No
Change Remote LB Opt? Yes
RMT LB Enabled Change? Yes
RMT LB Disabled Change? No
Change DSR Opt? No
Change Sys Status Opt? No
Change CA Option? No
Change RTS-CTS Delay? Yes
DLY CTS 30 mSec Change? Yes
DLY CTS 60 mSec Change? Yes
RTS-CTS Normal Change? No
Change DTE RL Opt? No
Change DTE LL Opt? No
Change DTE TP Opt? No
Change DTE RT Opt? No
Change 64k Scram Opt? No
Load Factory Option Set? Yes
Table 10. MR64 DASR Modem First Run through Table, Setting Factory Defaults
*
*
09/11/2007 SDR-ASR11-009 TI 6310.47 WP 004 07
40
k. Press Home key. Load site specific settings by proceeding through Table 11. Answer all questions as shown below.
NOTE: Use this table only for the rehost remote Modem. Only One Modem can be set to internal clocks. If you are replacing the local rehost Modem, use Table 11.
Configuration Question User Response
Select test? No
Sync DTE Change? No
Rate Adapter Disabled-Change No
Change Timing? DDS Yes
CHANGE TO INT? Yes
Change Line Rate? 56K BPS Line
No
Change Control Options? Yes
Change RTS Control? No
Change Sync Buffer Opt? No
Change Remote LB Opt? Yes
RMT LB Enabled Change? Yes
RMT LB Disabled Change? No
Change DSR Opt? No
Change Sys Status Opt? No
Change CA Option? No
Change RTS-CTS Delay? Yes
DLY CTS 30 mSec Change? Yes
DLY CTS 60 mSec Change? Yes
RTS-CTS Normal Change? No
Change DTE RL Opt? No
Change DTE LL Opt? No
Change DTE TP Opt? No
Change DTE RT Opt? No
Change 64k Scram Opt? No
Load Factory Option Set? No
Save New Configuration? Yes
Table 11. MR64 DASR Modem Second Run through Table Sets Internal Clock
FOR REMOTE MODEM ONLY
*
*
XX/XX/XXXX SDR-ASR11-057 TI 6310.47 WP 004 07
41
6.4 Remove and Replace Remote Offsite LAN Ethernet Switches.
6.4.1 Remove and Replace Omnitron LAN Ethernet Switches.
NOTE: Although extremely remote, there is a possibility of taking the radar out of service when you connect an Ethernet cable into the offsite LAN. Coordination with Air Traffic Control is essential. Advise them that you will be connecting 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.
The following procedure describes removing and replacing the Offsite LAN Ethernet Switches at the TRACON/RAPCON.
CAUTION: Observe Precautions For Handling ESD Sensitive Items to Prevent Damage To Components.
a. Power off Ethernet Switch by removing AC power plug from switch.
b. Ensure cables are all labeled and identifiable.
c. Remove cables from Ethernet ports and fiber optic ports, if applicable.
d. Remove screws securing the Ethernet Switch to rack.
e. Remove Ethernet Switch and place in ESD-safe location.
f. Obtain the replacement switch and remove from packaging.
g. Install appropriate rack mounting hardware on switch.
h. Configuration before hardware installation
Ports 1 thru 4 settings via dip switches on rear of unit
Manual operation 10 Base-T
Half duplex operation
i. Place new Ethernet Switch onto rack.
j. Secure the Ethernet Switch with screws.
k. Install cables from Ethernet ports and fiber optic ports, if applicable.
l. Set Port 1 Control Switch on front of unit
Out position (not cross connected) Push in, if needed, to change setting from in to the out position
Set Fiber optic port on front of unit to full duplex position.
m. Power up Ethernet Switch by inserting AC power plug into switch.
n. Configure ports 5 - xx via computer if needed.
*
*
* *
XX/XX/XXXX SDR-ASR11-057 TI 6310.47 WP 004 07
42
(1) Use the DB-9 serial interface located on the rear of the switch. Attach a DB-9 serial cable to the switch and connect to the weather laptop
(2) Press the enter key after the connection has been established and the main menu will appear on the screen with several options
(3) Select Display port mode configuration option to view settings
(4) Follow the on screen instructions to make the desired changes if needed
10 Base-T Half duplex operation
(5) To exit the main menu, disconnect the serial cable
Note: All changes made through the serial interface will affect the unit immediately and will remain in effect until changed again through the serial interface or via manual switches.
If the power is turned off at the switch the current port setting will be restored when the power is turned back on.
Any changes made through the serial interface for ports 1 through 4 will override the switch setting for that port until the port is configured manually again.
o. Verify 10 Base-T/Half duplex settings are implemented correctly
Top LED
Green / ON 100Base-Tx (Fast Ethernet) device detected Green / Flash Data activity present Yellow / ON 10Base-T (standard Ethernet) device detected Yellow / Flash Data activity present
OFF No connection
Bottom LED
Green / ON Full-Duplex OFF Half-Duplex Flash Collisions
6.4.2 Remove and Replace Milan LAN Ethernet Switches.
24 Port MiLAN Switch Equipment Set-Up:
NOTE: Although extremely remote, there is a possibility of taking the radar out of service when you connect an Ethernet cable into the offsite LAN. Coordination with Air Traffic Control is essential. Advise them that you will be connecting 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.
