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Compact BTS Expansion Configuration (Indoor) – continued

E-18 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU Jun 2004

DRAFT

Figure E-8: Two Expansion BTSes Cabling Diagram

EXPANSION 2

EXPANSION 1

STARTER

LOCAL GPS

Power and Ground not shown

Ensure that the expansion

BTSes have the expansion

cMPC cards installed.

COMBINER

TX 1

RX MAIN

RX DIV

TX 2

Summary of content (58 pages)

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Compact BTS Expansion Configuration (Indoor) – continued Figure E-8: Two Expansion BTSes Cabling Diagram Power and Ground not shown Ensure that the expansion BTSes have the expansion cMPC cards installed.
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Compact BTS Expansion Configuration (Indoor) – continued Figure E-9: One Expansion BTS Cabling Diagram Power and Ground not shown LOCAL GPS Ensure that the expansion BTS has an expansion cMPC card installed.
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Compact BTS Expansion Configuration (Indoor) – continued Table E-11: BBX (Carrier) to cCLPA Via RS485 BTS cCLPA Starter – BBX1 cCLPA–1 Starter – BBX4 cCLPA–1 Expansion 1 – BBX1 cCLPA–2 Expansion 1 – BBX4 cCLPA–2 Expansion 2 – BBX1 cCLPA–1 Expansion 2 – BBX4 cCLPA–1 Expansion 3 – BBX1 cCLPA–2 Expansion 3 – BBX4 cCLPA–2 Table E-12 shows in tabular format the BTS–to–cCLPA cabling of Figure E-1.
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Compact BTS Expansion Configuration (Indoor) – continued Table E-13: Starter and Two Expansion BTS Cabling for Circuit or Packet to Dual cCLPAs BTS cCLPA Starter – BBX1 CPA–A (CPA–1) Starter – BBX4 CPA–A (CPA–1) Expansion 1 – BBX1 CPA–B (CPB–2) Expansion 1 – BBX4 CPA–B (CPB–2) Expansion 2 – BBX1 CPA–A (CPA–1) Expansion 2 – BBX4 CPA–A (CPA–1) Starter and One Expansion BTS to cCLPA Cabling Table E-14 shows in tabular format the BTS–to–cCLPA cabling of Figure E-3.
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Multiple Compact BTS Configuration (Outdoor) Introduction This section covers only the outdoor version of the multiple Compact BTS configuration. Materials Needed The following materials are required to configure expansion BTSes.
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Multiple Compact BTS Configuration (Outdoor) – continued S Directional coupler and combiner are not environmentally protected , and so must be placed within the TME. ExpansionCompact BTS Installation Procedure Follow the procedure in Table E-16for installation of multiple Compact BTSes. Table E-16: Procedure for Installing Expansion Compact BTSes Step Action 1 Follow the procedure in Chapter 4 for installing a Compact BTS in a rack. 2 For a 3 BTS expansion configuration, follow Figure E-1.
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Multiple Compact BTS Configuration (Outdoor) – continued Figure E-10: Three Expansion BTSes Cabling Diagram Power and Ground not shown EXPANSION 3 LOCAL GPS TME RF–GPS CONNECTOR LIGHTNING ARRESTOR cCLPA 1 EXPANSION 2 E STARTER EXPANSION 1 LIGHTNING ARRESTOR RX MAIN TX1 cCLPA 2 RX DIV TX2 TME ANTENNA CONNECTORS E-24 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU DRAFT Jun 2004
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Multiple Compact BTS Configuration (Outdoor) – continued Figure E-11: Outdoor Two Expansion BTSes Cabling Diagram Power and Ground not shown LOCAL GPS TME RF–GPS CONNECTOR LIGHTNING ARRESTOR cCLPA 1 EXPANSION 2 E STARTER EXPANSION 1 LIGHTNING ARRESTOR RX MAIN TX1 cCLPA 2 RX DIV TX2 TME ANTENNA CONNECTORS Jun 2004 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU DRAFT E-25
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Multiple Compact BTS Configuration (Outdoor) – continued Figure E-12: Outdoor One Expansion BTS Cabling Diagram Power and Ground not shown LOCAL GPS LIGHTNING ARRESTOR TME RF–GPS CONNECTOR cCLPA 1 STARTER E EXPANSION 1 LIGHTNING ARRESTOR RX MAIN TX1 cCLPA 2 RX DIV TX2 TME ANTENNA CONNECTORS Other Diagrams For single cCLPA and no cCLPA, refer to the diagrams for indoor and allow for the TME connectors as shown in the diagrams presented in this appendix.
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Appendix F: Logical BTS Configuration Appendix Content Logical BTS LAN Configuration for Compact BTS (Indoor) . . . . . . . . . . . . . . Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Materials Needed . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . BTS ID Switch Settings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Logical BTS LAN Cabling Installation Procedure . . . . . . . . . . . .
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Table of Contents – continued Notes F 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU DRAFT Jun 2004
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Logical BTS LAN Configuration for Compact BTS (Indoor) Introduction This appendix covers only the Logical BTS configuration for cicruit Compact BTS. The diagrams cover only the LAN connections. This configuration is set up to be used only with other Compact BTSes. Power and ground cabling are not shown. The LAN operates at 10Mbps which is an ethernet standard. It provides an interface for each GLI in the confiiguration. Refer to Figure 6-1 for location of the LAN connectors.
