Page 1
Span Line, RGPS, and RF–GPS Cabling – continued
Connecting Customer–Defined
Inputs to the CBIO
The unit provides eight customer–defined inputs for connection to
external contacts. Each input (a signal/ground pair) is monitored for an
“OPEN” (>50 k Ohms) or “CLOSED” (<3 Ohms) condition.
RGPS or RF–GPS Installation
If RGPS is being installed, proceed to Table 4-36. If RF–GPS is being
installed, proceed to Table 3-7.
Cable Pinout
Figure 4-42 shows the connector pins on cables C and C1. Table 4-35
gives the pinout for cable C and C1.
Figure 4-42: Connector Pins Numbering for Cables C and C1
4
1
2
3
CONNECTOR FOR
10
11 12
4
5
CABLE C
9
8
7
6
PIN 9
PIN 1
CONNECTOR FOR
CABLE C1
Table 4-35: Pinout for Cables C and C1
Cable C Wire Color Cable C1
Pin Signal Pin
9 DC Ground 1 Blue–Black 15
1 Power 1 Blue 8
8 DC Ground 2 Yellow–Black 14
10 Power 2 Yellow 7
Jun 2004
4 Transmit Port (–) Green–Black 9
5 Transmit Port (+) Green 1
2 Receive Port (–) White–Black 12
3 Receive Port (+) White 4
7 No Connect Red–Black No Connect
table continued on next page
1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU
DRAFT
4-67
Page 2
Span Line, RGPS, and RF–GPS Cabling – continued
Table 4-35: Pinout for Cables C and C1
Cable C Cable C1Wire Color
Pin PinSignal
6 No Connect Red No Connect
12 PPS Timing (–) Brown–Black 10
11 PPS Timing (+) Brown 2
Wire colors are the same for both cables.
Procedure to Install the RGPS
4
Head
The RGPS is connected to the BTS via the RGPS connector on the
CBIO Board. See Figure 4-41.
Site specific characteristics determine the GPS cabling that is installed.
Install each cable by referring to the cabling diagram in Figure 4-41, and
the procedure in Table 4-36. The lightning arrestor connections are
shown in Figure 4-46.
Figure 4-43 and Figure 4-44 show the RGPS head. Be sure to factor in
mounting considerations as described in Chapter 3.
CAUTION
The RGPS head must not make contact with any metal
surface other than the provided hardware. Use only the
equipment provided to mount the RGPS head. Failure to
do so could damage the RGPS head.
Table 4-36: Procedure for Installing the RGPS Head and Cabling
Step Action
1 Determine the mounting location.
2
3 Remove RF–GPS cover plate from CBIO Board.
n W ARNING
The structure of the wall should be verified by a qualified structural engineer.
Mounting the RGPS head and hardware to an inadequate wall structure and/or using inadequate
installment methods can result in serious personal injury.
Use the appropriate mounting bolts for the mounting surface and install the two wall mounting
brackets. Refer to Figure 4-43.
Remove protective connector cover.
4 Connect cables C and C1 into the punch block, as if they were part of the same cable, cut in the
middle maintaining color code and signal integrity. Connect the same corresponding color on both
sides of the punchblock (see Figure 4-41 and Table 4-35).
4-68
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Jun 2004
Page 3
Span Line, RGPS, and RF–GPS Cabling – continued
Table 4-36: Procedure for Installing the RGPS Head and Cabling
Step Action
5 Connect RGPS cable (cable C1) to D–connector.
Attach ferrite bead on the cable close to the BTS connector.
6 Route RGPS cable C (12–pin Deutsch connector) into the pipe.
7 Mate the 12–pin Deutsch connector of the RGPS Head cable and cable C. Refer to Figure 4-43.
Tighten the spinning flange on the connector a quarter turn to secure the connection.
8 Insert the pipe into the threaded mount in the RGPS Head and carefully hand–tighten.
9 Place the assembly into the mounting brackets. Refer to Figure 4-43. Tighten the U–bolt clamps
to secure the assembly.
Figure 4-43: Installing the Remote GPS Head
VIEW A
4
RGPS HEAD
(MOTOROLA PART
NUMBER 0186012H03)
U–BOLTS
RGPS HEAD WITH
12 PIN MALE
CONNECTOR
1
RGPS INTERFACE
CABLE WITH 12 PIN
FEMALE CONNECTOR
ON ONE END AND
UNTERMINATED WIRE
ON OTHER END
REFER TO VIEW A
NOTE:
CLAMP BRACKETS (2)
1. REPLACEMENT RGPS HEAD
(MOTOROLA PART NUMBER
0186012H04)
MATING
CONNECTORS
CABLE TO PUNCHBLOCK
(CABLE C)
Jun 2004
WALL MOUNTING
BRACKETS (2)
1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU
CABLE TO PUNCHBLOCK
(CABLE C)
4-69
DRAFT
Page 4
Span Line, RGPS, and RF–GPS Cabling – continued
Figure 4-44: RGPS Head
THREADED MOUNT ADAPTER
12–PIN DEUTSCH TYPE MMP
CONNECTOR
4
Connecting the RGPS Cable to
Lightning Arrestor
Figure 4-45 is a detail of the RGPS connections. Figure 4-46 is a detail
of the Lightning Arrestor connections.
Figure 4-45: RGPS to SC480 Connection Diagram
RGPS HEAD (MOTOROLA
P/N 0186012H04)
1
9
10
2
8
11 12
3
RGPS CABLE CONNECTOR
(VIEWED FROM CABLE PERSPECTIVE)
CELL SITE
GROUND =
7
6
4
5
C
LIGHTNING ARRESTOR
(WNP CGDSO971017AA1
OR EQUIVALENT)
UNUSED
Red/Black
Red
C1
CABLE DRAIN
Green/Black
Green
White/Black
White
Brown/Black
Brown
Yellow
Blue/Black
Yellow/Black
Earth Ground
Blue
D–CONNECTOR
TO BTS
9
1
12
4
10
2
8
7
15
14
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Jun 2004
Page 5
Span Line, RGPS, and RF–GPS Cabling – continued
Figure 4-46: RGPS Lightning Arrestor Wiring
C1 (RGPS)
TO BTS
UNIT
EARTH GROUND
Blue/Black
Blue
Yellow/Black
Yellow
Green/Black
Green
White/Black
White
Cable Drain
Red/Black
Red
Brown/Black
Brown
DC
Equipment
DC
Equipment+40V
+17V
DC
Equipment+17V
MOUNTING PLATE
+40V
DC
Lines +17V
DC
Lines +17V
DC
Lines
Blue/Black
Blue
Yellow/Black
Yellow
Green/Black
Green
White/Black
White
Cable Drain
Red/Black
Red
Brown/Black
Brown
C (RGPS)
TO RGPS
RECEIVER
Blue
White/Black
White
Green/Black
Green
Red
Red/Black
Yellow/Black
Blue/Black
Yellow
Brown
Brown/Black
10
11
12
1
2
3
4
5
6
7
8
9
4
Connecting the RF–GPS Cable
Figure 4-47 shows the components of the RF–GPS. The RF–GPS is
connected to the BTS via the RF–GPS module through the RGPS
connector on the CBIO Board. See Figure 4-48.
Procedure
Use the procedure in Table 4-37 to install the RF–GPS system.
Table 4-37: Procedure for Installing RF–GPS Antenna and Cabling
Step Action
1 Determine the mounting location (see RF–GPS Mounting Considerations, Table 6-34).
2 Install the mounting kit at the RF–GPS location of choice. Use the appropriate mounting bolts for
mounting surface.
3
n W ARNING
The roof structure on which the mounting pole is attached should be verified by a qualified structural
engineer for the weight of the RF–GPS engine and mounting hardware or under adverse conditions for
the installation area
Mounting the RF–GPS antenna and hardware to an inadequate roof surface and/or using inadequate
installation methods can result in serious injury.
4 Attach the RF–GPS head assembly to the post mounting assembly and secure the assembly to the
assembly to the mounting kit using the screws and nuts supplied (see Figure 4-47).
Jun 2004
1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU
DRAFT
4-71
Page 6
Span Line, RGPS, and RF–GPS Cabling – continued
Table 4-37: Procedure for Installing RF–GPS Antenna and Cabling
Step Action
5 Attach the grounding kit to the mounting pole.
6 Connect one (1) N connector of the 50–feet superflex cable to the N jack of the RF–GPS antenna cable
and route the other end of the cable down to the frame.
7 If not already done, attach RF–GPS Module to CBIO Board and secure using 4 M4 screws.
8 Route the cable to the RF–GPS connector at the rear of the BTS.
9 Connect cable to RF–GPS connector. See Figure 4-48.
4
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Jun 2004
Page 7
Span Line, RGPS, and RF–GPS Cabling – continued
Figure 4-47: RF–GPS Installation and Components
3/4–IN
CABLE ASSEMBLY
(N–DSK) (12–IN LONG)
(CGDSMCXNJACK)
MOUNTING SHROUD
(CGDSMNT62311)
OUTER GASKET
(CGDSMNT62311)
CABLE RETAINING NUT
(CGDSMNT62311)
4–IN
RUBBER BOOT
(CGDSANT62301)
3–IN
“N” JACK
(CGDSMCXNJACK)
(SEE NOTE 1)
ANTENNA/PREAMP
(CGDSANT62301)
K
(CGDSVXL550)
1/2–IN SCREWS
2”
POST
MOUNTING
ASSEMBLY
(CGDS62312)
CONNECTOR
NOTE:
1. TOTAL WEIGHT FOR GPS ANTENNA
ASSEMBLY – 0.65 LBS.
MOUNTING &
GROUNDING KIT
(CGDS2417071)
“N” JACK
ADJUSTABLE FROM
4
33.5 TO 47–IN
Jun 2004
ROOF
E/K
(FSJ4–50B)
TO BTS
1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU
DRAFT
REF TO
FW00410R
4-73
Page 8
Span Line, RGPS, and RF–GPS Cabling – continued
Figure 4-48: Span and RF–GPS Cabling Details
Customer I/ O
PWR
RF–GPD IN
J
4
D
EXPANSION FRAME SYNC – OUT
DAISY–CHAIN POWER
SDCX POWER
SDCX KIT NO.
SDCX SERIAL NO.
Connecting MCC–DO
4-74
1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU
DAISY–CHAIN SYNC – OUT
ti–cdma–wp–00311–v01–ildoc–ah
At the front of the BTS under the CCP2 Shelf, there are two ethernet
connectors for MCC–DO use: Single and Dual. The connections can be
made with standard ethernet cables. The MCC–DO card provides for
three MCC–DO span lines (See Figure 4-49). Refer to 1X EV–DO
Hardware Installation manual – 68P09257A95 for further information.
Jun 2004
DRAFT
Page 9
Span Line, RGPS, and RF–GPS Cabling – continued
Figure 4-49: EV–DO Connections
NOTE:
MCC–DO card occupies MCC
slots 1 & 2.
4
SPARE
BPR A BPR B AUX
19MHz EVEN
GLI
RESET
RESET ALARM MMI
MMI
MMI
GROUP 1 SPAN
DUAL SINGLE
PWR/ALM
ACTIVE
ACTIVE
SINGLE
DUAL
GRP1
SPAN
GRP2
SPAN
GRP3
SPAN
ENET
ENET
TAT
ACT
ACTIVE
PWR/ALM
LAN A LAN B
PWR/ALM
PWR/ALM
SYSTEM
STATUS
MCC–DO Span Line
Connections
Ethernet Connections
ti–cdma–wp–00326–v01–ildoc–ah
Jun 2004
1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU
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4-75
Page 10
Customer Input / Output Cables
Introduction
The objective of this procedure is to attach the ferrite core onto the
customer input and output cables.
Cable Descriptions and Part
Numbers
Table 4-38 gives the cable descriptions and part numbers used to install
the Customer I/O connectors.
Table 4-38: Cable Descriptions and Part Numbers
Cable Qty. Part Number Description
4
E 1 Customer
Supplied
4 Molex, terminal
plugs, P/N
39352–0106
2 Molex, terminal
plugs, P/N
39352–0108
3 Motorola P/N
7687717T02
1–3 Customer
Supplied
Customer Input and Output
Connector Pinouts
Customer Input/Output cable, 0–8 conductor, 18–24 AWG, stranded
wire
Connector, 6 pin
Connector, 8 pin
Core, Ferrite
Tie–wrap
Input Pinouts
Table 4-39 lists the pinouts for the Customer Input connectors.
4-76
Table 4-39: Customer Input Connector Pinouts
Pin Number Description
1 Customer Input 1/5
2 Customer Input 1/5 Return
3 Customer Input 2/6
4 Customer Input 2/6 Return
5 Customer Input 3/7
6 Customer Input 3/7 Return
table continued on next page
1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU
DRAFT
Jun 2004
Page 11
Site Cleanup – continued
Table 4-39: Customer Input Connector Pinouts
Pin Number Description
7 Customer Input 4/8
8 Customer Input 4/8 Return
Output Pinouts
Table 4-40 lists the pinouts for the Customer Output connectors.
Table 4-40: Customer Input Connector Pinouts
Pin Number Description
1 Customer Output 1/3/5/7 NC
2 Customer Output 1/3/5/7 C
3 Customer Output 1/3/5/7 NO
4 Customer Output 2/4/6/8 NC
5 Customer Output 2/4/6/8 C
6 Customer Output 2/4/6/8 NO
Procedure
Follow the procedure in Table 4-41 to attach a ferrite core.
Table 4-41: Procedure for Using Ferrite Core on Customer Input and Output Wires
Step Action
1 Route Customer I/O cables from termination equipment to rear of BTS and connect.
2 At the rear of the BTS, just below the top, are three pairs of connectors for customer defined inputs
and outputs. See Figure 4-48.
4
3 Connect the cable for Customer Outputs 1 and 2 to BTS connector CUST. OUTPUT 1–2.
Perform the same for the remaining connectors.
4 After connections are made, bundle the wires of CUST. OUTPUT 1–2 and CUST. OUTPUT 3–4
together and place a ferrite core around them. Ensure that the wires will not be pinched prior to
closing and latching the ferrite core.
5 Slide ferrite core as close to the BTS connectors as possible without causing stress. Use a tie–wrap on
the ferrite core side away from the BTS connectors to hold the ferrite core in place.
6 Perform step 4 and step 5 for CUST. OUTPUT 5–6 and CUST. OUTPUT 7–8 and CUST. INPUT
1–4 and CUST. INPUT 5–8.
Jun 2004
1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU
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4-77
Page 12
Site Cleanup
Remove Protective Covering
Lighting Fixtures
Tools
Remove any anti–static plastic or cloth sheeting that was used to cover
the equipment.
Remove the masking tape from the fluorescent light fixtures.
Place all hand and power tools in the installation tool kit or other
appropriate place. Note any tools that need replacement, cleaning, or
adjustment.
4
Materials
Place any leftover materials in a location specified by the site manager.
Remove Debris
Remove any packing material.
Ensure that all scrap materials have been removed from any tables or
stands.
Clean/sweep the area. Ensure that all alignment marks have been
removed.
Environment
Remove any temporary weather protection used for installation.
Check that the power connections are tight.
Organize any items (manuals, materials, etc.) left on site and place them
in a location specified by the site manager.
Check that the unit lock is secure and key is removed.
Verify that cabling is properly secured between unit and enclosures.
4-78
1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU
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Jun 2004
Page 13
Installation Completion Checklist
Directions
Fill out the installation completion checklist and make any necessary
copies. You may copy this check sheet as needed.
Indoor Installation Completion
Checklist
Date Hardware Installation Completed: ________________________
Site:_______________________________________________________
Serial Number(s):__________________________
__________________________________________________________
Checklist Completed By:_____________________________________
Checklist Reviewed By:______________________________________
Table 4-42: Indoor Installation Completion Checklist
Status No. Item Notes
4
1 Equipment is not damaged.
2 Air flow clearance requirements are met.
3 Mounting plate is level and secure. (Indoor)
4 BTS is securely mounted to plate and rack.
(Indoor)
5 TME is securely mounted to wall or pole.
(Outdoor)
6 PDM is installed and cabled within TME.
(Outdoor)
7 BTS is securely mounted within the TME.
(Outdoor)
8 BTS is correctly cabled to TME.
9 1U Module is installed and cabled to TME (If
used).
10 HMS is securely mounted to TME. (Outdoor)
11 HMS is cabled to TME. (Outdoor)
12 PDE is securely mounted to wall or pole.
(outdoor)
Jun 2004
13 HX is securely mounted to PDE. (Outdoor)
14 HX is cabled to PDE. (Outdoor)
15 TME, PDE, and cCLPA are grounded.
(Outdoor)
1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU
DRAFT
table continued next page
4-79
Page 14
Installation Completion Checklist – continued
Table 4-42: Indoor Installation Completion Checklist
Status NotesItemNo.
16 TME is cabled to PDE and cCLPA through
conduit and conduit hubs on TME are tight.
17 PDE is cabled to TME through conduit and
conduit hubs on PDE are tight.
18 cCLPA is cable to TME through conduit and
and conduit hubs on cCLPA are tight.
19 Conduit is sufficiently grounded.
20 200–240 VAC is connected to PDE.
4
21 Battery backups (if used) are connected to the
PDE.
22 TME DC power cable is connected (through
conduit) to PDE (Outdoor)
23 cCLPA DC power cable is connected through
conduit) to PDE
24 RGPS head and mast are secure.
25 RGPS head has a clear view of the sky and is
not in a location which accumulates debris.
Make sure the RGPS is located away from
the BTS transmit antenna.
26 Local GPS antenna is secure. (If used)
27 Local GPS cabling is installed (If used).
28 Mounting rack is isolated from the Master
ground. (Indoor)
29 cCLPA is securely mounted to rack (if in
use). (Indoor)
30 Compact BTS connection to the DC source is
secure. (Indoor)
4-80
31 cCLPA connection to its DC source is secure.