*
*
*
*
XX/XX/XXXX SDR-ASR11-057 TI 6310.47 WP 004 07
42A
The following procedure describes removing and replacing the Offsite LAN Ethernet Switches at the TRACON/RAPCON
CAUTION: Observe precautions for handling ESD sensitive items to prevent damage to components.
a. Power off Ethernet Switch by removing AC power plug from switch.
b. Ensure cables are all labeled and identifiable.
c. Remove cables from Ethernet ports and fiber optic ports, if applicable.
d. Remove screws securing the Ethernet Switch to rack.
e. Remove Ethernet Switch and place in ESD-safe location.
f. Obtain the replacement switch and remove from packaging.
g. If this assembly is to be configured to be H409508-2 or H409508-3, Fiber Optic Transceiver, remove metal plate attached to the right front of the switch, then install the Dual Fiber Module.
h. Attach the rack mount brackets.
i. Attach AC power (at the rear panel) to MIL-SM2401-STK switch.
j. Connect the MIL-SM2401-STK to the Wx Laptop as shown by figure 20. The Wx Laptop may need a Serial-to-USB adapter.
Figure 20. Connection Diagram
*
*
XX/XX/XXXX SDR-ASR11-057 TI 6310.47 WP 004 07
6-42B
k. Find the COM port used by the PC.
(1) Right Click <My Computer> <Manage>.
(2) Click on “Device Manager”.
(3) Scroll and expand “Ports (COM & LPT)”.
(4) Choose the appropriate COM port for the Serial on USB Port (see Figure 21).
Write the COM port here _____________
XX/XX/XXXX SDR-ASR11-057 TI 6310.47 WP 004 07
43
Figure 21. Device Manager Window (This PC uses a Serial-to-USB converter so COM4 is chosen.)
(2) If prompted, click “Cancel” for a new connection name.
(3) In the HyperTerminal menu click <File> <Properties>.
(4) Select the appropriate COM port in the “Connect using:” dropdown.
(5) Click “Configure”.
(6) Settings are as follows:
9600 Bits per second 8 Data bits, None Parity 1 Stop bits None Flow Control
(7) Click OK twice to return to HyperTerminal window.
*
*
XX/XX/XXXX SDR-ASR11-057 TI 6310.47 WP 004 07
44
(8) Click <Call> <Call> in the menu.
(9) If prompted, enter “MILAN Switch” in the new connection name.
(10) Click in the white space and hit <Enter> to bring up the login screen (Figure 22)
Figure 22. Login Screen
m. User Name is root. Password is root.
n. Type at the prompt: switch> menu.
o. Use the arrow keys to select Switch Configuration.
p. Select Port Configuration.
q. Select <Edit>.
r. Use the arrow keys and the space bar to change the settings for port 01-08 to mirror Figure 23.
State = Enable Negotiation = Force Speed Duplex = 10 Half FC = OFF BP = OFF Bandwidth In = 0
XX/XX/XXXX SDR-ASR11-057 TI 6310.47 WP 004 07
45
Bandwidth Out = 0 Priority = Disable Security = OFF
Figure 23. Settings for Ports 01-24
s. Press the Escape key.
t. Select <Next Page>.
u. Select <Edit>. Change the port settings for 09-16 to match 01-08.
v. Press the Escape key.
w. Select <Next Page>.
x. Select <Edit>. Change the port settings for 17-24 to match 01-08.
y. Press the Escape key.
z. Select <Next Page>.
aa. Select <Edit>.
bb. Change the settings for port 25-26 to mirror Figure 24.
XX/XX/XXXX SDR-ASR11-057 TI 6310.47 WP 004 07
46
State = Enable Negotiation = Force Speed Duplex = 100 Full FC = ON BP = OFF Bandwidth In = 0 Bandwidth Out = 0 Priority = Disable Security = OFF
Figure 24. Settings for Ports 25-26
cc. Press the Escape key.
dd. Select <Apply>.
ee. Hit any key after the settings are applied successfully to return to the configuration menu.
ff. Select Port Mirroring Configuration.
gg. Select <Edit>.
hh. Use the arrow keys to navigate and the space key to toggle settings. Make the screen look like Figure 25.
Mirroring State = Both Analysis Port = Port.24 Asterisks on every port except Port.24
XX/XX/XXXX SDR-ASR11-057 TI 6310.47 WP 004 07
47
Figure 25. Settings for Port Mirroring
ii. Press the Escape key.
jj. Select <Apply>.
kk. Hit any key after the settings are applied successfully to return to the configuration menu.
ll. Select Main Menu.
mm. Select Save Configuration.
nn. Type y to continue.
oo. Select Logout.
pp. Close all windows on PC. Disconnect serial cable from MIL-SM2401-STK switch.
XX/XX/XXXX SDR-ASR11-057 TI 6310.47 WP 004 07
48
Procedures for 24 Port Milan MIL-SM24T4DPA Switch Set-Up:
NOTE: Although extremely remote, there is a possibility of taking the radar out of service when you connect an Ethernet cable into the offsite LAN. Coordination with Air Traffic Control is essential. Advise them that you will be connecting 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. The following procedure describes removing and replacing the Offsite LAN Ethernet Switches at the TRACON/RAPCON
CAUTION: Observe precautions for handling ESD sensitive items to prevent damage to components.
a. Power off Ethernet Switch by removing AC power plug from switch.
b. Ensure cables are all labeled and identifiable.
c. Remove cables from Ethernet ports and fiber optic ports, if applicable.
d. Remove screws securing the Ethernet Switch to rack.
e. Remove Ethernet Switch and place in Electrostatic Discharge (ESD)-safe location.
f. Obtain the replacement switch and remove from packaging.
g. If this assembly is to be configured for fiber, insert module and cables per figure 33.
h. Attach the rack mount brackets.
i. Attach AC power (at the rear panel) to MIL-SM24T4DPA switch.
j. Connect the MIL-SM24T4DPA to the Wx Laptop as shown by Figure 26. The Wx Laptop may need a Serial-to-USB adapter.
Figure 26. – Connection Diagram
*
*
XX/XX/XXXX SDR-ASR11-057 TI 6310.47 WP 004 07
49
k. Find the COM port used by the PC using the following procedure:
(1) Right Click <My Computer> <Manage>.