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Logical BTS LAN Configuration for Compact BTS (Indoor) – continued Figure F-2: Two Expansion BTSes LAN Cabling Diagram 50–ohm Loads Ain Bin Aout Bout STARTER Ain Bin Aout Bout Ain Bin Aout Bout EXPANSION 1 EXPANSION 2 50–ohm Loads Figure F-3: One Expansion BTS LAN Cabling Diagram F 50–ohm Loads Ain Bin Aout Bout Ain Bin Aout Bout STARTER F-2 50–ohm Loads EXPANSION 1 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU DRAFT Jun 2004
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Logical BTS LAN Configuration for Compact BTS (Indoor) – continued Logical BTS LAN Cabling Installation Procedure Follow the procedure in Table F-1 for installation of LAN cables for Logical BTS. Table F-1: Procedure for Installing LAN Cabling for Logical BTS Step Action 1 Follow the procedure in Chapter 4 for installing a Compact BTS in a rack. 2 For a 3 BTS expansion configuration, follow Figure F-1. Proceed to step 3. 2a For a 2 BTS expansion configuration, follow Figure F-2. Proceed to step 3.
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Logical BTS LAN Configuration for Compact BTS (Indoor) – continued Notes F F-4 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU DRAFT Jun 2004
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Appendix G: Integrated BTS Router Preliminary Operations Appendix Content Integrated BTS Router Preliminary Operations – Introduction . . . . . . . . . . . . . Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Preliminary Operations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . When to Perform the Verifications . . . . . . . . . . . . . . . . . . . . . . . . . . . .
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Table of Contents – continued Notes G 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU DRAFT Jun 2004
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Integrated BTS Router Preliminary Operations – Introduction Introduction The information and procedures provided are performed in cases where the GLI3 load and span parameters need to be verified. Preliminary Operations Implementing the Integrated BTS Router (IBR) function requires some preliminary checks of the GLI3 cards which will be used. This appendix provides the procedures to accomplish these checks.
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Verify GLI3 Software Version and Span Parameter Settings Verify GLI3 Software Version and Span Parameter Settings Software Version Verification – Before upgrading a BTS to packet backhaul with an IBR, the software version installed in the GLI3 card or cards must be verified. If the installed software version does not support IBR functionality, it must be upgraded to a version which does.
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Verify GLI3 Software Version and Span Parameter Settings – continued Table G-2: Verify GLI3 Software Version and Span Parameter Settings Step Action 1 If it has not been done, start a GLI3 MMI communication session on the LMF computer as described in Table 6-11. 2 Verify the installed software version by entering the following at the GLI3 prompt: display version 3 Response to the command will depend on the operating mode of the card.
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Verify GLI3 Software Version and Span Parameter Settings – continued Table G-2: Verify GLI3 Software Version and Span Parameter Settings Step 3b Action – For cards in packet mode: GLI3> display version 03.23.2004 18:16:07 MGLI–250–1 CC PRESENT BTS–CDMA 16.41.00.11 INTERNAL RAM VERSION: 16.41.0.11 RAM Built: Tue Mar 2 04:59:33 2004 il27–2112 BOOTROM VERSION: 16.41.00.08 BOOTROM Built: Tue Feb 17 10:52:27 2004 il27–0507 BOOTBLOCK VERSION: 16.1.59.
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Verify GLI3 Software Version and Span Parameter Settings – continued Table G-2: Verify GLI3 Software Version and Span Parameter Settings Step 5 Action Verify the span parameter settings for frame format, equalization, and linkspeed by entering the following at the GLI3> prompt: config ni current The system will respond with a display similar to the following: The frame format in flash Equalization: Span A – Default (0–131 Span B – Default (0–131 Span C – Default (0–131 Span D – Default (0–131 Span E – D
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Change GLI3 Span Parameter Settings Change GLI3 Span Parameter Configuration If span parameter settings in the GLI3 card do not match the OMC–R database span parameters for the BTS where they are to be installed, follow the procedure in Table G-3 to change them. Table G-3: Set GLI3 Span Parameter Configuration Step Action 1 If it has not been done, start a GLI3 MMI communication session on the LMF computer as described in Table 6-11.
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Change GLI3 Span Parameter Settings – continued Table G-3: Set GLI3 Span Parameter Configuration Step 4 Action An acknowledgement similar to the following will be displayed: The value has been programmed. It will take effect after the next reset.
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Change GLI3 Span Parameter Settings – continued Table G-3: Set GLI3 Span Parameter Configuration Step 8 Action If the span equalization must be changed, enter the following MMI command: config ni equal A response similar to the following will be displayed: COMMAND SYNTAX: config ni equal Next available options: LIST – span : Span a : Span b : Span c : Span d : Span e : Span f : Span > span equal A B C D E F . . .