(Indoor)
32 The antenna connections are secure.
33 The antenna cables are protected by lightning
arrestors (if applicable).
34 Span and RGPS connections are protected by
lightning arrestors (if applicable).
35 The RGPS ground lead is connected to the
BTS digital ground reference.
1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU
DRAFT
table continued next page
Jun 2004
Page 15
Installation Completion Checklist – continued
Table 4-42: Indoor Installation Completion Checklist
Status NotesItemNo.
36 Installation hardware is removed.
37 The earth ground connections are secure
between the earth ground and the Compact
BTS. (Indoor)
38 The DC input cable is securely attached to the
DC input connector. (Indoor)
39 The BTS–to–cCLPA cabling is secure (if
applicable) (Indoor)
40 cCLPA connection to earth ground is secure
(if cCLPA in use). (Indoor)
41 The antenna N–type connectors are securely
attached to the antenna A and B connectors
(if applicable). (Indoor)
4
42 All unused ports on BTS and/or cCLPA are
properly terminated. (Indoor)
43 All cables are dressed and tied. (Indoor)
44 Power, Span, Customer I/O, PA, RGPS, and
DO cables to the BTS have a ferrite core
attached and tie–wrapped in place.
45 The external power source (DC) is active.
(Indoor)
46 AC power source is active. (Outdoor)
47 The circuit breaker on the BTS is disengaged
(Pulled out).
48 Circuit breakers are disengaged (Pulled out)
on TME PDM. (Outdoor)
49 Circuit breakers are disengaged (Pulled out)
on PDE. (Outdoor)
50 Circuit breaker is disengaged (Pulled out) on
cCLPA.
51 The site is cleaned, swept and trash removed.
Jun 2004
52 The site specific documentation is present at
the site.
1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU
DRAFT
4-81
Page 16
Installation Completion Checklist – continued
Notes
4
4-82
1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU
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Jun 2004
Page 17
Chapter 5: Power Installation
Table of Contents
Frame Configuration DIP Switch 5-1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Introduction 5-1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Setting Frame Configuration DIP Switch 5-1 . . . . . . . . . . . . . . . . . . . . . . .
Expansion Frame DIP Switch Settings 5-2 . . . . . . . . . . . . . . . . . . . . . . . . .
Expansion 1 Frame DIP Switch 5-3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Expansion 2 Frame DIP Switch 5-3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Expansion 3 Frame DIP Switch 5-3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Pre–Power Up Test (Indoor) 5-4 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Objective 5-4 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Power for EV–DO 5-4 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Test Equipment 5-4 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Cabling Inspection 5-4 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
DC Power Pre–Test 5-4 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
cCLPA DC Power Pre–Test 5-5 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5
AC Power Input (Outdoor Configuration) 5-7 . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Objective 5-7 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Test Equipment 5-7 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Cabling Inspection 5-7 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Battery Backup DC Power Input (Outdoor Configuration) 5-9 . . . . . . . . . . . . . . . .
Objective 5-9 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Cable Descriptions and Part Numbers 5-9 . . . . . . . . . . . . . . . . . . . . . . . . . .
Test Equipment 5-9 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Tools Required 5-9 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Cabling Inspection 5-9 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Initial Power–Up Test 5-11 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Initial Power–Up Tests 5-11 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Outdoor Configuration Initial Power Test 5-12 . . . . . . . . . . . . . . . . . . . . . . .
Remove Power 5-14 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Removing BTS Power 5-14 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Removing cCLPA Power 5-14 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Removing PDE Power 5-14 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Jun 2004 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU
DRAFT
Page 18
Table of Contents – continued
Notes
5
1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU Jun 2004
DRAFT
Page 19
Frame Configuration DIP Switch
Introduction
This section describes setting the DIP switch positions for starter/single
frame and exapansion frames. The following sections describe BTS
preparation before applying DC power.
Setting Frame Configuration
DIP Switch
The frame configuration switch is located on the Compact BTS
Input/Output (CBIO) Card of the BTS. Figure 5-1 shows the switch
position for a starter /single frame configuration. If there are expansion
frames, then each would have the DIP switch positions set to reflect that
frames identification. See Figure 5-2.
The switch settings must be verified and set before power is applied to
the BTS. Refer to Figure 5-1 or Table 5-1 for a starter or single frame.
Figure 5-1: DIP Switch Configuration
PWR
RF–GPS IN
EXPANSION FRAME SYNC – OUT
SDCX POWER
DAISY–CHAIN SYNC – OUT
DAISY–CHAIN
POWER
5
Frame ID
1 2 3 4
UP
DN
3rd and 4th Positions
– Don’t Care
Note:
Black represents Switch Actuator
SDCX
KIT NO.
SDCX
SERIAL NO.
Jun 2004 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU 5-1
DRAFT
Page 20
Frame Configuration DIP Switch – continued
Table 5-1: Frame ID Switch Position – Single/Starter Frame
1 2 3 4
UP UP –– ––
–– = Don’t Care. These switch positions do not affect the BTS.
Expansion Frame DIP Switch
Settings
Figure 5-2 shows the switch position for the expansion frames.
Figure 5-2: Expansion Frames DIP Switch Configuration
Expansion 1
1 2 3 4
5
PWR
RF–GPS IN
UP
DN
Expansion 2
1 2 3 4
UP
DN
EXPANSION FRAME SYNC – OUT
DAISY–CHAIN
POWER
SDCX POWER
DAISY–CHAIN SYNC – OUT
SDCX
KIT NO.
SDCX
SERIAL NO.
UP
Expansion 3
1 2 3 4
DN
Note:
Black represents Switch Actuator
3rd and 4th Positions
– Don’t Care
5-2 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU Jun 2004
DRAFT
Page 21
Frame Configuration DIP Switch – continued
Expansion 1 Frame DIP Switch
The switch settings must be verified and set before power is applied to
the BTS. Refer to Figure 5-2 or Table 5-2 for the expansion 1 frame.
Table 5-2: Frame ID Switch Position – Expansion 1 Frame
1 2 3 4
DN UP –– ––
–– = Don’t Care. These switch positions do not affect the BTS.
Expansion 2 Frame DIP Switch
The switch settings must be verified and set before power is applied to
the BTS. Refer to Figure 5-2 or Table 5-3 for Expansion 2 frame.
Table 5-3: Frame ID Switch Position – Expansion 2 Frame
1 2 3 4
Expansion 3 Frame DIP Switch
UP DN –– ––
–– = Don’t Care. These switch positions do not affect the BTS.
The switch settings must be verified and set before power is applied to
the BTS. Refer to Figure 5-2 or Table 5-4 for Expansion 3 frame.
Table 5-4: Frame ID Switch Position – Expansion 3 Frame
1 2 3 4
DN DN –– ––
–– = Don’t Care. These switch positions do not affect the BTS.
5
Jun 2004 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU 5-3
DRAFT
Page 22
Pre–Power Up Test (Indoor)
Objective
Power for EV–DO
Test Equipment
This procedure check for any electrical problems and verifies the
operation and tolerances of the cell site BTS power supply prior to
applying power for the first time.
Information for applying power to a BTS equipped with EV–DO
(MCC–DO) can be found in 1xEV–DO Hardware Installation manual –
68P09257A95
The following test equipment is required to perform the Pre–Power Up
test:
S Digital Multimeter (DMM)
CAUTION
5
Cabling Inspection
Using the site specific documentation generated by Motorola Systems
Engineering, verify that the following cable systems are properly
connected:
Before handling any circuit cards or modules, be sure to
wear a grounding strap to prevent damage from ESD.
S DC Power cabling
S Receive RF cabling
S Transmit RF cabling
S GPS
DC Power Pre–T est
Perform the procedure Table 5-5 in before applying any power to the
BTS.
Table 5-5: BTS DC Pre–Power Test
Step Action
* IMPORTANT
When handling circuit boards and modules, be sure to wear a grounding strap to prevent damages
caused by ESD.
1 Remove front panel cover.
2 Unseat all circuit boards and modules, but do not remove them from their slots.
table continued on next page
5-4 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU Jun 2004
DRAFT
Page 23
Pre–Power Up Test (Indoor) – continued
Table 5-5: BTS DC Pre–Power Test
Step Action
3 At the rear of the BTS, verify that 20 or 25 A circuit breaker is OFF (pulled out). See Figure 5-3 or
Figure 1-8.
4 Use a DMM (set to ohms) and verify the resistance on the +27V bus.
– Remove the Power Supply Module from the CCP2 Shelf
– Verify that the resistance from the power (+) feed terminal with respect to ground measures > 500
W
See Figure 5-3
– Verify that the resistance from the power (–) feed terminal with respect to ground measures > 500
W
See Figure 5-3
– The resistance measurement should not read 0 (zero).
5 Re–seat all circuit boards into their slots
6 Install the Power Supply Module into its slot.
7 Install front panel cover.
Figure 5-3: Location of Circuit Breaker
Circuit Breaker
25A
25
5
GROUND Location
(Screw Holes)
DC Power
Terminal Strip
cCLPA DC Power Pre–Test
Perform the procedure Table 5-6 in before applying any power to the
cCLPA.
Jun 2004 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU 5-5
DRAFT
Page 24
Pre–Power Up Test (Indoor) – continued
Table 5-6: cCLPA DC Pre–Power Test
Step Action
1 Ensure that DC power is disengaged at the source. Verify that the DC power cable has been connected
using the procedure in Table 4-8.
2 Remove I/O panel cover.
3 At the bottom of the cCLPA, verify that 25 A circuit breaker to OFF (pulled out). See Figure 5-4.
4 Us a DMM (set to ohms) and verify the resistance on the +27 V bus.
– Verify that the resistance from the power (+) feed terminal with respect to ground measures > 500
W
– Verify that the resistance from the power (–) feed terminal with respect to ground measures > 500
W
The resistance measurement should not read 0 (zero).
5 Proceed to Initial Power up procedure in Table 5-11.
5
Figure 5-4: Bottom View of cCLPA
25A FUSE
for +27 V
ti–cdma–wp–00298–v01–ildoc–ah
5-6 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU Jun 2004
DRAFT
Page 25
AC Power Input (Outdoor Configuration)
Objective
The objective of this procedure is to verify the AC power for the
Compact BTS outdoor configuration.
Test Equipment
The following test equipment is required to perform the Pre–Power Up
test:
S Digital Multimeter (DMM) or equivalent
Cabling Inspection
Using the site specific documentation generated by Motorola Systems
Engineering, verify that the following cable systems are properly
connected:
S AC Power cabling
S DC Power Cabling
AC power was installed per manufacturer’s installation procedure.
Perform the procedure Table 5-7 in before applying any power to the
TME and cCLPA.
Table 5-7: PDE Initial Power –Up Test
Step Action
* IMPORTANT
To avoid extensive re–work of the PDE and BTS connections, this procedure should be performed
after the PDE and TME are mounted in place.
n W ARNING
This equipment uses dangerous voltages and is capable of causing death. Failure to observe this
Warning could result in electrical shock to personnel and damage to equipment. The AC voltage
source should be isolated and locked, and a clearly visible, Warning label attached.
1 Verify that AC power from the source is OFF.
2 If not already done, remove safety shield covering AC terminal block.
3 Connect AC power cable to AC power source.
4 Verify that PDE DC circuit breakers are set to “O” or pulled out (disengaged).
5 Verify that AC power cable is securely connected to PDE AC terminal block.
5
6 Turn on AC power source.
n W ARNING
This equipment uses dangerous voltages and is capable of causing death. Failure to observe this
Warning could result in electrical shock to personnel and damage to equipment. Do not wear jewelry
on hands/fingers when making electrical measurements.
table continued on next page
Jun 2004 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU 5-7
DRAFT
Page 26
AC Power Input (Outdoor Configuration) – continued
Table 5-7: PDE Initial Power –Up Test
Step Action
7 Using a DMM set toVAC, measure the voltage at the AC terminal block. DMM should indicate
200–240 VAC. Adjust AC voltage as necessary.
8 Remove DMM.
9 If there is nothing further to do, replace safety shield. Secure to cabinet with 2 nuts and washers. Use
an adjustable wrench to tighten nuts. Torque nuts to 3.4 N–M (20 in–lbs).
5
5-8 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU Jun 2004
DRAFT
Page 27
Battery Backup DC Power Input (Outdoor Configuration)
Objective
The objective of this procedure is to verify the Battery Backup DC
power for the Compact BTS outdoor configuration.
Cable Descriptions and Part
Numbers
Table 5-8 gives the cable description and part number for the
recommended cable. Consult manufacturer’s installation guide for
further information.
Table 5-8: Cable Descriptions and Part Numbers
Cable Qty. Part Number Description
{
L 1 Customer
Supplied
{
Length of cables are dependent upon BTS equipment layout.
DC power cables, 10 AWG, stranded, designed for +20 to +34 VDC
power input
Test Equipment
The following test equipment is required to perform the Pre–Power Up
test:
S Digital Multimeter (DMM) or equivalent
Tools Required
Relatively small, flat head, screwdriver or equivalent.
Cabling Inspection
Using the site specific documentation generated by Motorola Systems
Engineering, verify that the following cable systems are properly
connected:
S AC Power cabling
S DC Power Cabling
Battery Backup has been installed per the manufacturer’s installation
procedure.
Following the procedure in Table 5-9 to verify Battery Backup DC
power is present.
Table 5-9: Procedure to Verify Battery Backup DC Power Test
Step Action
5
n W ARNING
Do not wear a grounding device or metal of any kind on hands/fingers when working with voltage.
injury to personnel and damage to equipment could occur.
1 Verify that Battery Backup DC Power is disengaged.
table continued on next page
Jun 2004 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU 5-9
DRAFT
Page 28
Battery Backup DC Power Input (Outdoor Configuration) – continued
Table 5-9: Procedure to Verify Battery Backup DC Power Test
Step Action
2 If not already done, connect Battery Backup DC power cable to batteries.
3 If not already done, remove safety shield covering DC terminal block.
4 Verify that Battery Backup DC power cable is securely connected to DC terminal block of PDE.
5 Verify that circuit breakers on PDE front panel are disengaged (pulled out or set to “O” (OFF)).
6 Turn on Battery Backup source.
7 Using a DMM set to VDC, measure the voltage at the DC terminal block. DMM indicates VDC in the
range +20 to +34 VDC.
8 Remove DMM.
9 If there is nothing further to do, replace safety shield. Secure to cabinet with 2 nuts and washers. Use
an adjustable wrench to tighten nuts. Torque nuts to 3.4 N–M (20 in–lbs).
5
5-10 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU Jun 2004
DRAFT
Page 29
Initial Power–Up Test
Initial Power–Up Tests
WARNING
Potentially lethal voltage and current levels are present in
the Compact BTS. This test must NOT be performed
without a second person present capable of administering
emergency medical treatment. Remove all decorative metal
before beginning this test. Do NOT wear a grounding strap
when performing voltage measurements.
BTS Initial Power–Up
Perform the procedure in Table 5-10 to verify input power. Once power
has been applied the cards and modules within the BTS should begin
operating within specifications.
Table 5-10: Procedure for BTS Initial Power–Up
Step Action
NOTE
If the BTS is being utilized in an outdoor configuration, perform this procedure after the TME has
been verified as operational.
1 Ensure that DC power source is OFF.
2 Connect DC power to BTS DC Power input.
3 Turn on DC power source.
4 Use a DMM (set to VDC) to verify the +27 V power output is within +20 to +34 VDC)
5 On the BTS, set the 25 A circuit breaker to ON (push in). See Figure 5-3.
6 If not already done, install the fan module, note that the fan module begins operating. Feel for air
movement at the exhaust vent on top of the BTS.
7 Ensure that all circuit boards and modules are seated and locked into their associated slots.
cCLPA Initial Power –Up
Perform the procedure in Table 5-11 to perform the initial power–up.
Table 5-11: Procedure cCLPA Initial Power–Up
Step Action
5
NOTE
If the cCLPA is being utilized in an outdoor configuration, perform this procedure after the PDE has
been verified as operational.
1 Ensure that DC power source is OFF.
table continued on next page
Jun 2004 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU 5-11
DRAFT
Page 30
Initial Power–Up Test – continued
Table 5-11: Procedure cCLPA Initial Power–Up
Step Action
2 If not already done, remove cCLPA I/O panel cover.
3 Connect DC power to cCLPA I/O board DC terminal block.
4 Turn on DC power source.
5 Using a DMM (set to VDC), measure the voltage at the cCLPA I/O board terminal block.
DC voltage should measure in the range of +20 to +34 VDC. Adjust DC power source as necessary.
6 Remove DMM and install I/O panel cover.
7 On the cCLPA, push in 20 A circuit breaker.
Outdoor Configuration Initial
Power T est
TME Initial Power–Up
5
Step Action
Perform the procedure Table 5-12 in before applying any power to the
BTS and HMS.
Table 5-12: TME DC Initial Power–Up Test
* IMPORTANT
To avoid extensive re–work of the TME and BTS connections, this procedure should be performed
after the TME with BTS is mounted in place.
NOTE
Perform this procedure after the PDE has been verified as operational.
1 Verify that DC power from the PDE is OFF.
2 If not already done, route DC power cable from PDE through conduit to TME.
3 If not already done, remove protective cover from voltage connection on PDA.
4 Use a Phillips screw driver to remove screws from DC power connector on PDA.
5 Set lug of “–” wire in the RTN location and secure with screw.
6 Set lug of “+” wire in the +27 VDC location and secure with screw.
7 Verify that 1U and TME circuit breakers on PDA are disengaged (pulled out).
8 Turn on PDE supplying the TME.
9 Using a DMM set to VDC, measure the voltage at the PDA connector. DMM should indicate +20 to
+34 VDC.
10 If not already done, connect PDA to HMS Controller (D–connector)
table continued on next page
5-12 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU Jun 2004
DRAFT
Page 31
Initial Power–Up Test – continued
Table 5-12: TME DC Initial Power–Up Test
Step Action
11 If not already done, connect PDA to BTS. (Three appropriately marked cables .)
12 Engage (push in) TME circuit breaker on PDA.
NOTE
Fans on HMS and BTS begin to operate. With TME cable connected the controller for the HMS and
BTS is bypassed, and DC power is supplied as long as the TME circuit breaker is engaged.