(2) Click on Device Manager.
(3) Scroll and expand Ports (COM & LPT).
(4) Choose the appropriate COM port for the Serial on USB Port (see Figure 27).
Write the COM port here _____________
Figure 27. – Device Manager Window
(This PC uses a Serial-to-USB converter so COM4 is chosen.)
(2) If prompted, click Cancel for a new connection name.
(3) In the HyperTerminal menu click <File> <Properties>.
(4) Select the appropriate COM port in the Connect using dropdown menu.
(5) Click Configure.
(6) Settings are 115200 Bits per second, 8 Data bits, None Parity, 1 Stop bits, None Flow Control. Click “OK” twice to return to HyperTerminal window, Figure 28.
* *
XX/XX/XXXX SDR-ASR11-057 TI 6310.47 WP 004 07
50
Figure 28. HyperTerminal Properties Setup
m. Log in (see figure 29):
User Name admin. Password. N/A
n. Click enter.
Figure 29. Login Screen
o. The Main Screen will appear. See figure 30. *
*
*
*
XX/XX/XXXX SDR-ASR11-057 TI 6310.47 WP 004 07
51
p. Type port at the > Prompt.
q. Type c at the Port> prompt to display current port configuration, Figure 31.
r. Ports 1-24 should be Mode 10hdx, Flow Control Enabled.
s. Ports 25-28 should be Mode Auto. These are the fiber optic ports.
Figure 30. Main Screen
Figure 31. Port Configurations
*
*
XX/XX/XXXX SDR-ASR11-057 TI 6310.47 WP 004 07
52
t. Use the following directions to change port mode settings if needed:
(1) Type at the prompt Port> Mode 1-24 10hdx to change the ports to 10Mb Half Duplex.
(2) Type at the prompt Port> Mode <port number> 100fdx to change a port to 100Mb Full Duplex for special configuration setups that require 100Mb interface.
(3) Type at the prompt Port> Mode 25-28 Auto to change the fiber ports to Auto configuration.
u. To Change Flow Control Settings if needed:
(1) Type at the prompt Port> Flow C all e to change Flow Control for all ports to Enabled.
(2) Type at the prompt Port> c to display current port configuration, the screen will resemble Figure 31.
v. Type backslash (/) at the Port>prompt to go back to the root prompt.
w. Unplug the serial cable from the console port.
x. Connect all Ethernet and fiber cables. For switches that use the fiber option, you must have a fiber adaptor module and cable that will plug into port 25, figure 32.
Figure 32. – Fiber Connections
y. Close all windows on PC. Disconnect serial port adapter from PC.
*
*
*
XX/XX/XXXX SDR-ASR11-057 TI 6310.47 WP 004 07
52A
6.4.3 Replace Black Box LAN Ethernet Switches.
24 Port Black Box LGB1126A Switch Equipment Set-Up:
Note: The switch will come pre-configured from the Depot. These procedures are only necessary if you need to verify the switch’s configuration.
a. If this assembly is to be configured to be H469469-2B, install fiber module into SFP port 25 or 26.
b. Connect a straight Ethernet cable between the LGB1126A switch and the Wx Laptop. Use any Ethernet port.
c. Set the Laptop’s IP address to 192.168.1.100 with a subnet of 255.255.255.0.
d. Open an internet browser and point to 192.168.1.1
e. Log into the switch (default username is “admin”, with no password configured).
Note: It may take multiple attempts with correct credentials to get in. Just keep trying, or refresh the page and try again.
f. On the left tree menu, select Configuration > Port > Configuration
g. Configure the port speed and duplex selecting the following settings.
ports 1-24, Speed = 10Mbps HDX ports 25-26, Speed = Auto all ports, No Flow Control, Max Frame = 9600, Collision = Discard, Power =
Disabled
h. Click Apply at the bottom of the page.
i. Allow the page to refresh (link on laptop may need to reconnect).
j. On the left tree menu, select Maintenance > Save/Restore > Save Start.
k. Click the Save button.
l. Close browser and disconnect laptop.
6.4.4 Replace MOXA LAN Ethernet Switches.
18 Port MOXA IKS-6726A Switch Equipment Set-Up:
Note: The switch will come pre-configured from the Depot. These procedures are only necessary if you need to verify the switch’s configuration.
Note: Copper ports G1 and G2 have shared resources with fiber ports G1 and G2. It is recommended to not use copper ports G1 and G2 for this reason.
a. If this assembly is to be configured to be H469469-2M or H469469-3M, install fiber module into SFP port G2 or G1 (G1 is upside down).
*
*
XX/XX/XXXX SDR-ASR11-057 TI 6310.47 WP 004 07
52B
b. Connect a straight Ethernet cable between the IKS-6726A switch and the Wx Laptop.
Use any Ethernet port.
c. Connect AC power to switch.
d. Set the Laptop’s IP address to 192.168.127.100 with a subnet of 255.255.255.0.
e. Open an internet browser and point to 192.168.127.253.
f. Log into the switch (default username is “admin”, password “moxa”).
Note: Switch will pop-up a window advising to change the default password. Click OK. The default password is the desired configuration.
g. On the left tree menu, select Port > Port Settings.
h. Configure the port speed and duplex selecting the following settings.
ports 1-1 to 1-8, Speed = 10M-Half ports 2-1 to 2-8, Speed = 10M-Half change no other settings
i. Click Apply at the bottom of the page.
j. Allow the page to refresh (link on laptop may need to reconnect).
Note: The switch automatically saves the configuration and will remember through power cycles.
k. On the left tree menu, select Port > Port Status. Verify the page loads.
l. Disconnect the laptop.
6.5 Remove and Replace Local Offsite LAN Ethernet Switch. WARNING: Although extremely remote, there is a possibility of taking the radar out of service when you connect an Ethernet cable into the offsite LAN. Coordination with Air Traffic Control is essential. Advise them that you will be connecting 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.
The following procedure describes removing and replacing the 4-port Omnitron LAN Ethernet Switch or the iConverter switch located in the Common Equipment Cabinet (CEC).
CAUTION: Observe precautions for handling ESD sensitive items to prevent damage to components.
a. Power off Ethernet Switch by removing AC power plug from switch.
b. Ensure cables are all labeled and identifiable.
c. Remove cables from Ethernet ports and fiber optic ports, if applicable.
*
*
53
d. Remove velcro straps securing Ethernet Switch to shelf and place in ESD-safe location.
e. Obtain replacement switch and remove from packaging.
6.5.1 FOR OMNITRON SWITCH:
a. Set each port 1 thru 4 (via dip switches on side of unit) to operate in manual operation, at 10 Base-T, and half duplex operation (refer to Omnitron Flexswitch 600XC User’s Manual for procedure). Fiber optic port stays in full duplex position.
b. Push in and release Cross-Connect Switch to out position (not cross-connected).
c. Mount Ethernet Switch with Velcro straps back on to shelf in CEC cabinet.
d. Install cables from Ethernet ports and fiber optic ports, if applicable.
e. Power up Ethernet Switch by inserting AC power plug into switch.
f. Verify 10 Base-T/Half duplex settings are implemented by confirming Ethernet activity lights are Amber. Green lights indicate 100 Base-T setting which is not desired.
6.5.2 FOR iConverter Fiber Module:
a. On the iConverter Fiber Optic Module, set the Front Panel switches as shown in Figure 33.
b. Remove the Fiber module from the assembly and set the switches on the circuit board as shown in Figure 33.
Figure 33. iConverter Fiber Module with iConverter 4Tx Switch
*
*
54
Note: Use only ports A, B and C because they are manually configured. Ports D & E are auto configure and should not be used.
Circuit Board:
Front Panel:
OUT
X II
IN OU
T
FD
X
FD
X
AN
100
10Man
HD
X
HD
X
LP BP
OE
N
RF
D
1 2 3 4
Switch PositionIn or Out
DOWN
UP
Figure 34. Switch Settings for the iConverter Fiber Module
c. Re-install the Fiber module in the assembly.
d. Proceed to iConverter 4 Tx instructions for proper setup.
Denotes Position of Tab
08/06/2014 SDR-ASR11-048 TI 6310.47 WP 004 07
55
6.5.3 FOR iConverter 4 Tx Module:
a. Remove 4 Port Module.
b. Set the S1 switches on the module as shown in Figure 35.
Figure 35. S1 Switch Settings for the 4 Port 100/10 Module
c. Set switch S3 to the “Workstation” position.
d. Re-install the module in the assembly.
e. Connect Ethernet cables and apply power to cable to switch.
6.6 REMOVE AND REPLACE DL-64
a. Disconnect power cord from DL-64.
b. Remove V.35 cable from back of unit.
Denotes Position of Tab
8
1
S
Front Plate
2
3
5
4
6
7
HD
HD
10
10
MAN
MAN
BP B
BP A
FD
10
AN
FD
10
AN
---
---
P
P
08/06/2014 SDR-ASR11-048 TI 6310.47 WP 004 07
56
c. Place DL-64 on rack
d. Connect V.35 cable.
e. Connect power cord.
f. DL-64 is now ready.
6.7 REMOVE AND REPLACE SPLITTER
WARNING: Although extremely remote, there is a possibility of taking the radar out of service when you connect an Ethernet cable into the offsite LAN. Coordination with Air Traffic Control is essential. Advise them that you will be connecting 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. Disconnect power cord from the splitter.
b. Disconnect EIA-530 cables from the splitter.
c. Remove four screws from splitter.
d. Screw new splitter onto the splitter rack.
e. Connect EIA-530 cables.
f. Connect new power cable provided with the splitter.
6.8 REMOVE AND REPLACE EIA-530 Switch
WARNING: Although extremely remote, there is a possibility of taking the radar out of service when you connect an Ethernet cable into the offsite LAN. Coordination with Air Traffic Control is essential. Advise them that you will be connecting 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. Disconnect power cable from the switch.
b. Remove EIA-530 cables from the back side of the switch.
c. Remove DB-15 connector from the back of the switch.
d. Remove 4 pan head screws that mount switch to the rack.
e. If replacement is an Electro Standards Laboratories M7266, mount switch in place of the old switch using four pan head screws and go to step f. If replacement is a Dataprobe K-AB-530-R-L, then refer to Raytheon INCO manual for installation of Dataprobe switch.
f. Reconnect EIA-530 cables in their respective spots.
g. Reconnect DB-15 connector on the rear of the switch.
h. Connect new power cable to the switch.
i. Ensure that channel indicators match on both the switch and the remote switch.
08/06/2014 SDR-ASR11-048 TI 6310.47 WP 004 07
57
6.9 REMOVE AND REPLACE VDCU Modem
a. Remove power from modem.
b. Remove wiring from modem.
c. Place modem in an ESD safe location.
d. Remove replacement modem from packaging.
e. Configure DIP switches in accordance with Figure 36 for SRM-0 Modem and Figure 37 for the 1080A modems.
f. Reconnect modem to wiring. Apply power to modem.
g. Ensure VDCU operation.
Figure 36. VDCU Modem Removal and Replacement for SRM-9
*
*
*
*
08/06/2014 SDR-ASR11-048 TI 6310.47 WP 004 07
58
Figure 37. VDCU Modem Removal and Replacement for Model 1080A
6.10 REMOVE AND REPLACE RCP Modem The following procedure describes removing and replacing the RCP Modem.
a. Remove telephone cable G710563 from the modem to be replaced (Figure 38).
b. If Power Supply Adapter (PSA) is attached to modem (“B”), remove plug from AC power to the PSA and then remove the PSA from the modem.
c. Remove modem from the unit.
d. On replacement modem, set the DCE/DTE Switch to the DCE position.
e. If a PSA is used, connect PSA to the modem (“B”).
f. Attach modem to the unit.
g. Attach telephone cable G710563 to the modem.
h. If PSA is used, plug into AC power.
PS-115/9AC/100(5)
PS-115/9AC/100(5)
Model 1080AV.24/RJ-45
Modem
Model 1080AV.24/RJ-45
Modem
Note: 1) The DIP switches on 1080A modems are set as shown below2) Connection between modems per FN 3 – G7105633) The power supply leads extend 6’ beyond the connector end4) For reference only5) Power supply on this modem is not interchangeable with SRM-9 modem
Underside of the 1080A showingLocation of the dip switches
S1: 1: OFF2: ON3: OFF4: OFF5: ON6: ON7: ON8: OFF
S2: 1: OFF2: OFF3: OFF4: ON5: ON6: OFF7: OFF8: OFF
S3: 1: ON2: OFF3: OFF4: ON5: OFF6: OFF7: OFF8: OFF
On/OFF position on a DIP-Switch
Front panel switches should be placed at center position (Normal).
1080A Front Panel View with switches
* *
08/06/2014 SDR-ASR11-048 TI 6310.47 WP 004 07
59
Figure 38. RCP Modem Installation
7 COMMUNICATIONS FAULT ISOLATION.
Foldouts FO-4, sheets 1-5 provide fault logic diagrams to enable identifying suspected LRUs that may need to be restored, or removed and replaced, in accordance with the procedures in this WP. Problems relating to the DTE, SDT, SIU, and DVGs may be evaluated using these foldouts.
* *
08/06/2014 SDR-ASR11-048 TI 6310.47 WP 004 07
60
This Page Intentionally Left Blank
09/11/2007 SDR-ASR11-009 TI 6310.47 WP 004 07
FP - 1
Figure FO-1.ASR-11 System InterconnectionDiagram (Production) (Sheet 1 of 5)
STARS/REHOST AUTOMATION SYSTEM COMMUNICATIONS LINK
REFER TO SHEET 6
REFER TO SHEET 7
RADARCONTROL
PANEL
STARS/REHOST
TOWER
REMOTE AUTOMATION SYSTEM
Figure FO-2. ASR-11 Generic Communications Diagram STARS Automation System (Sheet 2 of 9)
10M 10M
MPS 800
RADARCONTROL
PANEL
09/11/2007 SDR-ASR11-009 TI 6310.47 WP 004 07
FP - 8
6 6
10BASE2
10BASET 10BASET
10/100BASET 10/100BASET6 6
X2 X2
X2X2
X2
X26
610/100BASET
10BASET
MAXIMUMLENGTH 100m!
A
B
RADARCONTROL
PANEL
SCDI A SCDI B
OMT
PRIMARYSURVEILLANCE
RADAR
EIA-232EIA-232
EIA-232
REFER TO SHEET 5
EIA-422
EIA-422
MPS 800
SECONDARYSURVELLIENCE
RADAROFFSITE LAN COMMUNICATIONS LINK
RADARSITE
INDICATORSITE
SIU B
SIU A
RADAR CONTROL PANEL COMMUNICATIONS LINK
ARTS AUTOMATION SYSTEM COMMUNICATIONS LINK
REFER TO SHEET 6
REFER TO SHEET 8
RADARCONTROL
PANEL
ARTS-IIIE
TOWER
REMOTE AUTOMATION SYSTEM
Figure FO-2. ASR-11 Generic Communications Diagram ARTS-IIIE Automation System (Sheet 3 of 9)
10M 10M
MPS 800
RADARCONTROL
PANEL
09/11/2007 SDR-ASR11-009 TI 6310.47 WP 004 07
FP - 9
PRIMARYSURVEILLANCE
RADAR
10BASE2
10M 10M
6 6X2 X210BASET 10BASET
! MAXIMUMLENGTH 100m
! MAXIMUMLENGTH 100m
A
B
RADARCONTROL
PANEL
66 X2
X210/100BASET 10/100BASET
SCDI A SCDI B
EIA-232
REFER TO SHEET 5
10/100BASET
10/100BASET
OFFSITE LAN COMMUNICATIONS LINK
MPS 800
SECONDARYSURVEILLIANCE
RADAR
EIA-422
EIA-422
6
6
RADARSITE
INDICATORSITE
EXISTING AUTOMATION SYSTEMCOMMUNICATIONS LINK
REFER TO SHEET 8
10/100BASET
10BASETX4
X26
6
! MAXIMUMLENGTH 100m
REMOTE AUTOMATION SYSTEM
OMT
ARTS-IIE
SDT A
SDT B
6
X4
6X2
RADARCONTROL
PANEL
RADAR CONTROL PANEL COMMUNICATIONS LINK
REFER TO SHEET 6
DVG TO VDCUCOMMUNICATIONS LINK
REFER TO SHEET 9
VDCU
Figure FO-2. ASR-11 Generic Communications DiagramExisting Automation System (Sheet 4 of 9)
10/100BASET
10/100BASET
TOWER
TOWER
EIA-232
MPS 800
RADARCONTROL
PANEL
DVG
VDCU
TRACON
DigitizedRadar Data
Analog Radar Data
ETHERNET SWITCHLAN A
ETHERNET SWITCHLAN B
09/11/2007 SDR-ASR11-009 TI 6310.47 WP 004 07
FP - 10
X2
OFFSITE LANCOMMUNICATIONS
LINK
OFFSITE LANCOMMUNICATIONS
LINK
OFFSITE LANCOMMUNICATIONS
LINK
SCDI A MPS A
X2 X2
TO RADARSITE EQUIPMENT
MPS BSCDI B
X3
10/100BASET
X3
10/100BASET
TO RADARSITE EQUIPMENT
! MAXIMUMLENGTH
100m
TOINDICATOR
SITE EQUIPMENT(2LINKS SHOWN)
TOINDICATOR
SITE EQUIPMENT(2LINKS SHOWN)
10/100BASET 10/100BASET
RADARSITE
INDICATORSITE
TO RADARSITE EQUIPMENT
MPS BSCDI B
X3
10/100BASET
X3
10/100BASET
TO RADARSITE EQUIPMENT
! MAXIMUMLENGTH
2km(Note 1)
TOINDICATOR
SITE EQUIPMENT(2LINKS SHOWN)
TOINDICATOR
SITE EQUIPMENT(2LINKS SHOWN)
10/100BASET 10/100BASET
RADARSITE
INDICATORSITE
TO RADARSITE EQUIPMENT
MPS BSCDI B
X3
10/100BASET
X3
10/100BASET
TO RADARSITE EQUIPMENT
!MAXIMUMLENGTH
25km(Note 1)
TOINDICATOR
SITE EQUIPMENT(2LINKS SHOWN)
TOINDICATOR
SITE EQUIPMENT(2LINKS SHOWN)
10/100BASET 10/100BASET
RADARSITE
INDICATORSITE
48 48
49
50
49
50
49
51 48 48
49
51
NOTES;
1. MAXIMUM LENGTH IS RESTRICTED BYOPTICAL ATTENUATION WHICH MAY BECALCULATED AS FOLLOWS: MM SM11dB 15dB OPTICAL POWER BUDGET-2dB -2dB SYSTEM MARGIN-0.3dB -0.3dB REPAIR MARGIN-(C*0.3)dB -(C*0.3)dB CONNECTIONS-(S*0.15)dB -(S*0.15)dB SPLICE LOSS-(L*1.0)dB/km -(L*0.4)dB/km CABLE ATTENUATION-0dB -0dB OTHER OPTICAL COMPONENTS (SITE SPECIFIC)--------------------------------------------------------------This number must be greater than or equal to 0
Where:L=Cable Length in km.S=Number of Splices in CableC=Number of Connector Pairs (ST TYPE)
Multi Mode Fiber
0 - 100m600m - 2km > 2km
6 6 6 66 6
48 48 52 52
54 54
53 53
55 55
6 6
SCDI A MPS A SCDI A MPS A
X2 X2 X2
LAN A SWITCH10/100M
LAN A SWITCH10/100M
66
LAN A SWITCH10/100M
6
LAN A SWITCH10/100M
LAN B SWITCH10/100M
LAN B SWITCH10/100M
LAN B SWITCH10/100M
LAN B SWITCH10/100M
6
LAN A SWITCH10/100M
LAN B SWITCH10/100M
LAN A SWITCH10/100M
LAN B SWITCH10/100M
LAN A SWITCH10/100M
LAN B SWITCH10/100M
Single Mode FiberHard Wire
Figure FO-2 ASR-11 Generic Communications DiagramOffsite LAN Communications Link (Sheet 5 of 9)
09/11/2007 SDR-ASR11-009 TI 6310.47 WP 004 07
FP - 11
9.6k
2.4k 2.4k
2.4k2.4k
30
20
30
30
39
39
60
60
RADARCONTROL
PANEL
RADARCONTROL
PANEL
RADARCONTROL
PANEL
RADARCONTROL
PANEL
RADARCONTROL
PANEL
RADARCONTROL
PANEL9.6k
9.6k
9.6k
POWERSUPPLY
ADAPTER
POWERSUPPLY
ADAPTER
Direct Connection (0 - 15.2m)(NOTE 1)
NOTES:
1. THE MAXIMUM LENGTH BETWEEN SITES MAY BE INCREASED BY USING HEAVIER GUAGE WIRE. THE SPECIFIED DISTANCE IS FOR 24 GUAGE WIRE.
2. THE SPECIFIED DISTANCE IS FOR 26 GUAGE ORDINARY UNLOADED 4-WIRE TWISTED PAIR.
3. WHEN TWO RCPs ARE CONNECTED TO ONE OMT/SCDI A DB-9 TO DB-25 ADAPTER IS REQUIRED
Inter-Facility Telco (15.2m - 5.5Km)(NOTE 1)
Inter-Facility Telco or Leased Line (15.2m - 10km)(NOTE 2)
Figure FO-2. ASR-11 Generic Communications DiagramRadar Control Panel Communications Link (Sheet 6 of 9)
RADAR CONTROL PANEL COMMUNICATIONS LINKS
OR EQUIVALENT
MAXIMUMLENGTH 15.2m
EIA-232
EIA-232
DB-25
DB-9DB-25
OMT
DB-25
(NOTE 3)
(NOTE 3)
DB-9
DB-25
MAXIMUMLENGTH 5.5km
MAXIMUMLENGTH 10km
DB-25DB-25
DB-25 DB-25
DB-9
(NOTE 3)
OMT
OMT
TOWER
TOWER
!
!
18
18
18
18
20
17
31
31
38
38
30
3020
17
DB-25
!
09/11/2007 SDR-ASR11-009 TI 6310.47 WP 004 07
FP - 12
56k
56k
19
19
18
18
18
18
19
19
36
36
37
41
41
5
5
!
56k
56kEIA-530
EIA-530 EIA-530
EIA-530
MAXIMUMLENGTH 5.5km
(NOTE 1)
(NOTE 3)
(NOTE 3)
STARS/REHOST
CD-2 & ASTERIX SERIAL DATA, 56kbps0 - 5.5km
CD-2 SERIAL DATA, 56kbps> 5.5km
56k
56k
19
19
18
18
EIA-530
EIA-530
18
18
19
19
36
36
37
41
41
56k
56k
EIA-530
EIA-530
(NOTE 3)
(NOTE 3)
STARS
Dedicated LineREMOTE AUTOMATION SYSTEM
SIU B
SIU A
EIA-530
EIA-530
Direct ConnectionLOCAL AUTOMATION SYSTEM
STARS/REHOST AUTOMATION SYSTEM COMMUNICATIONS LINKS
CD-2 & ASTERIX SERIAL DATA, 56kbps0 - 1.2km
43
43
!
REMOTE AUTOMATION SYSTEM
demarc demarc
Fractional T1/DDS Leased Line
(NOTE 4)
MAXIMUMLENGTH 1.2km
Figure FO-2. ASR-11 Generic Communications DiagramSTARS/REHOST Automation System Communications Link (Sheet 7 of 9)
NOTES:
1. THE MAXIMUM LENGTH BETWEEN SITES MAY BE INCREASED BY USING HEAVIER GAUGE WIRE. THE SPECIFIED DISTANCE IS FOR 26 GAUGE ORDINARY UNLOADED 4-WIRE TWISTED PAIR
2. UNLESS OTHERWISE SPECIFIED, 56Kbps DATA LINKS ARE CATEGORY A, 4-WIRE, DATAPHONE
DATA SERVICE (DDS-56)
3. F/N”S 36 AND 37 ARE USED WHERE F/N 18 IS GREATER THAN 6 CABLE FEET AWAY FROM THE STARS DEMARCATION.
4. USED WHERE THE CABLE LENGTH BETWEEN THE SIU’s AND STARS IS UP TO 4000 FEET AND DSUs/
CSUs (F/N 18) ARE NOT USED.
5. DEMARCATION POINT IS GOVERNMENT FURNISHED EQUIPMENT (GFE).
6. THE REMOTE CSU/DSU SHOULD BE SET TO INTERNAL TIMING IF NO CLOCK IS PROVIDED ON THE LINE.
7. FOR REHOST INPUT CONFIGURE CSU/DSU DTE TO RS-232
8. THE EIA-530 SPLITTER IS INSTALLED AT THE SIU OUTPUT AT ARTS-IIIE AND STARS FACILITIES
STARS
6 6
6 6
(NOTE 6)
(NOTE 6)
(NOTE 7)
(NOTE 7)
(NOTE 8)
ABCD
I
EIA-530 SPLITTER
ABCD
I
EIA-530 SPLITTER
SIU B
SIU A
(NOTE 8)
ABCD
I
EIA-530 SPLITTER
ABCD
I
EIA-530 SPLITTER
SIU B
SIU A
(NOTE 8)
ABCD
I
EIA-530 SPLITTER
ABCD
I
EIA-530 SPLITTER
09/11/2007 SDR-ASR11-009 TI 6310.47 WP 004 07
FP - 13
TO OMT LAN A INPUT
TO OM T LAN B INPUT
TO SDT B LAN A INPUT
TO SDT B LAN B INPUT
TO SDT A LAN A INPUT
TO SDT A LAN B INPUT
D irect Connection (0-100m)
OFFSITE LAN A SW ITCH (SHT 4)
OFFSITE LAN B SW ITCH (SHT 4)
OFFSITE LAN A SW ITCH (SHT 4)
OFFSITE LAN B SW ITCH (SHT 4)
TO OMT LAN A INPUT
TO OMT LAN B INPUT
TO SDT B LAN A INPUT
TO SDT B LAN B INPUT
TO SDT A LAN A INPUT
TO SDT A LAN B INPUT
ROUTER10M
ROUTER10M
ROUTER10M
56k
T1
T1
T1
T1
56k
EXISTING AUTOMATION SYSTEM COMMUNICATIONS LINKS
REMOTE AUTOMATION SYSTEMdem arc demarc
(NOTE 1C)
(NOTE 1C)
(NOTE 1C)
ROUTER10M
ROUTER10M
ROUTER10M
6
6
6
6
6
6
6
6
6
6
6
6
SW ITCH10/100M
SW ITCH10/100M
34
34
59
57
5959
59
57
49
49
(NOTE 2A) (NOTE 2A)
(NOTE 2B)
(NOTE 2B)
(NOTE 2B)
(NOTE 2B)
10BASET
10BASET
10BASET
NOT USED
Fractional T1 Line
NOT USED
(NOTE 3)(NOTE 3)
F igure FO-2. ASR-11 Generic Communications DiagramExisting Automation Systems Communications Link (Sheet 8 of 9)
NOTES:
1 . UNLESS OTHERW ISE SPECIFIED: A . 56Kbps DATA LINKS ARE CATEGO RY A , 4-W IRE, DATAPHONE DATA SERVICE (DDS-56) USE W IRES 1,2,7,8.
B . 19.2Kbps DATA LINKS ARE CATEGORY A , 4-W IRE, DATAPHONE DATA SERVICE (DDS-19.2) USE W IRES 1,2,7,8. C . FRACTIONAL T1 LINKS ARE 4 W IRE SERVICE. USE W IRES 1,2,4,5.
2 . UNLESS OTHERW ISE SPECIFIED: A . THE CISCO 1600 SERIES ROUTERS M UST BE LOADED W ITH CISCO IOS VER 11.2(14) AND CONFIGURED.