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Change GLI3 Span Parameter Settings – continued Table G-3: Set GLI3 Span Parameter Configuration Step 9 Action At the entry prompt (>), enter the designator from the list for the span to be changed as shown in the following example: > a A response similar to the following will be displayed : COMMAND SYNTAX: config ni equal a equal Next available options: LIST – equal : Span Equalization 0 : 0–131 feet (default for T1/J1) 1 : 132–262 feet 2 : 263–393 feet 3 : 394–524 feet 4 : 525–655 feet 5 : LONG HAUL 6
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Change GLI3 Span Parameter Settings – continued Table G-3: Set GLI3 Span Parameter Configuration Step 10 Action At the entry prompt (>), enter the code for the required equalization from the list as shown in the following example: > 0 A response similar to the following will be displayed : > 0 The value has been programmed. It will take effect after the next reset. GLI2> 11 Repeat steps 8 through 10 for each in–use span.
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Change GLI3 Span Parameter Settings – continued Table G-3: Set GLI3 Span Parameter Configuration Step 14 Action Once the card has completed resetting, execute the following command to verify span settings are as required: config ni current A response similar to the following will be displayed : The frame format in flash Equalization: Span A – 0–131 feet Span B – 0–131 feet Span C – Default (0–131 Span D – Default (0–131 Span E – Default (0–131 Span F – Default (0–131 is set to use T1_2.
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Change GLI3 Span Parameter Settings – continued Notes G G-12 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU DRAFT Jun 2004
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Appendix H: Integrated BTS Router Installation Appendix Content Integrated BTS Router Installation – Introduction . . . . . . . . . . . . . . . . . . . . . . . Background . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . H-1 H-1 New Packet BTS Installation with IBR . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . New Packet BTS Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Prerequisites . . . . . . . . . . . . . . . .
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Table of Contents – continued Notes H 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU DRAFT Jun 2004
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Integrated BTS Router Installation – Introduction Background The IBR capability was developed to provide a low–cost solution for providing CDMA packet backhaul benefits at cell sites with lower traffic volumes. The IBR function is implemented by using the GLI3 card Concentration Highway Interface (CHI) bus 2 processor to perform the router function. This is accomplished through changes in the GLI3 card software.
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New Packet BTS Installation with IBR New Packet BTS Installation This section covers the actions necessary for implementing IBR packet capability in the installation of a new BTS. Procedures unique to this implementation are contained in this section. When procedures required in this implementation are contained in other parts of this publication or in other publications, the user will be specifically directed to them at the appropriate places in this section.
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New Packet BTS Installation with IBR – continued Table H-1: Implement IBR Functionality in New BTS Step Action 7 Refer to the site documentation for IBR spans and inspect the BTS span cabling connections to be sure they match Figure H-1. 8 Correct any cabling discrepancies between the BTS span cabling and site documentation, referring to Figure H-1 and the Install Span and Alarm Cables and Span Line Cable Pin Numbering Chapter 4 of this manual as required.
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BTS Span Connections for IBR BTS Span Connections The illustration in this section provides the detail of span connection for a non–redundant BTS to support IBR packet operation. The required configuration for IBR in redundant BTS is a single span.
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BTS Span Connections for IBR – One Span One Span Frame Figure H-1 illustrates the connection details for one span to support packet operation with IBR for non–redundant BTS.
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BTS Span Connections for IBR – One Span – continued Notes H H-6 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU DRAFT Jun 2004
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Appendix I: Packet Backhaul Configuration Appendix Content Packet Backhaul BTS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Packet Backhaul BTS Procedures . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
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Table of Contents – continued Notes I 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU DRAFT Jun 2004
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Packet Backhaul BTS Introduction For Packet Backhaul, the LMF Help should be accessed for the appropriate procedures.