13 Using a DMM set to VDC, measure the voltage at the BTS DC Input connector. DMM should indicate
+20 to +34 VDC.
14 Using a DMM set to VDC, measure the voltage at the HMS Controller connector. DMM should
indicate +20 to +34 VDC.
15 If the 1U connector is being used, engage 1U circuit breaker (push in), use a DMM set to VDC to
measure the voltage at the 1U unit connector. DMM should indicate +20 to +34 VDC.
NOTE
If 1U connector is not in use, do not measure at this time.
5
Jun 2004 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU 5-13
DRAFT
Page 32
Remove Power
Removing BTS Power
Perform the procedure in Table 5-13, if power must be removed from the
BTS.
Table 5-13: Procedure to Remove Power to BTS
Step Action
1 For indoor configuration, set the 25 A circuit breaker to OFF (pulled out). See Figure 5-3.
For outdoor configuration, open TME and set circuit breaker on PDA to “O”.
Set TME circuit breaker on PDE to OFF.
2 Confirm all LEDs are OFF.
3 If possible, for added safety, locate circuit breaker of DC power source (PDE or Battery Backup) and
set it to OFF.
Removing cCLP A Power
5
Table 5-14: Procedure to Remove Power to cCLPA
Step Action
1 Set the 20A circuit breaker to OFF (pulled out). See Figure 5-4.
2 For indoor configuration, turn off DC power source.
For outdoor configuration, pull cCLPA circuit breaker on PDE out.
3 Turn off Battery backup DC power (if used).
Removing PDE Power
Table 5-15: Procedure to Remove Power to PDE
Step Action
Perform the procedure in Table 5-14, if power must be removed from the
cCLPA.
Perform the procedure in Table 5-15, if power must be removed from the
PDE.
1 Turn off AC power source.
2 Turn off Battery Backup DC power (if used).
5-14 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU Jun 2004
DRAFT
Page 33
Chapter 6: Optimization and Calibration
Table of Contents
Preliminary Operations: Overview 6-1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Introduction 6-1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Cicruit Backhaul Operation 6-1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Packet Backhaul Operation 6-1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Cell–site Types 6-1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
CDF/NECF 6-1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Site Equipage Verification 6-2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Initial Installation of Boards/Modules 6-2 . . . . . . . . . . . . . . . . . . . . . . . . . .
Ethernet LAN 6-3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Ethernet LAN Termination 6-3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Introduction to Optimization and Calibration 6-4 . . . . . . . . . . . . . . . . . . . . . . . . . .
Overview 6-4 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Optimization Process Summary 6-4 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Cell-site Types 6-5 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
CDF/NECF 6-5 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
BTS System Software Download 6-6 . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Site Equipage Verification 6-6 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6
Preparing the LMF 6-7 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Overview of Packet BTS files 6-7 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
WinLMF Features and Installation Requirements 6-8 . . . . . . . . . . . . . . . . .
WinLMF File Structure Overview 6-9 . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
WinLMF Home Directory 6-9 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
NECF Filename Conventions and Directory Location 6-10 . . . . . . . . . . . . .
WinLMF Operating System Installation 6-11 . . . . . . . . . . . . . . . . . . . . . . . .
Copy BTS CDF (or NECF) and CBSC CDF Files to the
WinLMF Computer 6-12 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Creating a Named HyperTerminal Connection for MMI
Communication 6-14 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Span Lines – Interface and Isolation 6-16 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
T1/E1 Span Interface 6-16 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Isolate BTS from T1/E1 Spans 6-16 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
T1/E1 Span Isolation 6-16 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
LMF to BTS Connection 6-17 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Connect the WinLMF to the BTS 6-17 . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Using the LMF 6-18 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Basic LMF Operation 6-18 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Jun 2004 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU
DRAFT
Page 34
Table of Contents – continued
The LMF Display and the BTS 6-19 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Graphical User Interface Overview 6-19 . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Understanding GUI Operation 6-19 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Command Line Interface Overview 6-24 . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Logging Into a BTS 6-25 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Logging Out 6-28 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Establishing an MMI Communication Session 6-30 . . . . . . . . . . . . . . . . . . .
Online Help 6-32 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Pinging the Processors 6-33 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Pinging the BTS 6-33 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Pinging the Processors 6-34 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Download the BTS 6-36 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Overview 6-36 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
ROM Code 6-36 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
RAM Code 6-36 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Verify GLI ROM Code Loads 6-38 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Download RAM Code and Data to GLI 6-39 . . . . . . . . . . . . . . . . . . . . . . . .
Download RAM Code and Data to Non–GLI Devices 6-39 . . . . . . . . . . . . .
Selecting CSA Clock Source and Enabling CSAs 6-40 . . . . . . . . . . . . . . . .
Enable MCCs 6-42 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
CSA System Time – GPS & HSO/MSO Verification 6-43 . . . . . . . . . . . . . . . . . . . .
Clock Synchronization and Alarm (CSA) Sub–system
Description 6-43 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Front Panel LEDs 6-43 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6
Test Equipment Setup 6-51 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Test Set Calibration 6-65 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
High Stability Oscillator / Medium Stability Oscillator
(HSO/MSO) 6-44 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
CSA Frequency Verification 6-45 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Test Equipment Setup
(GPS & HSO/MSO Verification) 6-45 . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
GPS Initialization/Verification 6-46 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Connecting Test Equipment to the BTS 6-51 . . . . . . . . . . . . . . . . . . . . . . . .
Supported Test Equipment 6-51 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Equipment Warm-up 6-55 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Background 6-65 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Calibration Procedures Included 6-65 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
GPIB Addresses 6-66 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Selecting Test Equipment 6-66 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Manually Selecting Test Equipment in a Serial Connection Tab 6-67 . . . . .
Automatically Selecting Test Equipment in the Serial Connection Tab 6-68
Calibrating Test Equipment 6-68 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Calibrating Cables Overview 6-69 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Calibrating Test Cable Configurations with a Communications System Analyzer
6-70
Calibrate Test Cabling Using Signal Generator & Spectrum
Analyzer 6-71 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU Jun 2004
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Table of Contents – continued
Setting Cable Loss Values 6-73 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Setting TX and RX Directional Coupler Loss Value 6-74 . . . . . . . . . . . . . .
Bay Level Offset Calibration 6-76 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Purpose of Bay Level Offset Calibration 6-76 . . . . . . . . . . . . . . . . . . . . . . . .
What is BLO Calibration? 6-76 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Component Verification During Calibration 6-76 . . . . . . . . . . . . . . . . . . . . .
When to Calibrate BLOs 6-76 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
BLO Calibration Data File 6-77 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
BLO for Expansion BTS 6-78 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Test Equipment Setup for RF Path Calibration 6-78 . . . . . . . . . . . . . . . . . .
Transmit (TX) Path Calibration Description 6-79 . . . . . . . . . . . . . . . . . . . . .
TX Calibration and the LMF 6-80 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Set-up for TX Calibration 6-81 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
TX Calibration 6-82 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
All Cal/Audit and TX Calibration Procedure 6-82 . . . . . . . . . . . . . . . . . . . .
Download BLO Procedure 6-84 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Calibration Audit Introduction 6-85 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
TX Path Audit 6-85 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
TX Audit Test 6-85 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Create CAL File 6-87 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6
Jun 2004 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU
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Table of Contents – continued
Notes
6
1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU Jun 2004
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Page 37
Preliminary Operations: Overview
Introduction
This section first verifies proper frame equipage against the site-specific
documentation supplied for each BTS application.
Cicruit Backhaul Operation
If circuit backhaul operation is being used, perform the procedures
described in this chapter. Refer to the LMF Help, if further information
is needed.
Packet Backhaul Operation
If packet backhaul configuration is being used, perform the procedures
described in Appendix I.
Peform the IBR procedures described in Appendix G and Appendix H if
GLI3 data load and span parameters need to be verified.
Cell–site Types
CDF/NECF
The site is configured as Omni with one carrier. The BTS can handle two
carriers.
The Configuration Data File (CDF) or Network Element Configuration
File (NECF) contains information that defines the BTS and data used to
download files to the devices. The BTS CDF (bts–#.cdf) and CBSC
CDF (cbsc–#.cdf) files are used by circuit BTSs. The NEC Base
(NECB – NECB*bts#.xml ) and NEC Journaling (NECJ–
NECJ*bts#.xml ) files are used by packet BTSs. CDF or NEC files
must be placed in the applicable BTS folder before the LMF can be used
to log into that BTS. CDF and NEC files are normally obtained from the
CBSC using a floppy disk. A file transfer protocol (ftp) method can be
used if the LMF computer has that capability.
The CDF and NEC files include the following information:
S Download instructions and protocol
S Site specific equipage information
S CCP2 Shelf allocation plan
– BBX equipage
– CSA equipage
– MCC–1X (16, 24,32, 64) channel element allocation plan. This plan
indicates how the CCP2 shelf is configured, and how paging,
synchronization, traffic, and access channel elements (and
associated gain values) are assigned among the (up to 3) MCC–1Xs
in the shelf.
6
JUN 2004
S CSA equipage
1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU
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6-1
Page 38
Preliminary Operations: Overview
S Effective Rate Power (ERP) table for all TX channels to antennas
respectively. Motorola System Engineering specifies the ERP of a
transmit antenna based on the site geography, antenna placement, and
government regulations. Working from this ERP requirement, the
antenna gain, (dependent on the units of measurement specified) and
antenna feed line loss can be combined to determine the required
power of the BTS. The corresponding BBX–1X output level required
to achieve that power level on any channel/sector can also be
determined.
NOTE
Refer to the LMF Help function on–line documentation for
additional information on the layout of the LMF directory
structure (including CDF or NEC file locations and
formats).
Site Equipage Verification
Review the site documentation. Match the site engineering equipage data
to the actual boards and modules shipped to the site. Physically inspect
and verify the equipment provided for the frame.
CAUTION
Always wear an approved anti–static wrist strap while
6
Initial Installation of
Boards/Modules
Table 6-1: Initial Installation of Boards/Modules
Step Action
1 Refer to the site documentation and, if it was not previously done, slide all boards and modules into
the appropriate shelves as required. DO NOT SEAT the boards and modules at this time.
handling any circuit card/module to prevent damage by
ESD. After removal, the card/module should be placed on
a conductive surface or back into the anti–static packaging
in which it was shipped.
2 As the actual site hardware is installed, record the serial number of each module on a “Serial Number
Checklist” in the site logbook.
6-2
1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU
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Page 39
Ethernet LAN
Ethernet LAN Termination
Figure 6-1: LAN Connectors
Front Panel
For proper operation, the BTS Ethernet Local Area Network (LAN)
connections must be terminated with a 50–ohm loads. This is done by
placing four (4) 50–ohm BNC terminations on the LAN A and B
external IN and OUT connectors located on the rear of the BTS. This is
only done on stand–alone BTSs. The front panel LAN connections are
not terminated with loads.
Verify that the LAN A and B external IN and OUT connectors at the rear
of the BTS have terminations installed. See Figure 6-1 for locations.
P/O Rear Panel
Rear Panel LAN Connectors
PWR/ALM
ACTIVE
PWR/ALM
ACTIVE
ACTIVE
PWR/ALM
ACTIVE
PWR/ALM
6
PWR/ALM
PWR/ALM
BPR A BPR B AUX
19MHz EVEN
GLI
RESET
RESET ALARM MMI
MMI
MMI
ACTIVE
LAN A & B
Connections
LAN A LAN B
JUN 2004
1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU
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6-3
Page 40
Introduction to Optimization and Calibration
Overview
This section describes procedures for isolating the BTS from the span
lines, preparing and using the WinLMF, downloading system operating
software, CSA reference verification/optimization, set up and calibration
of the supported test equipment, and transmit/receive paths are
functioning properly.
NOTE
Before using the WinLMF, use an editor to view the
“CAVEATS” section in the “readme.txt” file in the c:\wlmf
folder for any applicable information.
Optimization Process
Summary
After a BTS is physically installed and the preliminary operations, such
as power up, have been completed, the WinLMF is used to optimize the
BTS. The basic optimization process consists of the following:
1. Download GLI3 (GLI–bts#–1) with application code and data and
then enable GLI3.
2. Use the WinLMF status function and verify that all of the installed
devices of the following types respond with status information:
CSA, BBX, GLI3, and MCC. If a device is installed and powered up
6
but is not responding and is colored gray in the BTS display, the
device is not listed in the CDF file. The CDF/NECF file must be
corrected before the device can be accessed by the WinLMF.
3. Download device application code and data to all devices of the
following types:
– CSA
– BBX–1X
– MCC–1X
4. Verify the operation of the GPS and HSO/MSO signals.
5. Using the WinLMF test equipment selection function, select the test
equipment to be used for the calibration.
6. Calibrate the TX and RX test cables if they have not previously been
calibrated with the WinLMF computer and software build which will
be used for the optimization/calibration. Cable calibration values can
be entered manually, if required.
7. Connect the required test equipment for a full optimization.
8. Select all of the BBXs and all of the MCCs and use the full
optimization function. The full optimization function performs TX
calibration, BLO download, TX audit, all TX tests, and all RX tests
for all selected devices.
9. If the TX calibration fails, repeat the full optimization for any failed
paths.
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Introduction to Optimization and Calibration – continued
10. If the TX calibration fails again, troubleshoot and correct the
problem causing the failure, and repeat the full optimization for the
failed path.
11. If the TX calibration and audit portion of the full optimization passes
for a path but some of the TX or RX tests fail, troubleshoot and
correct the problem causing the failure, and run the individual tests
as required until all TX and RX tests have passed for all paths.
Cell-site Types
The site is configured as Omni/Omni. Each cell site type has unique
characteristics and must be optimized accordingly.
CDF/NECF
The CDF/NECF (Configuration Data File/Network Element
Configuration File) contains information that defines the BTS and data
used to download files to the devices. A CDF/NECF file must be placed
in the applicable BTS folder before the WinLMF can be used to log into
that BTS. CDF/NECF files are normally obtained from the CBSC using
a floppy disk. A file transfer protocol (ftp) method can be used if the
WinLMF computer has that capability. Refer to the WinLMF Help
function on–line documentation for more information.
The CDF/NECF includes the following information:
S Download instructions and protocol
S Site specific equipage information
S CCP2 Shelf allocation plan
– BBX equipage (based on cell–site type) including IS–95A/B or
CDMA2000 1X capability and redundancy
– CSA equipage including redundancy
– Multi–Channel CDMA Card 1X channel element allocation plan.
This plan indicates how the CCP2 Shelf is configured, and how the
paging, synchronization, traffic, and access channel elements (and
associated gain values) are assigned among the (up to 3) MCC–1Xs
in the shelf.
S Effective Rated Power (ERP) table for all TX channels to antennas
respectively. Motorola System Engineering specifies the ERP of a
transmit antenna based on site geography, antenna placement, and
government regulations. Working from this ERP requirement, antenna
gain and antenna feed line loss can be combined to calculate the
required transmit power at the frame antenna connections. The
corresponding BBX output power required to achieve that power level
on any channel/sector can then be determined based on Bay Level
Offset (BLO) data established during the optimization process.
6
Jun 2004 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU 6-5
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Page 42
Introduction to Optimization and Calibration – continued
NOTE
Refer to Figure 6-2 and the WinLMF Help function on–line
documentation for additional information on the layout of
the WinLMF directory structure (including CDF/NECF file
locations and formats).
BTS System Software
Download
BTS system software must be successfully downloaded to the BTS
processor boards before optimization can be performed. BTS operating
code is loaded from the WinLMF computer terminal.
The BTS is configured for Circuit Backhaul and uses bts.cdf files. BTSs
configured for Packet Backhaul use bts.necf files (bts–xxx.xml) located
on the OMC–R.
NOTE
Before using the WinLMF for optimization/ATP, the
correct bts–#.cdf (or bts–#.necf) and cbsc–#.cdf files for
the BTS must be obtained from the CBSC and put in a
bts–# folder in the WinLMF. Failure to use the correct
CDF/NECF files can cause wrong results. Failure to use
the correct CDF/NECF files to log into a live (traffic
carrying) site can shut down the site.
6
The CDF/NECF is normally obtained from the CBSC on a DOS
formatted diskette, or through a file transfer protocol (ftp) if the
WinLMF computer has ftp capability. Refer to the WinLMF Help
function on–line documentation for the procedure.
Site Equipage Verification
If you have not already done so, use an editor to view the CDF/NECF,
and review the site documentation. Verify the site engineering equipage
data in the CDF/NECF matches the actual site hardware using a
CDF/NECF conversion table.
CAUTION
Use extreme care not to make any changes to the
CDF/NECF content while viewing the file. Changes to the
CDF/NECF can cause the site to operate unreliably or
render it incapable of operation.
Always wear a conductive, high impedance wrist strap
while handling any circuit card/module to prevent damage
by ESD. Extreme care should be taken during the removal
and installation of any card/module. After removal, the
card/module should be placed on a conductive surface or
back into the anti–static bag in which it was shipped.
6-6 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU Jun 2004
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Preparing the LMF
Overview of Packet BTS files
R16.0 and earlier releases had the configuration file called CDF for each
BTS and CBSC used by WinLMF. In 16.1 Packet BTS, BTS with GLI3
booting in packet binary, the CDF is replaced by two new configuration
files called Network Element Configuration Base (NECB) and Network
Element Change Journal (NECJ). The NECB contains the baseline
configuration and is analogous to the CDF, while the NECJ contains all
the changes made to the configuration since the last time the NECB was
re–generated. Once the NECJ gets to 80% of its maximum size, the
NECB is re–generated and all the updates are rolled into it.
These files play much broader and vital role than previous CDF files.
GLI3 booting in circuit binaries works similar to R16.0.
A few WinLMF related important facts about these files are listed below.
S Both files (NECB and NECJ) are in XML format.
S NECB contains all the up-to-date static configuration information and
NECJ contains all the recent changes (including operations) which are
not updated in the NECB.
S Both files can be viewed in any XML viewer (most easily available is
Internet Explorer V5.0 and higher). They can be also viewed by any
other word processor, but the XML tags will also be seen with them.
S These files will be created by OMC–R from MIB as per the BTS
provisioning.
S These files will be regenerated for each software release upgrade on
the system for each BTS.
S These files will reside on both OMC–R and Packet–GLI3 (unlike
CDF) and will be synchronized periodically between them.
S Both NECB and NECJ file contain a “SoftwareVersion” field in their
header section indicating the system release version of these files.
S Instead of the bts#.cdf file, the packet WinLMF uses a bts#.XML file,
which is a copy of the NECB.XML file.
S Packet–GLI3 will need these files for site initialization.
S The scope of NECB has grown much broader than CDF and has much
more BTS centric information. The use of generic version of these
files should be strictly avoided for the correct site initialization.
6
Jun 2004 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU 6-7
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Preparing the LMF – continued
WinLMF Features and
Installation Requirements
Before optimization can be performed, the WinLMF application software
must be installed and configured on a computer platform meeting
Motorola–specified requirements.
NOTE
For the WinLMF graphics to display properly, the
computer platform must be configured to display more
than 256 colors. See the operating system software
instructions for verifying and configuring the display
settings.
Software and files for installing and updating the WinLMF are provided
on CD ROM disks. The following items must be available:
S WinLMF application program on CD ROM
S CDF/NECF for each supported BTS (on diskette or available from the
CBSC)
S CBSC File for each supported BTS (on floppy disk or CD ROM)
FTP Server
To be able to download files to the GLI3, the WinLMF now runs FTP
6
server on the WinLMF laptop. The WinLMF FTP server runs from the
LMFs home directory. All the files necessary to run the WinLMF FTP
server are installed from the WinLMF CD. The FTP server is
automatically started by the WinLMF upon successful Login to a Packet
BTS.
In addition, the WinLMF provides a new option in the Tools menu called
FTP Server. The option starts the LMFs FTP server if Start is selected,
and stops the server if Stop is selected. The LMFs FTP server runs on
port 21. If any other process is using that port, the error message is
displayed to the user stating that the port is occupied. There is another
option under FTP Server menu called FTP Monitor, which allows the
user to watch FTP activity b/w the WinLMF and GLI.
Firewalls
Firewalls will block the FTP requests from the Packet GLI to the
WinLMF laptop. You must disable your firewall before attempting the
BTS Synch command. Some common firewall programs to look for
include Network ICE, BlackICE, Norton’s Desktop Firewall, Enterprise
Firewall, and Personal Firewall.
6-8 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU Jun 2004
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Preparing the LMF – continued
WinLMF File Structure
Overview
Figure 6-2: WinLMF Folder Structure
FTP Server Port in use
On some Windows 2000 installations, a process called “inetd.exe”
makes the FTP server port 21 unusable by the WinLMF. If the WinLMF
reports that the FTP server could not start because the port is in use,
make sure the inetd.exe is not running by using the Task Manager’s
process list. If inetd.exe is running, end the process by selecting it and
clicking the “End Process” button. Inetd32.
exe is NOT the same and
ending it will not resolve this problem.
The WinLMF uses a <x>:\<lmf home directory> folder that contains all
of the essential data for installing and maintaining the BTS. The
following list outlines the folder structure for WinLMF. Except for the
bts-nnn folders, these folders are created as part of the WinLMF
installation. Refer to the CDMA WinLMF Operator ’s Guide for a
complete description of the folder structure.
(C:)
x:\<lmf home directory> folder
cdma folder
BTS–nnn folders (A separate folder is
required for each BTS where bts–nnn is the
unique BTS number; for example, bts–163.)
loads folder
version folder (A separate folder is
required for each different version; for
example, a folder name 2.8.1.1.1.5.)
code folder
data folder
NOTE
The “loads” folder and all the folders below it are not
available from the WinLMF for Software Release 2.16.3.x.
These folders may be present as as a legacy from previous
software versions or downloaded from the OMC–R/CBSC.
6
WinLMF Home Directory
The WinLMF installation program creates the default home directory,
c:\wlmf, and installs the application files and subdirectories (folders)
in it. Because this can be changed at installation, the CDMA WinLMF
home directory will be referred to with the generic convention of:
Jun 2004 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU 6-9
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Preparing the LMF – continued
NECF Filename Conventions
and Directory Location
<x>:\<lmf home directory>
Where:
<x> = the WinLMF computer drive letter where the CDMA WinLMF
home directory is located.
<lmf home directory> = the directory path or name where the CDMA
WinLMF is installed.
NECF
The NECF actually consists of two files: the NECB and NECJ. The
naming convention for the NECB and NECJ is:
NECB*bts#.xml
NECJ*bts#.xml
Where:
* = any characters can be substituted there
# = the actual integer BTS number
The NECB and its corresponding NECJ must have the exact same name,
except for the “B” and “J” difference after the initial NEC characters.
The NECB and the NECJ must reside in the
<WinLMF_HOME>\cdma\bts–# directory corresponding to the BTS
6
frame they are for.
Load Information File (LIF)
The LIF contains all the devices binaries available for the specified
System Software Release. It is the functional equivalent of the OLF file
that was used pre–Packet.
The naming convention for the LIF is:
NE_LIF.xml
The LIF must reside in the <WinLMF_HOME>\cdma\loads\<Software
Release Number> directory, where <WinLMF_HOME> = the home
directory in which the WinLMF is installed, usually C:\wlmf <Software
Release Number> = the System Software Release Number (e.g.
2.16.1.0.10).
Cal File
The Cal File still resides in the <WinLMF_HOME>\cdma\bts–#
directory and is named bts–#.cal, where # is the actual integer number of
the BTS.
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Preparing the LMF – continued
WinLMF Operating System
Installation
This section provides information and instructions for installing and
updating the WinLMF software and files.
First Time Installation Sequence
S Install Java Runtime Environment (JRE)
S Install U/WIN K–shell emulator
S Install WinLMF application programs
S Install/create BTS folders
NOTE
Any time you install U/WIN, you must install the
WinLMF software because the installation of the WinLMF
modifies some of the files that are installed during the
U/Win installation. Installing U/Win over–writes these
modifications.
There are multiple binary image packages for installation
on the CD–ROM. When prompted, choose the load that
corresponds to the switch release that you currently have
installed. Perform the Device Images install after the
WinLMF installation.
If applicable, a separate CD ROM of BTS Binaries may be
available for binary updates.
6
Follow the procedure in Table 6-2 to install the WinLMF application
program using the WinLMF CD ROM.
Table 6-2: Install WinLMF using CD ROM
n Step Action
1 Insert the WinLMF CD ROM disk into your disk drive and perform the following as required:
1a – If the Setup screen appears, follow the instructions displayed on the screen.
1b – If the Setup screen is not displayed, proceed to Step 2.
2 Click on the Start button
3 Select Run.
4 Enter d:\autorun in the Open box and click OK.
NOTE
If applicable, replace the letter d with the correct CD ROM drive letter.
Jun 2004 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU 6-11
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Preparing the LMF – continued
Copy BTS CDF (or NECF) and
CBSC CDF Files to the WinLMF
Computer
Before logging on to a BTS with the WinLMF computer to execute
optimization/ATP procedures, the correct bts-#.cdf (or bts–#.necf) and
cbsc-#.cdf files must be obtained from the CBSC and put in a bts-#
folder in the WinLMF computer. This requires creating versions of the
CBSC CDF files on a DOS–formatted floppy diskette and using the
diskette to install the CDF files on the WinLMF computer.
NOTE
If the WinLMF has ftp capability, the ftp method can be
used to copy the CDF or NECF files from the CBSC.
On Sun OS workstations, the unix2dos command can be
used in place of the cp command (e.g., unix2dos
bts–248.cdf bts–248.cdf). This should be done using a
copy of the CBSC CDF file so the original CBSC CDF file
is not changed to DOS format.
When copying CDF or NECF files, comply with the
following to prevent BTS login problems with the
Windows WinLMF:
– The numbers used in the bts-#.cdf (or bts–#.necf)
and cbsc-#.cdf filenames must correspond to the
locally-assigned numbers for each BTS and its
6
controlling CBSC.
– The generic cbsc–1.cdf file supplied with the
Windows WinLMF will work with locally numbered
BTS CDF files. Using this file will not provide a
valid optimization unless the generic file is edited to
replace default parameters (e.g., channel numbers)
with the operational parameters used locally.
The procedure in Table 6-3 lists the steps required to transfer the CDF
files from the CBSC to the WinLMF computer. For further information,
refer to the WinLMF Help function on–line documentation.
Table 6-3: Copying CDF or NECF Files to the WinLMF Computer
n Step Action
AT THE CBSC:
1 Login to the CBSC workstation.
2 Insert a DOS–formatted floppy diskette in the workstation drive.
3 Type eject –q and press the Enter key.
. . . continued on next page
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Preparing the LMF – continued
Table 6-3: Copying CDF or NECF Files to the WinLMF Computer
n ActionStep
4 Type mount and press the Enter key.
NOTE
S Look for the “floppy/no_name” message on the last line displayed.
S If the eject command was previously entered, floppy/no_name will be appended with a number.
Use the explicit floppy/no_name reference displayed when performing step 7.
5 Change to the directory, where the files to be copied reside, by typing cd <directoryname>
(e.g., cd bts–248) and pressing the Enter key.
6 Type ls and press the Enter key to display the list of files in the directory.
7 With Solaris versions of Unix, create DOS–formatted versions of the bts-#.cdf (or bts–#.necf) and
cbsc-#.cdf files on the diskette by entering the following command:
unix2dos <source filename> /floppy/no_name/<target filename>
(e.g., unix2dos bts–248.cdf /floppy/no_name/bts–248.cdf).
NOTE
S Other versions of Unix do not support the unix2dos and dos2unix commands. In these cases, use
the Unix cp (copy) command. The copied files will be difficult to read with a DOS or Windows text
editor because Unix files do not contain line feed characters. Editing copied CDF files on the
WinLMF computer is, therefore, not recommended.
S Using cp, multiple files can be copied in one operation by separating each filename to be copied
with a space and ensuring the destination directory (floppy/no_name) is listed at the end of the
command string following a space (e.g., cp bts–248.cdf cbsc–6.cdf /floppy/no_name).
8 Repeat Steps 5 through 7 for each bts–# that must be supported by the WinLMF computer.
6
9 When all required files have been copied to the diskette type eject and press the Enter key.
10 Remove the diskette from the CBSC drive.
AT THE WinLMF:
11 If it is not running, start the Windows operating system on the WinLMF computer.
12 Insert the diskette containing the bts-#.cdf (or bts–#.necf) and cbsc-#.cdf files into the WinLMF
computer.
13 Using MS Windows Explorer, create a corresponding bts–# folder in the <x>:\<lmf home
directory>\cdma directory for each bts–#.cdf/cbsc–#.cdf (or bts–#.necf/cbsc–#.cdf) file pair copied
from the CBSC.
14 Use MS Windows Explorer to transfer the bts-#.cdf (or bts–#.necf) and cbsc-#.cdf files from the
diskette to the corresponding <x>:\<lmf home directory>\cdma\bts–# folders created in Step 13.
Jun 2004 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU 6-13
DRAFT
Page 50
Preparing the LMF – continued
Creating a Named
HyperTerminal Connection for
MMI Communication
Confirming or changing the configuration data of certain BTS Field
Replaceable Units (FRU) requires establishing an MMI communication
session between the WinLMF and the FRU. Using features of the
Windows operating system, the connection properties for an MMI
session can be saved on the WinLMF computer as a named Windows
HyperTerminal connection. This eliminates the need for setting up
connection parameters each time an MMI session is required to support
optimization.
Once the named connection is saved, a shortcut for it can be created on
the Windows desktop. Double–clicking the shortcut icon will start the
connection without the need to negotiate multiple menu levels.
Follow the procedures in Table 6-4 to establish a named HyperTerminal
connection and create a Windows desktop shortcut for it.
Table 6-4: Create HyperTerminal Connection
Step Action
1 From the Windows Start menu, select:
Programs>Accessories>
6
2 Perform one of the following:
S For Win NT, select Hyperterminal and then click on HyperTerminal or
S For Win 98, select Communications, double click the Hyperterminal folder, and then double click
on the Hyperterm.exe icon in the window that opens.
NOTE
S If a Location Information Window appears, enter the required information, then click on the
Close button. (This is required the first time, even if a modem is not to be used.)
S If a You need to install a modem..... message appears, click on NO.
3 When the Connection Description box opens:
– Type a name for the connection being defined (e.g., MMI Session) in the Name: window,
– Highlight any icon preferred for the named connection in the Icon: chooser window, and
– Click OK.
4 From the Connect using: pick list in the Connect To box displayed, select COM1 or COM2 (Win
NT) – or Direct to Com 1 or Direct to Com 2 (Win 98) for the RS–232 port connection and click OK.
NOTE
For WinLMF computer configurations where COM1 is used by another interface such as test
equipment and a physical port is available for COM2, select COM2 in the following step to prevent
conflicts.
. . . continued on next page
6-14 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU Jun 2004
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Page 51
Preparing the LMF – continued
Table 6-4: Create HyperTerminal Connection
Step Action
5 In the Port Settings tab of the COM# Properties window displayed, configure the RS–232 port
settings as follows:
S Bits per second: 9600
S Data bits: 8
S Parity: None
S Stop bits: 1
S Flow control: None
6 Click OK.
7 Save the defined connection by selecting:
File > Save
8 Close the HyperTerminal window by selecting:
File > Exit
9 Click the Yes button to disconnect when prompted.
10 Perform one of the following:
S If the Hyperterminal folder window is still open (Win 98) proceed to step 12
S From the Windows Start menu, select Programs > Accessories.
11 Perform one of the following:
S For Win NT, select Hyperterminal and release any pressed mouse buttons.
S For Win 98, select Communications and double click the Hyperterminal folder.
S For Win–XP, select Communications and double click the Hyperterminal folder.
12 Highlight the newly–created connection icon by clicking on it.
13 Right click and drag the highlighted connection icon to the Windows desktop and release the right
mouse button.
14 From the popup menu which appears, select Create Shortcut(s) Here.
15 If desired, reposition the shortcut icon for the new connection by dragging it to another location on the
Windows desktop.
16 Close the Hyperterminal folder window by selecting:
File > Close
6
Jun 2004 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU 6-15
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Page 52
Span Lines – Interface and Isolation
T1/E1 Span Interface
NOTE
At active sites, the OMC–R/CBSC must disable the BTS
and place it out–of–service (OOS). DO NOT remove the
span line cable connectors until the OMC–R/CBSC has
disabled the BTS.
Before connecting the WinLMF computer to the BTS LAN, the
OMC–R/CBSC must disable the BTS and place it OOS. This will allow
the WinLMF to control the BTS, and prevent the CBSC from
inadvertently sending control information to the BTS during
WinLMF–based tests.
Isolate BTS from T1/E1 Spans
Once the OMC–R/CBSC has disabled the BTS, the spans must be
disabled to ensure the WinLMF will maintain control of the BTS.
T1/E1 Span Isolation
Table 6-5 describes the action required for span isolation.
Table 6-5: T1/E1 Span Isolation
Step Action
6
1 Have the OMC–R/CBSC operator place the BTS OOS.
2 To disable the span lines, disconnect the span or spans from the CBIO Network Span–1X or Group 1
Span–EVDO sockets.
If in an outdoor configuration, then unlock and open TME left side door to gain access to rear of BTS.
6-16
1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU
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JUN 2004
Page 53
LMF to BTS Connection
Figure 6-3: WinLMF Connection Detail
Connect the WinLMF to the
BTS
The WinLMF computer may be connected to the LAN A or B connector
located on the front panel or at the rear of the BTS. Figure 6-3 below
shows the general location of these connectors. LAN A is considered the
primary LAN.
Table 6-6: Connecting the WinLMF to the BTS
n Step Action
1 For indoor configuration, remove BTS front panel cover.
For outdoor configuration, unlock and open TME right side door and remove BTS front panel cover.
NOTE
Xircom Model PE3–10B2 or equivalent can also be used to interface the WinLMF Ethernet
connection to the BTS frame connected to the PC parallel port, powered by an external AC/DC
transformer. In this case, the BNC cable must not exceed 91 cm (3 ft) in length.
2 Connect the WinLMF computer to the LAN A (left–hand) BNC connector . (See Figure 6-3)
* IMPORTANT
The LAN shield is isolated from chassis ground. The LAN shield (exposed portion of BNC connector)
must not touch the chassis during optimization.
Remove panel to gain
access to the site 1 or
site 2 LMF BNC
connector.
10BASET/10BASE2
CONVERTER CONNECTS
DIRECTLY TO LAN A
ETHERNET A LMF
CONNECTION
ETHERNET B LMF
CONNECTION
6
JUN 2004
PCMCIA ETHERNET
ADAPTER
If lap top is equipped with an
ethernet port, then PCMCIA
ethernet adapter is not required
1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU
115 VAC POWER
CONNECTION
DRAFT
FRONT OF BTS
WITH PANEL
COVER REMOVED
6-17
Page 54
Using the LMF
Basic LMF Operation
LMF Coverage in This Publication – The LMF application program
supports maintenance of both CDMA and SAS BTSs. All references to
the LMF in this publication are to the CDMA portion of the program.
Operating Environments – The LMF application program allows the
user to work in the two following operating environments which are
accessed using the specified desktop icons:
S Graphical User Interface (GUI) using the WinLMF icon
S Command Line Interface (CLI) using the WinLMF CDMA CLI icon
The GUI is the primary optimization and acceptance testing operating
environment. The CLI environment provides additional capability to the
user to perform manually controlled acceptance tests and audit the
results of optimization and calibration actions.
Basic Operation – Basic operation of the LMF in either environment
includes performing the following:
S Selecting and deselecting BTS devices
S Enabling devices
S Disabling devices
S Resetting devices
6
S Obtaining device status
The following additional basic operation can be performed in a GUI
environment:
S Sorting a status report window
For detailed information on performing these and other LMF operations,
refer to the LMF Help function on–line documentation.
NOTE
Unless otherwise noted, LMF procedures in this manual
are performed using the GUI environment.
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Using the LMF – continued
The LMF Display and the BTS
Graphical User Interface
Overview
BTS Display – When the LMF is logged into a BTS, a frame tab is
displayed for each BTS frames. The frame tab will be labeled with
“CDMA” and the BTS number, a dash, and the frame number (for
example, BTS–812–1 for BTS 812, RFMF 1). If there is only one frame
for the BTS, there will only be one tab.
CDF/NECF Requirements – For the LMF to recognize the devices
installed in the BTS, a BTS CDF/NECF file which includes equipage
information for all the devices in the BTS must be located in the
applicable <x>:\<lmf home directory>\cdma\bts–# folder. To provide
the necessary channel assignment data for BTS operation, a CBSC CDF
file which includes channel data for all BTS RFMFs is also required in
the folder.
The LMF uses a GUI, which works in the following way:
Understanding GUI Operation
S Select the device or devices.
S Select the action to apply to the selected device(s).
S While action is in progress, a status report window displays the action
taking place and other status information.
S The status report window indicates when the the action is complete
and displays other pertinent information.
S Clicking the OK button closes the status report window.
The following screen captures are provided to help understand how the
GUI operates:
– Figure 6-4 depicts the differences between packet and circuit
CDMA “cdf” file identification. Note that if there is a packet
version “bts” file, the “(P)” is added as a suffix. There is a
corresponding “(C)” for the circuit mode version.
– Figure 6-5 depicts the Self-Managed Network Elements (NEs) state
of a packet mode. Note that an “X” is on the front of each card that
is under Self–Managed Network Elements (NEs) control by the
GLI3 card.
– Figure 6-6 depicts three of the available packet mode commands.
Normally the GLI3 has Self-Managed Network Elements (NEs)
control of all cards as shown in Figure 6-5 by an “(X)”. In that state
the LMF may only status a card. In order to download code or test a
card, the LMF must request Self-Managed Network Elements (NEs)
control of the card by using the shown dropdown menu. It also uses
this menu to release control of the card back to the GLI3. The GLI3
will also assume control of the cards after the LMF logs out of the
BTS. The packet mode GLI3 normally is loaded with a tape release
6
Jun 2004 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU 6-19
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Page 56
Using the LMF – continued
Figure 6-4: BTS Login Screen – Identifying Circuit and Packet BTS Files
and NECB and NECJ files which point to a tape release stored on
the GLI3. When the GLI3 has control of a card it will maintain that
card with the code on that tape release.
– Figure 6-7 depicts a packet mode site that has the MCC–1 and the
BBX–1 cards under LMF control. Notice that the “X” is missing
from the front of these two cards.
For detailed information on performing these and other LMF operations,
refer to the LMF Help function on–line documentation.
6
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Using the LMF – continued
Figure 6-5: Self–Managed Network Elements (NEs) State of a Packet Mode
6
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Using the LMF – continued
Figure 6-6: Available Packet Mode Commands
6
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Using the LMF – continued
Figure 6-7: Packet Mode Site with MCC–1 and BBX–1 under LMF Control
6
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Page 60
Using the LMF – continued
Command Line Interface
Overview
The LMF also provides Command Line Interface (CLI) capability.
Activate the CLI by clicking on a shortcut icon on the desktop. The CLI
can not be launched from the GUI, only from the desktop icon.
Both the GUI and the CLI use a program known as the handler. Only one
handler can be running at one time. The architectural design is such that
the GUI must be started before the CLI if you want the GUI and CLI to
use the same handler.
When the CLI is launched after the GUI, the CLI automatically finds and
uses an in–progress login session with a BTS initiated under the GUI.
This allows the use of the GUI and the CLI in the same BTS login
session.
If a CLI handler is already running when the GUI is launched (this
happens if the CLI window is already running when the user starts the
GUI, or if another copy of the GUI is already running when the user
starts the GUI), a dialog window displays the following warning
message:
The CLI handler is already running.
This may cause conflicts with the LMF.
Are you sure that you want to start the application?
This window also contains yes and no buttons. Selecting yes starts the
application. Selecting no terminates the application.
6
CLI Format Conventions
The CLI command can be broken down in the following way:
S Verb
S Device including device identifier parameters
S Switch
S Option parameters consisting of:
– Keywords
– Equals sign (=) between the keyword and the parameter value
– Parameter values
Spaces are required between the verb, device, switch, and option
parameters. A hyphen is required between the device and its identifiers.
Following is an example of a CLI command.
measure bbx–<bts_id>–<bbx_id> rssi channel=6 sector=5
Refer to the LMF CLI Commands for a complete explanation of the CLI
commands and their usage.
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Using the LMF – continued
Logging Into a BTS
Logging into a BTS establishes a communication link between the BTS
and the LMF. An LMF session can be logged into only one BTS at a
time.
Prerequisites
Before attempting to log into a BTS, ensure the following have been
completed:
S The LMF is correctly installed on the LMF computer.
S A bts-nnn folder with the correct CDF/NECF and CBSC files exists.
S The LMF computer was connected to the BTS before starting the
Windows operating system and the LMF software. If necessary, restart
the computer after connecting it to the BTS in accordance with
Table 6-6 and Figure 6-3.
CAUTION
Be sure that the correct bts–#.cdf/necf and cbsc–#.cdf file
are used for the BTS. These should be the CDF/NECF files
that are provided for the BTS by the CBSC. Failure to use
the correct CDF/NECF files can result in invalid
optimization. Failure to use the correct CDF/NECF files
to log into a live (traffic–carrying) site can shut down
the site.
BTS Login from the GUI Environment
Follow the procedures in Table 6-7 to log into a BTS when using the
GUI environment.
Table 6-7: BTS GUI Login Procedure
n Step Action
1 Start the LMF GUI environment by double–clicking on the WinLMF desktop icon (if the LMF is
not running).
– An LMF window will open and display the LMF build number in the title bar.
NOTE
If a warning similar to the following is displayed, select No, shut down other LMF sessions which
may be running, and start the LMF GUI environment again:
The CLI handler is already running.
This may cause conflicts with the LMF.
Are you sure you want to start the application?
Yes No
2 Click on Login tab (if not displayed).
3 Double click on CDMA (in the Available Base Stations pick list).
. . . continued on next page
6
Jun 2004 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU 6-25
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Page 62
Using the LMF – continued
n ActionStep
4 Click on the desired BTS number.
5 Click on the Network Login tab (if not already in the forefront).
6 Enter correct IP address (normally 128.0.0.2) for a field BTS, if not correctly displayed in the IP
Address box.
7 Type in the correct IP Port number (normally 9216) if not correctly displayed in the IP Port box.
8 Click on Ping.
– If the connection is successful, the Ping Display window shows text similar to the following:
Reply from 128 128.0.0.2: bytes=32 time=3ms TTL=255
– If there is no response the following is displayed:
128.0.0.2:9216:Timed out
If the GLI fails to respond, reset and perform the ping process again. If the GLI still fails to
respond, typical problems are shorted BNC to inter–frame cabling, open cables, crossed A and B
link cables, missing 50–Ohm terminators, or the GLI itself.
Table 6-7: BTS GUI Login Procedure
9 If required, match the device corresponding to the BTS configuration by selecting
Multi-channel Preselector type from the Multi-channel Preselector drop–down list (default is
MPC).
10 Click on Login. (A BTS tab with the BTS and frame numbers is displayed.)
NOTE
6
S If an attempt is made to log into a BTS that is already logged on, all devices will be gray.
S There may be instances where the BTS initiates a log out due to a system error (i.e., a device
failure).
S If the GLI is OOS–ROM (blue), it must be downloaded with RAM code before other devices
can be seen.
S If the GLI is OOS–RAM (yellow), it must be enabled before other installed devices can be seen.
6-26 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU Jun 2004
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Page 63
Using the LMF – continued
BTS Login from the CLI Environment
Follow the procedures in Table 6-8 to log into a BTS when using the
CLI environment.
NOTE
If the CLI and GUI environments are to be used at the
same time, the GUI must be started first and BTS login
must be performed from the GUI. Refer to Table 6-7 to
start the GUI environment and log into a BTS.
Table 6-8: BTS CLI Login Procedure
n Step Action
1 Double–click the WinLMF CLI desktop icon (if the LMF CLI environment is not already
running).
NOTE
If a BTS was logged into under a GUI session before the CLI environment was started, the CLI
session will be logged into the same BTS, and step 2 is not required.
2 At the /wlmf prompt, enter the following command:
login bts–<bts#> host=<host> port=<port>
where:
host = GLI card IP address (defaults to address last logged into for this BTS or 128.0.0.2 if this is
first login to this BTS)
port = IP port of the BTS (defaults to port last logged into for this BTS or 9216 if this is first login
to this BTS)
A response similar to the following will be displayed:
LMF>
13:08:18.882 Command Received and Accepted
COMMAND=login bts–33
13:08:18.882 Command In Progress
13:08:21.275 Command Successfully Completed
REASON_CODE=”No Reason”
6
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Using the LMF – continued
Logging Out
Logging out of a BTS is accomplished differently for the GUI and CLI
operating environments.
NOTE
The GUI and CLI environments use the same connection to
a BTS. If a GUI and the CLI session are running for the
same BTS at the same time, logging out of the BTS in
either environment will log out of it for both. When either
a login or logout is performed in the CLI window, there is
no GUI indication that the login or logout has occurred.
Logging Out of a BTS from the GUI Environment
Follow the procedure in Table 6-9 to logout of a BTS when using the
GUI environment.
Table 6-9: BTS GUI Logout Procedure
n Step Action
1 Click on BTS in the BTS menu bar.
2 Click the Logout item in the pull–down menu (a Confirm Logout pop-up message will appear).
Click on Yes (or press the Enter key) to confirm logout. The Login tab will appear.
3
6
NOTE
If a logout was previously performed on the BTS from a CLI window running at the same time as
the GUI, a Logout Error pop–up message will appear stating the system could not log out of the
BTS. When this occurs, the GUI must be exited and restarted before it can be used for further
operations.
4 If a Logout Error pop–up message appears stating that the system could not log out of the Base
Station because the given BTS is not logged in, click OK and proceed to Step 5.
5 Select File > Exit in the window menu bar, click Yes in the Confirm Logout pop–up, and click
OK in the Logout Error pop–up which appears again.
6 If further work is to be done in the GUI, restart it.
NOTE
S The Logout item on the BTS menu bar will only log you out of the displayed BTS.
S You can also log out of all BTS sessions and exit LMF by clicking on the File selection in the
menu bar and selecting Exit from the File menu list. A Confirm Logout pop–up message will
appear.
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Using the LMF – continued
Logging Out of a BTS from the CLI Environment
Follow the procedure in Table 6-10 to logout of a BTS when using the
CLI environment.
Table 6-10: BTS CLI Logout Procedure
n Step Action
NOTE
If the BTS is also logged into from a GUI running at the same time and further work must be done
with it in the GUI, proceed to Step 2.
1 Log out of a BTS by entering the following command:
logout bts–<bts#>
A response similar to the following will be displayed:
LMF>
13:24:51.028 Command Received and Accepted
COMMAND=logout bts–33
13:24:51.028 Command In Progress
13:24:52.04 Command Successfully Completed
REASON_CODE=”No Reason”
2 If desired, close the CLI interface by entering the following command:
exit
A response similar to the following will be displayed before the window closes:
Killing background processes....
6
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Using the LMF – continued
Establishing an MMI
Communication Session
Equipment Connection – Figure 6-8 illustrates common equipment
connections for the LMF computer. For specific connection locations on
FRUs, refer to the illustration accompanying the procedures which
require the MMI communication session.
If the Motorola SLN2006A MMI Interface Kit is not available, an MMI
cable can be made, refer to Appendix D for more information.
Initiate MMI Communication – For those procedures which require
MMI communication between the LMF and BTS FRUs, follow the
procedures in Table 6-11 to initiate the communication session.
Table 6-11: Establishing MMI Communication
Step Action
1 Connect the LMF computer to the equipment as detailed in the applicable procedure which requires
the MMI communication session. Refer to Figure 6-8 or Figure 6-9 using the GLI3 as an example.
2 If the LMF computer has only one serial port (COM1) and the LMF is running, disconnect the LMF
from COM1 by performing the following:
2a – Click on Tools in the LMF window menu bar, and select Options from the pull–down menu list.
–– An LMF Options dialog box will appear.
2b – In the LMF Options dialog box, click the Disconnect Port button on the Serial Connection tab.
6
Start the named HyperTerminal connection for MMI sessions by double clicking on its Windows
3
desktop shortcut.
NOTE
If a Windows desktop shortcut was not created for the MMI connection, access the connection from the
Windows Start menu by selecting:
Programs > Accessories > Hyperterminal > HyperTerminal > <Named HyperTerminal
Connection (e.g., MMI Session)>
4 Once the connection window opens, establish MMI communication with the BTS FRU by pressing
the LMF computer <Enter>key until the prompt identified in the applicable procedure is obtained.
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Using the LMF – continued
Figure 6-8: LMF Computer Common MMI Connections – Motorola MMI Interface Kit, SLN2006A
RESET
Button
To MMI
Connector
MMI
Connector
LMF
COMPUTER
8–PIN
COM1
COM2
OR
8–PIN TO 10–PIN
RS–232 CABLE
(P/N 30–09786R01)
RS–232 CABLE
NULL MODEM
DB9–TO–DB25
ADAPTER
BOARD
(TRN9666A)
6
FW00687
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Page 68
Using the LMF – continued
Figure 6-9: MMI Connection Detail – Fabricated MMI Cable
To MMI
Connector
8–PIN
RESET
Button
MMI
Connector
LMF COMPUTER
OR EQUIVALENT
FABRICATED MMI CABLE
(SEE MMI CABLE
FABRICATION APPENDIX D)
COM1
6
OR
COM2
DB–9
CONNECTOR
Online Help
Task oriented online help is available in the LMF by clicking on Help in
the window menu bar, and selecting LMF Help from the pull–down
menu.
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Pinging the Processors
Figure 6-10: BTS Ethernet LAN Termination Diagram
Pinging the BTS
For proper operation, the integrity of the Ethernet LAN A and B links
must be verified. Figure 6-10 represents a typical BTS Ethernet
configuration. The drawing depicts cabling and termination for both the
A and B LANs.
Ping is a program that sends request data packets to hosts on a network,
in this case GLI modules on the BTS LAN, to obtain a response from the
“target” host specified by an IP address.
Follow the steps in Table 6-12 to ping each processor (on both LAN A
and LAN B) and verify LAN redundancy is working properly.
CAUTION
TERMINATION
50Ω
SIGNAL
GROUND
Always wear an approved anti–static wrist strap while handling
any circuit card/module to prevent damage by ESD.
BIN
BOUT
SIGNAL
GROUND
50Ω
TERMINATION
CHASSIS GROUND
6
JUN 2004
SIGNAL
GROUND
TERMINATION
50Ω
SIGNAL
GROUND
AIN
AOUT
SIGNAL
GROUND
50Ω
1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU
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TERMINATION
SC4812ETL0013–5
6-33
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Pinging the Processors
NOTE
The Ethernet LAN A and B cables and/or terminations must be
installed on each frame/enclosure external LAN connector before
performing this test. All other processor board LAN connections
are made through the backplanes.
Table 6-12: Pinging the Processors
Step Action
1 If this is a first–time communication with a newly–installed frame or a GLI card which has been
replaced, perform the procedure in Table 11-3 and then return to step 2.
2 Be sure any uncabled LAN A and B IN and OUT connectors at the rear of BTS are terminated with 50
Ω loads.
3 If it has not already been done, connect the LMF computer to the BTS.
4 If it has not already been done, start a GUI LMF session and log into the BTS ( refer to Table 6-7).
5 Remove the 50Ω termination on the BTS LAN B IN connector.
– The LMF session should remain active.
6 Replace the 50Ω termination on the BTS LAN B IN connector.
7 From the Windows desktop, click the Start button and select Run.
8 In the Open box, type ping and the GLI IP address (for example, ping 128.0.0.2).
NOTE
6
128.0.0.2 is the default IP address for the GLI card in slot GLI–1 in field BTS units.
9 Click on OK.
10 If the targeted module responds, a DOS window will appear with a display similar to the following:
Reply from 128.0.0.2: bytes=32 time=3ms TTL=255
– If the device responds, proceed to step 18.
If there is no response, the following is displayed:
Request timed out
– If the GLI fails to respond, it should be reset and re–pinged. If it still fails to respond, typical
problems would be: failure of the LMF to login, shorted BNC–to–inter-frame cabling, open
cables, crossed A and B link cables, or the GLI itself.
11 Logout of the BTS as described in Table 6-9, exit from the LMF program, and restart the Windows
operating system on the LMF computer.
12 Restart the LMF GUI program as described in LMF Help function on–line documentation, and log into
the BTS as described in Table 6-7.
13 Perform steps 7 through 10 again.
– If the device responds, proceed to step 18 .
6-34
If there is still no response, proceed to step 14.
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Page 71
Pinging the Processors
Table 6-12: Pinging the Processors
Step Action
14 If ping was unsuccessful after restarting the LMF computer, press the GLI front panel reset pushbutton
and perform steps 7 through 10 again.
15 After the BTS has been successfully pinged, be sure the 50Ω termination was replaced on the BTS
LAN B IN connector at the rear of the BTS. Disconnect the LMF cable from the front LAN A
connector, and connect it to front LAN B (right–hand connector).
16 Remove the 50Ω termination on the BTS LAN A IN connector.
17 Repeat steps 5 through 9 using LAN B.
18 After the BTS has been successfully pinged on the secondary LAN, replace the 50Ω termination on
the BTS LAN A IN connector.
19 Disconnect the LMF cable from the LAN B and connect it to LAN A.
20 Remove and replace the 50Ω termination on the LAN B IN connector to force the GLI to switch to
primary LAN A.
21 Repeat steps 5 through 9 to ensure proper primary LAN operation.
6
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Download the BTS
Overview
ROM Code
Before a BTS can operate, each equipped device must contain device
initialization (ROM) code. ROM code is loaded in all devices during
manufacture, factory repair, or, for software upgrades, from the CBSC
using the DownLoad Manager (DLM). Device application (RAM) code
and data must be downloaded to each equipped device by the user before
the BTS can be made fully functional for the site where it is installed.
Downloading ROM code to BTS devices from the LMF is NOT routine
maintenance or a normal part of the optimization process. It is only
done in unusual situations where the resident ROM code release level in
the device is not compatible with the required release level of the site
operating software and the CBSC can not communicate with the BTS to
perform the download.
If you must download ROM code, the procedures are located in
Appendix C.
Before ROM code can be downloaded from the LMF, the correct ROM
code file for each device to be loaded must exist on the LMF computer.
ROM code must be manually selected for download.
NOTE
The ROM code file is not available for GLI3s. GLI3s are
6
ROM code can be downloaded to a device that is in any state. After the
download is started, the device being downloaded will change to
OOS_ROM (blue). The device will remain OOS_ROM (blue) when the
download is completed. A compatible revision–level RAM code must
then be downloaded to the device. Compatible code loads for ROM and
RAM must be used for the device type to ensure proper performance.
The compatible device code release levels for the Base Station System
(BSS) software release being used are listed in the Version Matrix
section of the SCt CDMA Release Notes (supplied on the tape or
CD–ROM containing the BSS software).
RAM Code
Before RAM code can be downloaded from the LMF, the correct RAM
code file for each device must exist on the LMF computer. RAM code
can be automatically or manually selected depending on the Device
menu item chosen and where the RAM code file for the device is stored
in the LMF file structure. The RAM code file will be selected
automatically if the file is in the <x>:\<lmf home
directory>\cdma\loads\n.n.n.n\code folder (where n.n.n.n is the
download code version number that matches the “NextLoad” parameter
of the CDF file). The RAM code file in the code folder must have the
correct hardware bin number for the device to be loaded.
ROM code loaded at the factory.
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Download the BTS – continued
RAM code can be downloaded to a device that is in any state. After the
download is started, the device being loaded will change to OOS_ROM
(blue). When the download is completed successfully, the device will
change to OOS_RAM (yellow).
When code is downloaded to a GLI, the LMF automatically also
downloads data and then enables the GLI. When enabled, the GLI will
change to INS_ACT (bright green).
For non–GLI devices, data must be downloaded after RAM code is
downloaded. To download data, the device state must be OOS_RAM
(yellow).
If an MCC–DO card is in use, it can only be loaded using the Local
Maintenance Tool (LMT). LMT is software designed specifically for the
MCC–DO card. To avoid confusion and duplication of effort, refer to
Motorola Lifecycles website at
http://www.motorola.com/networkoperators/CDMA–1xEV–DO.htm for
further information on LMT or MCC–DO.
The devices to be loaded with RAM code and data are:
S Group Line Interface III (GLI3)
S Clock Synchronization and Alarm card (CSA) (Only if new revision
code must be loaded)
S Multi–Channel CDMA (MCC–1X) cards
S Broad Band Transceiver (BBX–1X) cards
NOTE
The GLI must be successfully downloaded with RAM code
and data, and in INS_ACT (bright green) status before
downloading any other device. The RAM code download
process for an GLI automatically downloads data and then
enables the GLI.
6
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Download the BTS – continued
Verify GLI ROM Code Loads
Devices should not be loaded with a RAM code version which is not
compatible with the ROM code with which they are loaded. Before
downloading RAM code and data to the processor cards, follow the
procedure in Table 6-13 to verify the GLI devices are loaded with the
correct ROM code for the software release used by the Base Station
System.
Prerequisite
Identify the correct GLI ROM code load for the software release being
used on the BSS by referring to the Version Matrix section of the SCt
CDMA Release Notes (supplied on the tapes or CD–ROMs containing
the BSS software).
Table 6-13: Verify GLI ROM Code Loads
Step Action
1 If it has not already been done, start a GUI LMF session and log into the BTS ( refer to Table 6-7).
2 Select all GLI devices by clicking on them, and select Device > Status from the BTS menu bar.
3 In the status report window which opens, note the number in the ROM Ver column for each GLI2.
4 If the ROM code loaded in the GLIs is not the correct one for the software release being used on the
BSS, perform the following:
4a – Log out of the BTS as described in Table 6-9 or Table 6-10, as applicable.
6
4b – Disconnect the LMF computer.
4c – Reconnect the span lines as described in Table 8-6.
4d – Have the CBSC download the correct ROM code version to the BTS devices.
5 When the GLIs have the correct ROM load for the software release being used, be sure the span lines
are disabled as outlined in Table 6-5 and proceed to downloading RAM code and data.
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Download the BTS – continued
Download RAM Code and Data
to GLI
Prerequisites
S Prior to performing these procedures, ensure a code file exists for each
of the devices to be loaded.
S The LMF computer is connected to the BTS (refer to Table 6-6), and
is logged in using the GUI environment (refer to Table 6-7).
Procedure
Follow the procedure in Table 6-14 to download the firmware
application code for GLI. The download code action downloads data and
also enables the GLI.
Table 6-14: Download and Enable GLI Device
n Step Action
1 Note the active LAN to which the LMF computer is connected.
2 At the rear of the BTS, remove the 50–ohm termination from the LAN OUT connector of the
LAN to which the LMF is not connected.
3 Select Tools > Update Next Load > CDMA function to ensure the Next Load parameter is set to
the correct code version level.
4 Note the LAN IP address in the Network Login section of the LMF Login tab, and verify the Win
LMF is logged into the following IP address:
– GLI : 128.0.0.2
5 Down load code to the GLI by clicking on the GLI.
– From the Device pull down menu, select Download > Code/Data
A status report confirms change in the device status.
– Click OK to close the status window. (The GLI should automatically be downloaded with
data and enabled.)
6 If the card accepts the download and enables, proceed to step 8.
7 If the BTS connection is lost during or after the download process, repeat step 4 and step 5 again.
8 Re–install the 50 ohm termination removed from the LAN connector in step 2.
Download RAM Code and Data
to Non–GLI Devices
6
Downloads to non–GLI devices can be performed individually for each
device or all installed devices can be downloaded with one action.
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Download the BTS – continued
NOTE
CSA devices are RAM code–loaded at the factory. RAM
code is downloaded to CSA only if a newer software
version needs to be loaded.
When downloading to multiple devices, the download may
fail for some of the devices (a time–out occurs). These
devices can be loaded individually after completing the
multiple download.
Follow the steps in Table 6-15 to download RAM code and data to
non–GLI devices.
Table 6-15: Download RAM Code and Data to Non–GLI Devices
n Step Action
1 Select the target CSA, MCC, and/or BBX device(s) by clicking on them.
2 Click Device in the BTS menu bar, and select Download > Code/Data in the pull–down menus.
– A status report is displayed that shows the results of the download for each selected device.
3 Click OK to close the status report window when downloading is completed.
NOTE
After a BBX, CSA, or MCC device is successfully loaded with RAM code and data have changed
to the OOS_RAM state (yellow), the status LED should be rapidly flashing GREEN.
NOTE
6
Selecting CSA Clock Source
and Enabling CSAs
The command in Step 2 loads both code and data. Data can be downloaded without doing a code
download anytime a device is OOS–RAM using the command in Step 4.
4 To download just the firmware application data to each device, select the target device and select:
Device>Download>Data
CSA must be enabled prior to enabling the MCCs. Procedures in the
following two sub-sections cover the actions to accomplish this. For
additional information on the CSA sub–system, see “Clock
Synchronization and Alarm (CSA) in the CSA System Time – GPS &
HSO/MSO Verification section of this chapter.
Select CSA Clock Source
A CSA can have three different clock sources. The CSA Source function
can be used to select the clock source for each of the three inputs. This
function is only used if the clock source for a CSA needs to be changed.
The Clock Source function provides the following clock source options.
S Local GPS
S Remote GPS
S HSO/MSO
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Download the BTS – continued
Prerequisites
S GLI is INS_ACT (bright green)
S CSA is OOS_RAM (yellow) or INS_ACT (bright green)
Follow the procedure in Table 6-16 to select a CSA Clock Source.
Table 6-16: Select CSA Clock Source
n Step Action
1 Select the CSA for which the clock source is to be selected.
2 Click on Device in the BTS menu bar, and select CSA > Select Clock Source... in the pull–down
menu list.
– A CSA clock reference source selection window will appear.
3 Select the applicable clock source in the Clock Reference Source pick lists. Uncheck the related
check boxes for Clock Reference Sources 2 and 3 if you do not want the displayed pick list item to
be used.
4 Click on the OK button.
– A status report is displayed showing the results of the operation.
5 Click on the OK button to close the status report window.
NOTE
For Local GPS (RF–GPS), verify the CSA configured with
the GPS receiver “daughter board” is installed in the BTS’s
CSA slot before continuing.
Enable CSA
Follow the steps outlined in Table 6-17 to enable the CSA.
Table 6-17: Enable CSA
n Step Action
1 Click on Device in the BTS menu bar, and select Enable in the pull–down menu list.
– A status report is displayed showing the results of the enable operation.
– Click OK to close the status report window.
* IMPORTANT
– The GPS satellite system satellites are not in a geosynchronous orbit and are maintained and
operated by the United States Department of Defense (DOD). The DOD periodically alters
satellite orbits; therefore, satellite trajectories are subject to change. A GPS receiver that is INS
contains an “almanac” that is updated periodically to take these changes into account.
– If a GPS receiver has not been updated for a number of weeks, it may take up to an hour for the
GPS receiver “almanac” to be updated.
– Once updated, the GPS receiver must track at least four satellites and obtain (hold) a 3–D position
fix for a minimum of 45 seconds before the CSA will come in service. (In some cases, the GPS
receiver needs to track only one satellite, depending on accuracy mode set during the data load).
6
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Download the BTS – continued
n ActionStep
NOTE
– After CSA have been successfully enabled, be sure the STA/ALM LED is steady green
(alternating green/red indicates the card is in an alarm state).
2 If more than an hour has passed without the CSA enabling, refer to the CSA System Time – GPS &
HSO/MSO Verification section of this chapter (see Table 6-19, Figure 6-11, and Table 6-20) to
determine the cause.
Enable MCCs
Table 6-17: Enable CSA
This procedure configures the MCC and sets the “tx fine adjust”
parameter. The “tx fine adjust” parameter is not a transmit gain setting,
but a timing adjustment that compensates for the processing delay in the
BTS (approximately 3 mS).
Follow the steps in Table 6-18 to enable the MCCs installed in the CCP2
shelf.
NOTE
The GLI and primary CSA must be downloaded and
enabled (IN–SERVICE ACTIVE), prior to downloading
and enabling an MCC.
6
Table 6-18: Enable MCCs
n Step Action
1 If the GLI/MCC/BBX view is not displayed in the LMF window, click on the GLI/MCC/BBX area
of the CCP2 shelf.
2 Click on the target MCC(s), or click on Select in the BTS menu bar, and select MCCs in the
pull–down menu list.
3 Click on Device in the BTS menu bar, and select Enable in the pull–down menu list.
– A status report is displayed showing the results of the enable operation.
4 Click OK to close the status report window.
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CSA System Time – GPS & HSO/MSO Verification
Clock Synchronization and
Alarm (CSA) Sub–system
Description
Overview
The primary function of the CSA card is to maintain CDMA system
time. A GPS receiver provides the primary timing reference for all
CDMA BTS’s During normal operation, the CSA clocking outputs are
phase locked to the GPS receiver timing reference. The CSA supports
either an on–board GPS receiver module (RF GPS) or Remote GPS
(RGPS) receiver. The RGPS receiver consists of a combined GPS
receiver and antenna witha digital interface to the CSA.
Backup Timing References
Timing signals from the High Stability Oscillator (HSO) or Medium
Stability Oscillator (MSO) are used in the event that the primary (GPS)
reference should become unavailable. The HSO or MSO clock is
calibrated against the GPS timing signal when a valid GPS timing signal
is available to provide the longest possible backup timing performance.
The CSA continuously monitors each available timing reference and
utilizes the most suited reference to maintain system synchronization.
Front Panel LEDs
Timing Source Fault Management
Fault management has the capability of switching between the GPS
synchronization source and the HSO/MSO backup source in the event of
a GPS receiver failure. During normal operation, the CSA selects GPS as
the primary timing source (Table 6-20). The source selection can also be
overridden via the WinLMF or by the system software.
The status of the LEDs on the CSA boards are as follows:
S Steady Green – CSA locked to GPS.
S Rapidly Flashing Green – Standby CSA locked to GPS.
S Flashing Green/Rapidly Flashing Red – CSA OOS–RAM attempting
to lock on GPS signal.
S Rapidly Flashing Green and Red – Alarm condition exists. Trouble
Notifications (TNs) are currently being reported to the GLI.
6
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CSA System Time – GPS & HSO/MSO Verification – continued
High Stability Oscillator /
Medium Stability Oscillator
(HSO/MSO)
General
CSA and HSO/MSO
The CSA utilizes timing signals provided by either an HSO or MSO to
maintain BTS synchronization during the absence of valid GPS timing
information. WHen a GPS timing signal is available the CSA is
responsible for calibration of the HSO or MSO clock to maximize the
backup timing interval. A minimum period of 24 hours of operation with
a valid GPS reference is required to fully calibrate the HSO backup
reference such that a 24 hour backup interval may be provided.
HSO
The HSO is a free–running backup oscillator that is capable of providing
a minimum backup interval of 24 hours.
MSO
The MSO is a free–running backup oscillator that is capable of providing
a minimum backup interval of 8 hours.
NOTE
6
Allow the base site and test equipment to warm up for 60
minutes after any interruption in oscillator power. CSA card
warm-up allows the oscillator oven temperature and oscillator
frequency to stabilize prior to test. Test equipment warm-up
allows the Rubidium standard time base to stabilize in frequency
before any measurements are made.
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CSA System Time – GPS & HSO/MSO Verification – continued
CSA Frequency Verification
The objective of this procedure is the initial verification of the Clock
Synchronization Alarms (CSA) Module before performing the RF path
verification tests.
Test Equipment Setup
(GPS & HSO/MSO Verification)
Follow the steps outlined in Table 6-19 to set up test equipment.
Table 6-19: Test Equipment Setup (GPS & HSO/MSO Verification)
Step Action
1 Perform one of the following as required by installed equipment:
1a – Verify a CSA card is installed in the CSA slot, and that the card is INS_ACT (bright green).
2 Connect a serial cable from the LMF COM 1 port (via null modem card) to the MMI port on the CSA
(see Figure 6-11).
3 Start an MMI communication session with the CSA by using the Windows desktop shortcut icon (see
Table 6-11) .
4 When the terminal screen appears press the Enter key until the CSA> prompt appears.
CAUTION
If the RF GPS module is uesd to take care to ensure that the GPS
antenna is properly connected to the GPS antenna connector
within the power entry compartment only. Damage to the GPS
antenna and/or GPS receiver can result if the GPS antenna is
inadvertently connected to any other RF connector.
6
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CSA System Time – GPS & HSO/MSO Verification – continued
Figure 6-11: CSA MMI Terminal Connection
CSA card shown
removed from frame
SYNC MONITOR
FREQ. MONITOR
TO FRONT
PANEL
9–PIN TO 9–PIN
RS–232 CABLE
NULL MODEM
BOARD
(TRN9666A)
FW00372
LMF
NOTEBOOK
6
DB9–TO–DB25
ADAPTER
NOTES:
COM1
1. One LED on each CSA:
Green = IN–SERVICE ACTIVE
Fast Flashing Green = OOS–RAM
Red = Fault Condition
Flashing Green & Red = Fault
RS–232 SERIAL
MODEM CABLE
GPS Initialization/Verification
Prerequisites
Ensure the following prerequisites have been met before proceeding:
S The CSA and HSO/MSO (if equipped) has been warmed up for at
least 15 minutes.
S The LMF computer is connected to the MMI port of the CSA as
shown in Figure 6-11.
S An MMI communication session has been started (Table 6-11), and
CSA> prompt is present in the HyperTerminal window
the
(Table 6-19).
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CSA System Time – GPS & HSO/MSO Verification – continued
Follow the steps outlined in Table 6-20 to initialize and verify proper
GPS receiver functioning.
Table 6-20: GPS Initialization/Verification
Step Action
1 To verify that Clock alarms (0000), Dpll is locked and has a reference source, and
GPS self test passed messages are displayed within the report, issue the following MMI
command
bstatus
– The system will display a response similar to the following:
Clock Alarms (0000):
DPLL is locked and has a reference source.
GPS receiver self test result: passed
Time since reset 0:33:11, time since power on: 0:33:11
2 Enter the following command at the CSA> prompt to display the current status of the GPS receiver and
HSO or MSO backup reference:
sources
– When equipped with HSO, the system will generate a response similar to the following:
N Source Name Type TO Good Status Last Phase Target Phase Valid
–––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––
0
LocalGPS Primary 4 YES Good 00Yes
1 HSO Backup 4 YES Good –2013177 –2013177 Yes
2 Not Used
*NOTE “Timed–out” should only be displayed while the HSO is warming up. If the HSO does not
appear as one of the sources, then configure the HSO as a back–up source by entering the following
command at the CSA> prompt:
ss 1 12
The HSO or MSO must complete an initial warmup and calibration cycle before being usable as a
backup reference source. The intial warmup cycle should be completed in less than 15 minutes. During
the warmup cycle, the HSO clock output is disabled and indicated as being “timed out” in the
following response to the “sources command:
43:26:15 CSA>sources
43:26:35
43:26:35 N Source Name Type TO Good Status Last Phase Target Phase Valid
43:26:35–––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––
43:26:35 0 Local GPS Primary 59 Yes Good 0 0 Yes
43:26:35 1 HSO Backup –25 No Bad timed out unknown No
43:26:35 2 Not Used
43:26:35 Current reference source number: 0
6
See 2–Cont.
. . . continued on next page
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CSA System Time – GPS & HSO/MSO Verification – continued
Table 6-20: GPS Initialization/Verification
Step Action
2–
At the completion of the HSO warmup cycle, the HSO clcok output is enabled allowing califd clock
Cont
6
pulses to be detected by the CSA. An integer value should then be displayed in the HSO “Last Phase”
entry of the “sources” command as show below. If the HSO or MSO calibration cycle is not completed
within 2 hours it will be necessary to inspect the HSO or MSO hardware.
43:29:33 CSA>sources
43:29:43
43:29:43 N Source Name Type TO Good Status Last Phase Target Phase Valid
43:29:43 ––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––
43:29:43 0 Local GPS Primary 59 Yes Good 0 0 Yes
43:29:43 1 HSO Backup 3 Yes Bad –xxxxxx –xxxxxx No
43:29:43 2 Not Used
43:29:43 Current reference source number: 0
The HSO or MSO calibration cycle can take as long as 2 hours to complete. The completion of the
HSO or MSO calibration is indicated by a “yes” value in the valid column of the “sources” command
response as shown below. If the HSO or MSO calibration cycle is not complete within 2 hours it will
be necessary to inspect the HSO or MSO hardware.
26:09:33 CSA>sources
26:09:35
26:09:35 N Source Name Type TO Good Status Last Phase Target Phase Valid
26:09:35 ––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––
26:09:35 0 Local GPS Primary 59 Yes Good 0 0 Yes
26:09:35 1 HSO
26:09:35 2 Not Used
26:09:35 Current reference source number: 0
Backup 3 Yes Bad 8683466 8683466 Yes
HSO information (underlined text above, verified from left to right) is usually the #1 reference source.
3
If this is not the case, have the OMC–R determine the correct BTS timing source has been identified in
the database by entering the display bts csmgen command and correct as required using the edit
csm csmgen refsrc command.
NOTE
If any of the above areas fail, verify:
– Verify that HSO had been powered up for at least 15 minutes.
– If “timed out” is displayed in the Last Phase column, suspect the HSO output buffer or oscillator
is defective
– Verify the HSO is FULLY SEATED and LOCKED.
4 Verify the following GPS information (underlined text above):
– GPS information is usually the 0 reference source.
– At least one Primary source must indicate “Status = good” and “Valid = yes” to bring site up.
. . . continued on next page
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CSA System Time – GPS & HSO/MSO Verification – continued
Table 6-20: GPS Initialization/Verification
Step Action
5 Enter the following command at the CSA> prompt to verify that the GPS receiver is in tracking mode.
gstatus
– Observe the following typical response:
27:27:11 CSA>gstatus
27:27:14 GPS Receiver Control Task State: tracking satellites.
27:27:14 Time since last valid fix: 0 seconds
27:27:14 Frame type (0): master
27:27:14
27:27:14 Recent Change Data:
27:27:14 GPS time offset 0 ns.
27:27:14 Initial position: lat 151679000 msec, lon: –316798000 msec, height 0 cm
(GPS)
27:27:14 Initial position accuracy (0): estimated.
27:27:14
27:27:14 GPS Receiver Status
27:27:14 Position hold: lat 151679326 msec, lon: –316798498 msec, hgt 21955 cm
27:27:14 Current position: lat 151679326 msec, lon: –316798498 msec, hgt 21955 cm
(GPS)
27:27:14 8 satellites tracked, receiving 8 satellites, 8 satellites visible.
27:27:14 Current Dilution of Precision (PDOP or HDOP): 0
27:27:14 Date & Time: 2004:03:16:21:37:48 LS:13
27:27:14 GPS Receiver Status Byte:0x8400
27:27:14 Chan:0, SVID: 24, Mode: 8, RSSI: 42, Status: 0x08a1
27:27:14 Chan:1, SVID: 10, Mode: 8, RSSI: 49, Status: 0x08a0
27:27:14 Chan:2, SVID: ––, Mode: –, RSSI: –––, Status: 0x0000
27:27:14 Chan:3, SVID: 21, Mode: 8, RSSI: 48, Status: 0x08a1
27:27:14 Chan:4, SVID: 26, Mode: 8, RSSI: 50, Status: 0x08a0
27:27:14 Chan:5, SVID: 29, Mode: 8, RSSI: 48, Status: 0x08a0
27:27:14 Chan:6, SVID: 18, Mode: 8, RSSI: 42, Status: 0x08a0
27:27:14 Chan:7, SVID: 17, Mode: 8, RSSI: 50, Status: 0x08a0
27:27:14 Chan:8, SVID: 6, Mode: 8, RSSI: 49, Status: 0x08a0
27:27:14 Chan:9, SVID: ––, Mode: –, RSSI: –––, Status: 0x0000
27:27:14 Chan:10, SVID: ––, Mode: –, RSSI: –––, Status: 0x0000
27:27:14 Chan:11, SVID: ––, Mode: –, RSSI: –––, Status: 0x0000
27:27:14
6
6 Verify the following GPS information (shown above in underlined text):
– At least 4 satellites are tracked, and 4 satellites are visible.
– GPS Receiver Control Task State is “tracking satellites”. Do not continue until this occurs!
– Dilution of Precision indication is not more that 30.
Record the current position base site latitude, longitude, height and height reference (height reference
to Mean Sea Level (MSL) or GPS height (GPS). (GPS = 0 MSL = 1).
. . . continued on next page
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CSA System Time – GPS & HSO/MSO Verification – continued
Table 6-20: GPS Initialization/Verification
Step Action
7 If steps 1 through 6 pass, the GPS is good.
NOTE
If any of the above mentioned areas fail, verify that:
– If Initial position accuracy is “estimated”
visible (1 satellite must be tracked and visible if actual lat, log, and height data for this site has
been entered into CDF file).
– If Initial position accuracy is “surveyed,”
improper GPS receiver timing may occur.
– The GPS antenna is not obstructed or misaligned.
– GPS antenna connector center conductor measureS approximately +5 Vdc with respect to the
shield.
– There is no more than 15 dB of loss between the GPS antenna OSX connector and the BTS frame
GPS input.
– Any lightning protection installed between GPS antenna and BTS frame is installed correctly.
(typical), at least 4 satellites must be tracked and
position data must be of sufficient accuracy or
8 Enter the following commands at the CSA> prompt to verify that the CSA is warmed up and that GPS
acquisition has taken place.
debug dpllp
Observe the following typical response if the CSA is not warmed up (15 minutes from application of
power) (If warmed–up proceed to step 9)
6
CSA>DPLL Task Wait. 884 seconds left.
DPLL Task Wait. 882 seconds left.
DPLL Task Wait. 880 seconds left. ...........etc.
NOTE
The warm command can be issued at the MMI port used to force the CSA into warm–up, but the
reference oscillator will be unstable.
9 Observe the following typical response if the CSA is warmed up.
c:17486 off: –11, 3, 6 TK SRC:0 S0: 3 S1:–2013175,–2013175
c:17486 off: –11
c:17470 off: –11
c:17486 off: –11
c:17470 off: –11
c:17470 off: –11
10 Verify the following GPS information (underlined text above, from left to right):
– Lower limit offset from tracked source variable is not less than –60 (equates to 3µs limit).
– Upper limit offset from tracked source variable is not more than +60 (equates to 3µs limit).
– TK SRC: 0 is selected, where SRC 0 = GPS.
, 3, 6 TK SRC:0 S0: 3 S1:–2013175,–2013175
, 1, 6 TK SRC:0 S0: 1 S1:–2013175,–2013175
, 3, 6 TK SRC:0 S0: 3 S1:–2013175,–2013175
, 1, 6 TK SRC:0 S0: 1 S1:–2013175,–2013175
, 1, 6 TK SRC:0 S0: 1 S1:–2013175,–2013175
11 Enter the following commands at the CSA> prompt to exit the debug mode display.
debug dpllp
6-50 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU Jun 2004
DRAFT
Page 87
Test Equipment Setup
Connecting T est Equipment to
the BTS
The following types of test equipment are required to perform calibration
and ATP tests:
S WinLMF
S Communications system analyzer model supported by the WinLMF
S Power meter model supported by the WinLMF (required when using
the HP 8921A/600 and Advantest R3465 analyzers)
S Non–radiating transmit line termination load
S Directional coupler and in–line attenuator
S RF cables and adapters
Refer to Table 6-21 for an overview of connections for test equipment
currently supported by the WinLMF. In addition, see the following
figures:
S Figure 6-15, Figure 6-17, and Figure 6-18 show the test set
connections for TX calibration
S Figure 6-19 through Figure 6-22 show the test set connections for
optimization/ATP tests
Test Equipment GPIB Address
Settings
Supported T est Equipment
CAUTION
All test equipment is controlled by the WinLMF through an
IEEE–488/GPIB bus. To communicate on the bus, each piece of test
equipment must have a GPIB address set which the WinLMF will
recognize. The standard address settings used by the WinLMF for the
various types of test equipment items are as follows:
S Signal generator address: 1
S Power meter address: 13
S Communications system analyzer: 18
Using the procedures included in the Verifying and Setting GPIB
Addresses section of Appendix B, verify and, if necessary, change the
GPIB address of each piece of employed test equipment to match the
applicable addresses above
To prevent damage to the test equipment in high power
configurations, all transmit (TX) test connections must be
through a 30 dB directional coupler plus a 20 dB in-line
attenuator for the 800 MHz BTSs.
Attenuators are not required for low power configurations.
.
6
IS–95A/B Operation
Optimization and ATP testing for IS–95A/B sites or carriers may be
performed using the following test equipment:
Jun 2004 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU 6-51
DRAFT
Page 88
Test Equipment Setup – continued
S CyberTest (High Power Configurations only)
S Advantest R3267 spectrum analyzer with R3562 signal generator
S Advantest R3465 spectrum analyzer with R3561L signal generator
and HP–437B or Gigatronics Power Meter
S Agilent E4406A transmitter test set with E4432B signal generator
S Agilent 8935 series E6380A communications test set (formerly HP
8935)
S Hewlett–Packard HP 8921 (with CDMA interface and, for 1.9 GHz,
PCS Interface) and HP–437B or Gigatronics Power Meter
S Spectrum Analyzer (HP8594E) – optional
S Rubidium Standard Timebase – optional
CDMA2000 1X Operation
Optimization and ATP testing for CDMA2000 1X sites or carriers may
be performed using the following test equipment:
S Advantest R3267 spectrum analyzer with R3562 signal generator
S Agilent E4406A transmitter test set with E4432B signal generator
S Agilent 8935 series E6380A communications test set (formerly HP
8935) with option 200 or R2K and with E4432B signal generator for
1X FER
S Agilent E7495A communications test set
6
Test Equipment Preparation
See Appendix B for specific steps to prepare each type of test set and
power meter to perform calibration and ATP.
Agilent E7495A communications test set requires additional setup and
preparation. This is described in detail in Appendix B.
6-52 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU Jun 2004
DRAFT
Page 89
Test Equipment Setup – continued
Test Equipment Connection
Charts
To use the following charts to identify necessary test equipment
connections, locate the communications system analyzer being used in
COMMUNICATIONS SYSTEM ANALYZER columns, and read down
the
the column. Where a dot appears in the column, connect one end of the
test cable to that connector. Follow the horizontal line to locate the end
connection(s), reading up the column to identify the appropriate
equipment and/or BTS connector.
IS–95A/B–only Test Equipment Connections
Table 6-21 depicts the interconnection requirements for currently
available test equipment supporting IS–95A/B only which meets
Motorola standards and is supported by the WinLMF.
Table 6-21: IS–95A/B–only Test Equipment Interconnection
COMMUNICATIONS SYSTEM ANALYZER ADDITIONAL TEST EQUIPMENT
SIGNAL
Cyber–Test
Advantest
R3465 HP 8921A
HP 8921
W/PCS
Power
Meter
GPIB
Interface
WinL
MF
Attenuator
&
Directional
Coupler
BTS
EVEN SECOND
SYNCHRONIZATION
19.6608 MHZ
CLOCK
CONTROL
IEEE 488 BUS
TX TEST
CABLES
EVEN
SEC REF
TIME
BASE IN
IEEE
488
RF
IN/OUT
EVEN SEC
SYNC IN
CDMA
TIME BASE
IN
GPIB GPIB
INPUT
50W
EVEN
SECOND
SYNC IN
CDMA
TIME BASE
IN
HP–I
B
RF
IN/OUT
EVEN
SECOND
SYNC IN
CDMA
TIME BASE
IN
HP–IB
RF
IN/OUT
HP–IB
SERIAL
PORT
20 DB
ATTEN.
BTS
PORT
SYNC
MON-
ITOR
FREQ
MON-
ITOR
TX1–6
6
RX TEST
CABLESRFGEN OUT
RF OUT
50W
DUPLEX
OUT
RF OUT
ONLY
RX1–6
Jun 2004 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU 6-53
DRAFT
Page 90
Test Equipment Setup – continued
CDMA2000 1X/IS–95A/B–capable Test Equipment
Connections
Table 6-22 depicts the interconnection requirements for currently
available test equipment supporting both CDMA 2000 1X and
IS–95A/B which meets Motorola standards and is supported by the
WinLMF.
Table 6-22: CDMA2000 1X/IS–95A/B Test Equipment Interconnection
COMMUNICATIONS SYSTEM ANALYZER ADDITIONAL TEST EQUIPMENT
Agilent
SIGNAL
EVEN SECOND
SYNCHRONIZATION
8935 (Op-
tion 200
or R2K)
EXT
TRIG IN
Agilent
E7495A
EVEN
SECOND
SYNC IN
Advan
test
R3267
EXT
TRIG
Agilent
E4406A
TRIGGER
IN
Agilent
E4432B
Signal
Generator
PATTERN
TRIG IN
Advant-
est
R3562
Signal
Genera-
tor
EVEN
SECOND
SYNC IN
Power
Meter
GPIB
Inter-
face
WinL
MF
30 dB
Directional
Coupler &
20 dB Pad*
BTS
SYNC
MONI
TOR
19.6608 MHZ
CLOCK
CONTROL
IEEE 488 BUS
MOD TIME
BASE IN
IEEE
488
EXT REF
IN
GPIB HP–IB GPIB
HP–IB
GPIB
EXT REF
IN
HP–IB
SERIAL
PORT
FREQ
MONITOR
6
10 MHZ
SIGNAL SOURCE
CONTROLLED
SERIAL I/O
TX TEST
CABLES
RX TEST
CABLES
10 MHZ IN
RF
IN/OUT
DUPLEX
OUT *
PORT 2
RF IN
PORT 1
RF OUT
10 MHZ
SERIAL
RF OUT
50–OHM
10 MHZ OUT
(SWITCHED)
OUT
I/O
RF INPUT
RF IN TX1–6
50 OHM
RF OUT
ONLY
10 MHZ IN
RF OUTPUT
50 OHM
RF OUTPUT
50–OHM
SYNTHE
REF IN
SERIAL
I/O
RF IN/OUT
RF OUT
50 OHM
30 DB COUPLER
AND 20 DB PAD
RX1–6
* WHEN USED ALONE, THE AGILENT 8935 WITH OPTION 200 OR R2K SUPPORTS IS–95A/B RX TESTING BUT NOT CDMA2000 1X RX TESTING.
6-54 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU Jun 2004
DRAFT
Page 91
Test Equipment Setup – continued
Equipment Warm-up
IMPORTANT
*
Warm-up BTS equipment for a minimum of 60 minutes
prior to performing the BTS optimization procedure. This
assures BTS stability and contributes to optimization
accuracy.
– Agilent E7495A for a minimum of 30 minutes
– All other test sets for a minimum of 60 minutes
– Time spent running initial or normal power-up,
hardware/firmware audit, and BTS download counts
as warm-up time.
WARNING
Before installing any test equipment directly to any BTS
TX OUT connector, verify there are no CDMA channels
keyed.
– At active sites, have the OMC-R/CBSC place the
antenna (sector) assigned to the BBX under test OOS.
Failure to do so can result in serious personal injury
and/or equipment damage.
Automatic Cable Calibration
Set–up
Manual Cable Calibration
6
Figure 6-21 and Figure 6-22 show the cable calibration setup for the test
sets supported by the WinLMF. The left side of the diagram depicts the
location of the input and output connectors of each test equipment item,
and the right side details the connections for each test. Table 6-24
provides a procedure for performing automatic cable calibration.
If manual cable calibration is required, refer to the procedures in
Appendix B.
Jun 2004 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU 6-55
DRAFT
Page 92
Test Equipment Setup – continued
Figure 6-12: IS–95A/B and CDMA 2000 1X Cable Calibration Test Setup –
Á
Agilent E4406A/E4432B and Advantest R3267/R3562
SUPPORTED TEST SETS
CALIBRATION SET UP
Motorola CyberTest
A. SHORT CABLE CAL
RF GEN OUTANT IN
Note: The 30 dB directional coupler is not used
with the Cybertest test set. The TX cable is
connected directly to the Cybertest test set.
A 10dB attenuator must be used with the short test
cable for cable calibration with the CyberTest test
set. The 10dB attenuator is used only for the cable
calibration procedure, not with the test cables for
TX calibration and ATP tests.
Agilent 8935 Series E6380A
(formerly HP 8935)
6
ANT
IN
RF
IN/OUT
B. RX TEST CAL SETUP
SHORT
CABLE
SHORT
CABLE
N–N FEMALE
ADAPTER
TEST
SET
TEST
SET
RX
CABLE
Advantest Model R3465
Hewlett Packard Model HP 8921A
DUPLEX
OUT
Note: For 800 MHZ only. The HP8921A cannot
be used to calibrate cables for PCS frequencies.
ANT
IN
RF OUT 50Ω
INPUT 50Ω
C. TX TEST AND RX TEST CAL SETUP
100–WATT (MIN)
NON–RADIATING
RF LOAD
TX CABLE FOR
TX TEST CABLE
CALIBRATION
50 Ω
ΤERM.
SHORT
CABLE
RX CABLE FOR
DRDC RX TEST
CABLE CALIBRATION
DIRECTIONAL
COUPLER
(30 DB)
20 DB IN–LINE
ATTENUATOR
N–N FEMALE
ADAPTER
TX
CABLE
TEST
SET
6-56 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU Jun 2004
DRAFT
Page 93
Test Equipment Setup – continued
Figure 6-13: CDMA2000 1X Cable Calibration Test Setup – Agilent E7495A
SUPPORTED TEST SETS
Agilent E7495A
A. SHORT CABLE CAL
D. RX and TX TEST SETUP
100–WATT (MIN)
Power REF
GPIO
Port 2
RF In
Serial 1
Serial 2
50 MHz
Sensor
In
Even Second
Sync In
GPS
Antenna
power adapter
Port 1
RF Out / SWR
Use only
Agilent supplied
Ext Ref
NON–RADIATING
RF LOAD
CALIBRATION SET UP
10 DB PAD
SHORT
CABLE
10 DB PAD
50 Ω
ΤERM.
SHORT
CABLE
DIRECTIONAL
COUPLER
(30 DB)
20 DB IN–LINE
ATTENUATOR
10 DB PAD
N–N FEMALE
ADAPTER
TEST
SET
TX
CABLE
PORT 2
RF IN
PORT 1
RF OUT
TX CABLE FOR
TX TEST CABLE
CALIBRATION
RX CABLE FOR
DRDC RX TEST
CABLE CALIBRATION
10 DB PAD
TEST
SET
6
Jun 2004 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU 6-57
DRAFT
Page 94
Test Equipment Setup – continued
Figure 6-14: IS–95A/B and CDMA 2000 1X Cable Calibration Test Setup – Agilent E4406A/E4432B
and Advantest R3267/R3562
SUPPORTED TEST SETS
Agilent E4432B (Top) and E4406A (Bottom)
NOTE:
10 MHZ IN ON REAR OF SIGNAL GENERATOR IS CONNECTED TO
10 MHZ OUT (SWITCHED) ON REAR OF TRANSMITTER TESTER
(FIGURE B-18).
RF OUTPUT
50 Ω
RF INPUT
50 Ω
CALIBRATION SET UP
A. SHORT CABLE CAL
SHORT
CABLE
B. RX TEST SETUP
N–N FEMALE
ADAPTER
SHORT
CABLE
TEST
SET
TEST
SET
RX
CABLE
6
Advantest R3267 (Top) and R3562 (Bottom)
NOTE:
SYNTHE REF IN ON REAR OF SIGNAL GENERATOR IS
CONNECTED TO 10 MHZ OUT ON REAR OF SPECTRUM
ANALYZER
INPUT 50 Ω
RF OUT
50 Ω
D. TX TEST SETUP AND RX TEST SETUP
100–WATT (MIN)
NON–RADIATING
RF LOAD
TX CABLE FOR
TX TEST CABLE
CALIBRATION
50 Ω
ΤERM.
SHORT
CABLE
RX CABLE FOR
DRDC RX TEST
CABLE CALIBRATION
DIRECTIONAL
COUPLER
(30 DB)
20 DB IN–LINE
ATTENUATOR
N–N FEMALE
ADAPTER
TX
CABLE
TEST
SET
6-58 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU Jun 2004
DRAFT
Page 95
Test Equipment Setup – continued
TEST SETS TRANSMIT (TX) SET UP
Set-up for TX Calibration
Figure 6-15 and Figure 6-17 show the test set connections for TX
calibration.
Figure 6-15: TX Calibration Test Setup –
CyberTest (IS–95A/B) and Agilent 8935 (IS–95A/B and CDMA2000 1X)
Motorola CyberTest
100–WATT (MIN.)
NON–RADIATING
RF LOAD
FRONT PANEL
NOTE: THE 30 DB DIRECTIONAL COUPLER IS NOT
USED WITH THE CYBERTEST TEST SET. THE TX
CABLE IS CONNECTED DIRECTLY TO THE
CYBERTEST TEST SET.
Agilent 8935 Series E6380A (formerly HP 8935)
IN/OUT
HP–IB
TO GPIB
BOX
RF
50 Ω
TERM
.
HIGH POWER
CONNECTION
RX OUT
CONNECTOR
TX TEST
CABLE
ANTENNA
CONNECTOR
TX TEST
CABLE
DIRECTIONAL
COUPLER
(30 DB)
0–20 DB
IN–LINE
ATTENUATOR
POWER
SENSOR
RF IN/OUT
Power Meter
(OPTIONAL)*
Communications
System Analyzer
* A POWER METER CAN BE USED IN
PLACE OF THE COMMUNICATIONS
TEST SET FOR TX CALIBRATION/
AUDIT
LOW POWER
CONNECTION
GPIB
GPIB
CABLE
6
* BLACK RECTANGLES
REPRESENT THE RAISED
PART OF SWITCHES
DIP SWITCH SETTINGS
BAUD RATE
ON
DATA FORMAT
S MODE
ANT
IN
RF
IN/OUT
cCLPA
TX IN
CONNECTOR
TX 1RX DIV
NOTE:
TO PERFORM LOW POWER CALIBRA TION
THE POWER METER IS ADEQUATE FOR
MEASUREMENT PURPOSES WITHOUT
USING THE 30 DB DIRECTIONAL COUPLER
AND 0–20 DB ATTENUATOR.
IF THE AGILENT 8935 MUST BE USED,
THEN CONNECT TO THE ANT IN PORT.
BTS
LAN
A
LAN
B
FREQ
MONITOR
SYNC
MONITOR
CSA
GPIB ADRS G MODE
RS232–GPIB
INTERFACE BOX
RS232 NULL
MODEM
CABLE
CDM
WinLMF
Jun 2004 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU 6-59
DRAFT
Page 96
Test Equipment Setup – continued
Figure 6-16: TX Calibration Test Setup – Agilent E7495A (IS–95A/B and CDMA2000 1X)
TEST SETS TRANSMIT (TX) SET UP
Agilent E7495A
NOTE: IF BTS IS EQUIPPED
WITH DUPLEXED RX/TX
SIGNALS, CONNECT THE TX
TEST CABLE TO THE
DUPLEXED ANTENNA
CONNECTOR.
POWER
SENSOR
POWER METER
PORT 1
RF OUT
COMMUNICATIONS
system analyzer
100–WATT (MIN.)
NON–RADIATING
RF LOAD
TX TEST
CABLE
DIRECTIONAL
50 Ω
TERM
.
HIGH POWER
Power REF
GPIO
Port 2
RF In
6
PORT 2
RF IN
Serial 1
Serial 2
SYNC MONITOR
EVEN SEC TICK
PULSE REFERENCE
FROM CSM BOARD
50 MHz
Sensor
In
Even Second
Sync In
GPS
Antenna
power adapter
Port 1
RF Out / SWR
PORT 1
RF OUT
Use only
Agilent supplied
Ext Ref
CONNECTION
RX OUT
CONNECTOR
ANTENNA
CONNECTOR
COUPLER
(30 DB)
TX TEST
CABLE
TX IN
CONNECTOR
2O DB IN–LINE
ATTENUATOR
PORT 2
RF IN
LOW POWER
CONNECTION
ETHERNET HUB
INTERNAL
ETHERNET
CARD
RX DIV
LAN
LAN
A
B
10BASET/
10BASE2
CONVERTER
UNIVERSAL TWISTED PAIR (UTP)
CABLE (RJ45 CONNECTORS)
TX 1
FREQ
MONITOR
SYNC
MONITOR
CSA
BTS
CDMA
WinLMF
6-60 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU Jun 2004
DRAFT
Page 97
Test Equipment Setup – continued
Figure 6-17: TX Calibration Test Setup – Using Power Meter
TEST SETS TRANSMIT (TX) SET UP
NOTE:
THE HP8921A AND ADVANTEST R3465
CANNOT BE USED FOR TX CALIBRATION. A
POWER METER MUST BE USED.
NOTE:
TO PERFORM LOW POWER CALIBRA TION
THE 30 DB DIRECTIONAL COUPLER AND
0–20 DB ATTENUATOR ARE NOT REQUIRED.
Hewlett Packard Model HP 8921A
(for 800 MHz)
ANT
IN
NOTE:
TO PERFORM LOW POWER CALIBRATION
USING THE HP8921A, CONNECT TO THE
ANT IN PORT. THE 30 DB DIRECTIONAL
COUPLER AND 0–20 DB ATTENUATOR ARE
NOT REQUIRED.
50 Ω
TERM
.
HIGH POWER
CONNECTION
RX OUT
CONNECTOR
cCLPA
100–WATT (MIN.)
NON–RADIATING
RF LOAD
TX TEST
CABLE
ANTENNA
CONNECTOR
TX IN
CONNECTOR
TX 1RX DIV
TX TEST
CABLE
DIRECTIONAL
COUPLER
(30 DB)
0–20 DB IN–LINE
ATTENUATOR
POWER
SENSOR
Power Meter
LOW POWER
CONNECTION
* BLACK RECTANGLES
REPRESENT THE RAISED
PART OF SWITCHES
DIP SWITCH SETTINGS
DATA FORMAT
BAUD RATE
ON
GPIB
CABLE
S MODE
6
BTS
LAN
A
LAN
B
FREQ
MONITOR
SYNC
MONITOR
CSA
GPIB ADRS G MODE
RS232–GPIB
INTERFACE BOX
RS232 NULL
MODEM
CABLE
CDMA
WinLMF
Jun 2004 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU 6-61
DRAFT
Page 98
Test Equipment Setup – continued
TEST SETS TRANSMIT (TX) SET UP
Figure 6-18: TX Calibration Test Setup –
Agilent E4406A and Advantest R3567 (IS–95A/B and CDMA2000 1X)
POWER
Agilent E4406A
NOTE: IF BTS IS EQUIPPED
WITH DRDCS (DUPLEXED
RX/TX SIGNALS), CONNECT
THE TX TEST CABLE TO
THE DRDC ANTENNA
CONNECTOR.
100–WATT (MIN.)
NON–RADIATING
RF LOAD
SENSOR
RF INPUT 50 Ω
OR INPUT 50 Ω
TX TEST
CABLE
DIRECTIONAL
TX TEST
CABLE
ANTENNA
COUPLER
(30 DB)
0–20 DB
IN–LINE
ATTENUATOR
Advantest R3267
RF INPUT
50 Ω
50 Ω
TERM
.
HIGH POWER
CONNECTION
RX OUT
CONNECTOR
CONNECTOR
POWER
METER
(OPTIONAL)*
Communications
SystemAanalyzer
GPIB
* A POWER METER CAN BE USED IN
PLACE OF THE COMMUNICATIONS
TEST SET FOR TX CALIBRATION/
AUDIT
LOW POWER
CONNECTION TO
EITHER THE
POWER METER
OR ANALYZER
GPIB
CABLE
6
cCLPA
INPUT 50 Ω
NOTE:
TO PERFORM LOW POWER CALIBRATION THE POWER
METER IS ADEQUATE FOR MEASUREMENT PURPOSES
WITHOUT USING THE 30 DB DIRECTIONAL COUPLER AND
0–20 DB ATTENUATOR.
BTS
LAN
A
LAN
B
TX IN
CONNECTOR
TX 1RX DIV
FREQ
MONITOR
SYNC
MONITOR
CSA
* BLACK RECTANGLES
REPRESENT THE RAISED
PART OF SWITCHES
DIP SWITCH SETTINGS
BAUD RATE
ON
RS232–GPIB
INTERFACE BOX
DATA FORMAT
GPIB ADRS G MODE
RS232 NULL
MODEM
CABLE
CDMA
WinLMF
S MODE
6-62 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU Jun 2004
DRAFT
Page 99
Test Equipment Setup – continued
Set–up for A TP
Figure 6-19 and Figure 6-20 show the test set connections for ATP tests.
Figure 6-19: IS–95A/B ATP Test Set–up–
CyberTest, Advantest R3465, and Agilent 8935
TEST SETS Optimization/ATP SET UP
Motorola CyberTest
SYNC MONITOR
EVEN SEC TICK
PULSE REFERENCE
FROM CSA CARD
RF
IN/OUT
NOTE: The 30 dB directional coupler is not
used with the Cybertest test set. The TX
cable is connected directly to the Cybertest
test set.
Advantest Model R3465
SYNC MONITOR EVEN
SEC TICK PULSE
REFERENCE FROM CSA
CARD
BNC
“T”
FREQ MONITOR
19.6608 MHZ CLOCK
REFERENCE FROM
CSA CARD
RF GEN
OUT
FREQ MONITOR
19.6608 MHZ CLOCK
REFERENCE FROM
CSA CARD
RF OUT 50Ω
GPIB CONNECTS
TO BACK OF UNIT
IMPORTANT:
WHEN PERFORMING LOW POWER TESTING BYPASS THE COUPLER AND
ATTENUATOR AND CONNECT DIRECTLY TO THE ANALYZER.
RX TEST
CABLE
NOTE: IF BTS IS EQUIPPED
WITH DRDCS (DUPLEXED RX/TX
SIGNALS), BOTH THE TX AND RX
TEST CABLES CONNECT TO THE
DRDC ANTENNA CONNECTOR.
(SEE FIGURE 6-22.)
100–WATT (MIN.)
NON–RADIATING
RF LOAD
50 Ω
TERM
.
HIGH POWER
CONNECTION
ANTENNA
RF GEN OUT,
RF OUT 50Ω,
OR RF IN/OUT
DIRECTIONAL
COUPLER
(30 DB)
0–20 DB IN–LINE
ATTENUATOR
TX TEST
CABLE
RF IN/OUT
OR
INPUT 50 Ω
TX TEST
CABLE
Communications
System Analyzer
EXT
REF IN
cCLPA
EVEN
SECOND/
SYNC IN
GPIB
GPIB
CABLE
6
MONITOR
MONITOR
B
TX IN
FREQ
SYNC
CSA
BTS
* BLACK RECTANGLES
REPRESENT THE RAISED
PART OF SWITCHES
DIP SWITCH SETTINGS
BAUD RATE
ON
RS232–GPIB
INTERFACE BOX
DATA FORMAT
GPIB ADRS G MODE
RS232 NULL
MODEM
CABLE
CDMA
WinLMF
S MODE
INPUT 50Ω
TO EXT TRIGGER CONNECTOR
ON REAR OF TEST SET
(FOR DETAILS, SEE
FIGURE B-15)
Agilent 8935 Series E6380A (formerly HP 8935)
SYNC MONITOR
EVEN SEC TICK
PULSE REFERENCE
FROM CSA CARD
ANT
IN
FREQ MONITOR
19.6608 MHZ CLOCK
REFERENCE FROM
CSA CARD
10 MHZ
REF OUT
RF IN/OUT
HP–IB
TO GPIB
BOX
RX OUT
RX MAINRX DIV TX1
LAN
LAN
A
Jun 2004 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU 6-63
DRAFT
Page 100
Test Equipment Setup – continued
Figure 6-20: IS–95A/B ATP Test Setup – HP 8921A
TEST SETS Optimization/ATP SET UP
Hewlett Packard Model HP 8921A W/PCS Interface
(for 1900 MHz)
SYNC MONITOR
EVEN SEC TICK
PULSE REFERENCE
FROM CSA CARD
FREQ MONITOR
19.6608 MHZ CLOCK
REFERENCE FROM
CSA CARD
GPIB
CONNECTS
TO BACK OF
UNITS
RX TEST
CABLE
100–WATT (MIN.)
NON–RADIATING
RF LOAD
RF OUT ONLY
PCS INTERFACE
INPUT/OUTPUT
PORTS
RF IN/OUT
TX TEST
CABLE
Signal
Generator
INTERFACE*
Communications
System Analyzer
EXT
REF IN
EVEN
SECOND/
SYNC IN
HP PCS
GPIB
RF
IN/OUT
RF OUT
ONLY
Hewlett Packard Model HP 8921A
50 Ω
TERM
.
DIRECTIONAL
COUPLER
(30 DB)
* FOR 1900 MHZ
ONLY
(for 800 MHz)
SYNC MONITOR
EVEN SEC TICK
PULSE REFERENCE
FROM CSA CARD
6
RF
IN/OUT
DUPLEX
OUT
NOTE:
FOR 800 MHZ TESTING, CONNECT CABLES TO THE
HP 8921A AS FOLLOWS:
RX TEST CABLE TO DUPLEX OUT
TX TEST CABLE TO RF IN/OUT
FREQ MONITOR
19.6608 MHZ CLOCK
REFERENCE FROM
CSA CARD
ANT
IN
GPIB
CONNECTS
TO BACK OF
UNIT
cCLPA
RX OUT
RX MAINRX DIV TX1
LAN
LAN
A
B
ANTENNA
FREQ
MONITOR
SYNC
MONITOR
TX TEST
CABLE
TX IN
CSA
BTS
0–20 DB IN–LINE
ATTENUATOR
* BLACK RECTANGLES
REPRESENT THE RAISED
PART OF SWITCHES
DIP SWITCH SETTINGS
BAUD RATE
ON
RS232–GPIB
INTERFACE BOX
DATA FORMAT
GPIB ADRS G MODE
RS232 NULL
MODEM
CABLE
CDMA
WinLMF
GPIB
CABLE
S MODE
6-64 1X SC480 BTS Hardware Installation, Optimization/ATP, and FRU Jun 2004
DRAFT
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