B . THE CISCO 1721 ROUTERS MUST BE LOADED W ITH CISCO IOS VER 12.3(1)P AND CONFIGURED .
3 . UNLESS OTHERW ISE SPECIFIED, CABLING BETW EEN THE W IC CARD AND TELCO DEMARC IS STRAIGHT THROUGH . REFER TO SATP AND INSTALLATION M ANUAL
LAN A SwitchSheet 4
LAN B SwitchSheet 4
09/11/2007 SDR-ASR11-009 TI 6310.47 WP 004 07
FP - 14
VDCU
VDCU
VDCU
VDCU
Direct Connection (0 - 15.2m) (NOTE 1)
EIA-232
EIA-232
(NOTE 6)
DVG
IndividualDVG
DVG Pair(NOTE 6)
DVG Switch
Inter-Facility Telco (15.2 m- 5.5km) (NOTE 1)
(NOTE 2)
(NOTE 2)
47
47
56k
56k
56k
56k
!
!
TOWER
MAXIMUMLENGTH 5.5km
DVG DVG
DVG
MAXIMUMLENGTH 5.5km
IndividualDVG
DVG Pair
NOTES:
1. THE MAXIMUM LENGTH BETWEEN SITES MAY BE INCREASED BY USING HEAVIER GUAGE WIRE. THE SPECIFIED DISTANCE IS FOR 24 GUAGE WIRE.
2. THE SDT INCLUDES 12 DVG’S. THE DVG CONFIGURATION CAN SUPPORT UP TO 4 DVG PAIRS AND 4 INDIVIDUAL DVGS
Figure FO-2. ASR-11 Generic Communications DiagramDVG/VDCU Communications Link (Sheet 9 OF 9)
09/11/2007 SDR-ASR11-009 TI 6310.47 WP 004 07
FP - 15
09/11/2007 SDR-ASR11-009 TI 6310.47 WP 004 07
FP - 16
09/11/2007 SDR-ASR11-009 TI 6310.47 WP 004 07
FP - 17
FP - 18
FP - 19
SIU SUMMARYSTATUS
SIU A AND/OR BSHOWN AS RED
BOXES?
DOES THE SIU HAVEPOWER ? IS THE SDT/SIU NET RED?
IS SIU IP ADDRESSCORRECT?
REF PARA 7.3.1 OF THESIU IOMM
YES YES
YES
NO NO
CHECK ANDRESTORE
COMMUNICATION.END TASK
REPLACE SIUIAW
PARA 4-6.2END TASK
NO
RESTOREPOWER
END TASK
CORRECT IPADRESS
END TASK
Figure FO-4. Fault Isolation DiagramSIU Sheet 3 of 5
FP - 20
DVG(S) SHOW RED ON OMT
ARE BOTHLAN A AND B
ETHERNET ACTIVITYLIGHTS LIT ON DVG?
CHECK DVG LANA/B
HUB ANDETHERNET
CABLING TO DVG
ENSURE DVG ISONLINE
PARA. 8.3.2 OFTHE CMC IOMM
DOES PROBLEM STILLEXIST?
REPLACE DVGPARA 4-6.7
END
ARE CABLING AND THEDVG LAN HUBS OK?
REPLACE DVGPARA 4-6.7
REPLACE FAULTYCABLE OR DVGLAN HUB PER
DASR DTE IOMMPARA. 8.4.3.5
Figure FO-4. Fault Isolation DiagramDVG Sheet 4 of 5
YESYES
YES
NO
NONO
FP - 21
LOSS OF CONNECTIVITYWITH REMOTE OMT
ARE APPROP. LEDsLIT ON ROUTER?
(CONSULT ROUTERMANUAL)
DOES WIC HAVEAN ALARM LED LIT?(CONSULT ROUTER
MANUAL)
CHECK TELCO FOR CKTSTATUS. IS CKT UP?
REPLACE ROUTERPER PARA 4-6.5
END TASK
TELCO RESTORESCKT
END TASK
ARE ALL CABLESPROPERLY
CONNECTED?
ARE QUAD ETHERNETPORT LEDS 2 & 3
GREEN?
REBOOT OMT. ISPROBLEM
CORRECTED?END TASK
REPLACE OMT.END TASK
RECONNECTCABLES
END TASK
PORT 1 OR 2 RED ONSDT DETAILED STATUS
SCREEN
IS OFFSITE LANPROVIDED BY TELCO?
IS ALARM LED LIT ONBOTH LOCAL & REMOTE
ROUTERWIC CARDS?
CHECK TELCOFOR STATUS IS TELCO OK?
REPLACE ROUTERPER PARA 4-6.5
END TASK
REPLACE ROUTERPER PARA 4-6.5
END TASK
REPLACE CABLEEND TASK
IS CABLING OK?
CHECK CABLINGBETWEEN ROUTER ANDETHERNET SWITCH ATRADAR AND TRACON
ARE THERE ANY OTHERDTE FAILURES?
REPLACE FAILEDOFFSITE LAN SWITCHPER PARA 4-6.3 OR 6.4
END TASK
-CHECK OFFSITE LANSWITCHES HAVE POWER-CHECK ETHERNETACTIVITY LIGHTS AREACTIVE-ENSURE FIBEROPTICMODULE INSTALLED INSWITCH HAS NOT FAILEDBY SWAPPING OFFSITELAN A SWITCH WITH THEOFFSITE LAN B SWITCH.
CHECK SDTFO-04 SHEET 2
ARE FIBER OPTICCABLES PROPERLY
CONNECTED?
TELCO RESTORESCIRCUIT
END TASK
RECONNECTCABLES
END TASK
Figure FO-4. Fault Isolation DiagramASR-11 communications Sheet 5 of 5