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Packet Backhaul BTS – continued Notes I I-2 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU DRAFT Jun 2004
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Appendix J: Highway Cell Configuration Appendix Content BTS for Highway Cell Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Highway Cell Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
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Table of Contents – continued Notes J 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU DRAFT Jun 2004
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BTS for Highway Cell Configuration Introduction The highway cell configuration is a 1 carrier, two sector with no RX diversity and one duplexed antenna. The configuration is for 1.9 GHz and +27 V. The 1.9 GHz, +27V A & B–Band does not support highway configuration. Highway Cell Configuration Figure J-1 shows a typical highway cell configuration. DC power may be provided by a +27V Power Distribution Enclosure or other equivalent power source. Units may be pole or wall mounted.
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BTS for Highway Cell Configuration – continued Figure J-1: Typical Highway Cell Configuration Diagram Power and Ground not shown LOCAL GPS TME RF–GPS CONNECTOR LIGHTNING ARRESTOR cCLPA 1 STARTER SURGE ARRESTORS SAs RX MAIN TX1 RX DIV TX2 LIGHTNING ARRESTOR TME ANTENNA CONNECTORS SAs cCLPA 2 J J-2 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU DRAFT Jun 2004
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Index Numbers code domain power acceptance test procedure, 7-19 10BaseT/10Base2 converter, LMF to BTS failure report generation, 7-23 FER test, frame error rate testing, 7-21 pilot time offset, 7-16 prerequisites, 7-2 spectral purity TX mask, 7-11 test set–up, 6-61 Advantest R3267/R3562, DRDCs, 6-64 Advantest R3465, 6-61 Agilent 8935, DRDCs, 6-61 Agilent 8935/E4432B, DRDCs, 6-63 Agilent E4406A/E4432B, DRDCs, 6-63 CyberTest, 6-61 HP 8921A, 1.
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Index – continued RX sensitivity/frame error rate, 7-10 system software download, 6-6 BTS Frame Erasure Rate.
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Index – continued Download/Enable MGLIs, 6-39 Gigatronics 8541C Power Meter, B-15 Hewlett Packard HP8921a & HP83236A/B, B-11 Motorola CyberTest, B-13 E E1, isolate BTS from the E1 spans, 6-16 GPIB Interface Box, RS232, B-16 E4406A, calibration, B-28 Enable CSMs.
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Index – continued LIF, Load Information File, 6-10 Pilot time offset, acceptance test, 7-16 LMF, B-17 , B-22 1X FER acceptance test, 7-4 1X upgrade preparation, home directory, 6-9 BTS connection, 6-17 to BTS connection, 6-16 TX acceptance tests, 7-4 view CDF information, 6-6 Ping, 6-33 LMF BTS displays, 6-19 Pre–calibration, HP 437, B-29 LMF Removal, 8-4 Preliminary operations, cell Site types, 6-1 Load Information File, 6-10 Prepare to leave site connect BTS E1/T1 spans, 8-4 connect BTS T1/E1 s
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Index – continued test cable calibration, 1-16 Restore Carrier Signaling Operations for a Circuit BTS, 10-29 Restore Carrier Signaling Operations for a Packet BTS, 10-59 Restore Carrier Signaling Operations Procedure For a Circuit BTS, Starting Up, 10-29 Restore Carrier Signaling Operations Procedure For a Packet BTS, Starting Up, 10-59 Restore Sector Signaling Operations for a Circuit BTS, 10-26 Restore Sector Signaling Operations for a Packet BTS, 10-56 Restore Sector Signaling Operations Procedure For
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Index – continued Tektronics, model 2445 or equivalent, optional test equipment, 1-21 Test cable calibration, required test equipment, 1-16 Test Equipment, Calibrating, 6-68 Test equipment set up, TX output verification/control, 7-4 system analyzer, 1-18 TX acceptance tests, 7-4 Test equipment connections , preliminary Agilent E4406A/E4432B set–up, B-26 Test Equipment Setup Calibration for TX Bay Level Offset, B-36 Test Equipment Setup Chart, 6-53 Test equipment setup RF path calibration, 6-78 transmit pa
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*68P09262A08−1* 68P09262A08–1
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Technical Information 1X SC480 BTS HARDWARE INSTALLATION, OPTIMIZATION/ATP, AND FRU SOFTWARE RELEASE 2.16.5.X 1.
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1X SC480 BTS HARDWARE INSTALLATION, OPTIMIZATION/ATP, AND FRU SOFTWARE RELEASE 2.16.5.X 1.
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Technical Information Products and Services STANDARD MANUAL PRINTING INSTRUCTIONS Filename: Part Number: 68P09262A08–1 262A08–1 APC: 379 Title: 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU Volume 1 of 1 Print Vendor: eDOC Date Jun 2004 ÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇ STANDARD SPECIFICATIONS – FOR REFERENCE–DO NOT MODIFY ÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇ ÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇ ÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇ ÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇ ÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇÇