Nokia Solutions and Networks T5CT1 Cellular CDMA base station User Manual IHET5CT1 GLI2 Manual 6 of 6

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Document Description	IHET5CT1 GLI2 Manual 6 of 6
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Document Type	User Manual
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Date Submitted	2002-11-01 00:00:00
Date Available	2002-10-31 00:00:00
Creation Date	2002-11-01 17:07:58
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Document Lastmod	2002-11-01 17:08:14
Document Title	IHET5CT1 GLI2 Manual 6 of 6

RF Cabinet Interconnect Cables – continued
Figure H-14: SC 4812ET BTS Combiner DRDC/TRDC Cable Connection
Dual Bandpass Filter
6 Sector – 1 or 2 Carrier
4B
1–1B 3064735A11 6 Sec
2–2B 3064735A07 6 Sec
3–3B 3064735A07 6 Sec
4A
1B
1A
5B
5A
2B
2A
6B
6A
3B
3A
1–1A 3064735A11 6 Sec
2–2A 3064735A07 6 Sec
3–3A 3064735A07 6 Sec
4–4B 3064735A12 6 Sec
5–5B 3064735A11 6 Sec
6–6B 3064735A07 6 Sec
4–4A 3064735A12 6 Sec
5–5A 3064735A11 6 Sec
6–6A 3064735A07 6 Sec
COMBINER CAGE
3B
2B
1B
3A
6B
5B
4B
6A
2A
5A
1A
4A
FW00707
DRDCs
Jan 2002
SC
4812ET BTS Optimization/ATP — CDMA LMF
H-19
RF Cabinet Interconnect Cables
– continued
MPC Functional Description
The MPC card provides (see Figure H-15) low-noise amplification for
all RX path signals. The low noise, high gain design improves frame RX
sensitivity and overcomes the splitting loss in the receive path. DC
voltages are monitored on the RF devices and regulators and are used to
generate hard and soft alarms. The MPC is not redundant at the
card–level, but includes dual–path amplifiers which provide soft–fail
redundancy for all sectors.
MPC to DRDC Cabling
The cables connecting the MPC cards to the DRDCs for a three sector
RF cabinet are shown in Figure H-15. A six sector RF cabinet would
have six more DRDC’s and they would be connected to the front of the
MPC cards.
H-20
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4812ET BTS Optimization/ATP — CDMA LMF
Jan 2002
RF Cabinet Interconnect Cables – continued
Figure H-15: DRDC To C–CCP Cage MPC Boards Cable Connections
MPC BOARDS
SC 4812ET
RF Cabinet
ETIB
EBA
RFDS
5 RU RACK
SPACE
CABLES CONNECT
1A, 2A, 3A TO TOP
MPC BOARD
# 3086659H01
CABLES CONNECT
1B, 2B, 3B TO
BOTTOM MPC BOARD
# 3086659H01
1A – 3A: CABLE # 3086659H01
1B – 3B: CABLE # 3086659H01
3B
2B
1B
3A
2A
1A
* Use Cable 3086659H02
For Sectors 4 – 6
DRDC CAGE
Jan 2002
SC
4812ET BTS Optimization/ATP — CDMA LMF
FW00710
H-21
RF Cabinet Interconnect Cables
– continued
RFDS Cabling Details
Figure H-16 shows the components of the RFDS. Table H-2 depicts the
cabling for a 3-Sector Duplexed configuration and Table H-3 depicts the
cabling for a 6-Sector Duplexed configuration. Figure H-17 shows the
connection of the RFDS to the BTS combiners.
Figure H-16: RFDS Cable Connectors
HANDLE
FWTIC
AMR BUS/POWER
Cable #
3064794A05 CONNECTOR (LR485)
(See Figure H-9)
ASU2
SUBSCRIBER
UNIT ASSEMBLY
ASU1
ÇÇ
ÇÇ
Å
MCX CABLE DETAIL
(See Figure H-17)
P2
REFL/ANT PORTS 1
THROUGH 6
(See Figure H-17)
MCX
CONNECTOR
TO ASU
P3
FWD/BTS PORTS
1 THROUGH 6
(See Figure H-17)
SMA CONNECTORS
TO DRDC BTS OR
ANT PORTS
KNURLED
LOCK
SCREWS
CONNECTS to P2 AND
P3 OF ASU1 AND ASU2
FW00217–REF
Table H-2: SC 4812ET Series 3-Sector Duplexed Directional Coupler to RFDS Cabling Table
DRDC Label
1A BTS
1B BTS
2A BTS
2B BTS
3A BTS
3B BTS
1A ANT
1B ANT
2A ANT
2B ANT
3A ANT
3B ANT
H-22
Directional Coupler Port
ASU 1 – FWD (six pack MCX)
Sector 1 Main BTS
Sector 1 Diversity BTS
Sector 2 Main BTS
Sector 2 Diversity BTS
Sector 3 Main BTS
Sector 3 Diversity BTS
ASU 1 – REF (six pack MCX)
Sector 1 Main ANT
Sector 1 Diversity ANT
Sector 2 Main ANT
Sector 2 Diversity ANT
Sector 3 Main ANT
Sector 3 Diversity ANT
Cobra RFDS Port
ASU1–FWD
ASU1–FWD
ASU1–FWD
ASU1–FWD
ASU1–FWD
ASU1–FWD
BTS–1
BTS–2
BTS–3
BTS–4
BTS–5
BTS–6
ASU1–REF ANT–1
ASU1–REF ANT–2
ASU1–REF ANT–3
ASU1–REF ANT–4
ASU1–REF ANT–5
ASU1–REF ANT–6
SC
4812ET BTS Optimization/ATP — CDMA LMF
Jan 2002
RF Cabinet Interconnect Cables – continued
Table H-3: SC 4812ET Series 6-Sector Duplexed Directional Coupler to RFDS Cabling Table
DRDC Label
Directional Coupler Port
Cobra RFDS Port
ASU 1 – FWD (six pack MCX)
1A BTS
Sector 1 Main BTS
ASU1–FWD BTS–1
1B BTS
Sector 1 Diversity BTS
ASU1–FWD BTS–2
2A BTS
Sector 2 Main BTS
ASU1–FWD BTS–3
2B BTS
Sector 2 Diversity BTS
ASU1–FWD BTS–4
3A BTS
Sector 3 Main BTS
ASU1–FWD BTS–5
3B BTS
Sector 3 Diversity BTS
ASU1–FWD BTS–6
ASU 2 – FWD (six pack MCX)
4A BTS
Sector 4 Main BTS
ASU2–FWD BTS–1
4B BTS
Sector 4 Diversity BTS
ASU2–FWD BTS–2
5A BTS
Sector 5 Main BTS
ASU2–FWD BTS–3
5B BTS
Sector 5 Diversity BTS
ASU2–FWD BTS–4
6A BTS
Sector 6 Main BTS
ASU2–FWD BTS–5
6B BTS
Sector 6 Diversity BTS
ASU2–FWD BTS–6
ASU 1 – REF (six pack MCX)
1A ANT
Sector 1 Main ANT
ASU1–REF ANT–1
1B ANT
Sector 1 Diversity ANT
ASU1–REF ANT–2
2A ANT
Sector 2 Main ANT
ASU1–REF ANT–3
2B ANT
Sector 2 Diversity ANT
ASU1–REF ANT–4
3A ANT
Sector 3 Main ANT
ASU1–REF ANT–5
3B ANT
Sector 3 Diversity ANT
ASU1–REF ANT–6
ASU 2 – REF (six pack MCX)
Jan 2002
4A ANT
Sector 4 Main ANT
ASU2–REF ANT–1
4B ANT
Sector 4 Diversity ANT
ASU2–REF ANT–2
5A ANT
Sector 5 Main ANT
ASU2–REF ANT–3
5B ANT
Sector 5 Diversity ANT
ASU2–REF ANT–4
6A ANT
Sector 6 Main ANT
ASU2–REF ANT–5
6B ANT
Sector 6 Diversity ANT
ASU2–REF ANT–6
SC
4812ET BTS Optimization/ATP — CDMA LMF
H-23
RF Cabinet Interconnect Cables
– continued
Figure H-17: SC 4812ET BTS Combiner DRDC/TRDC RFDS Cable Connection
BTS COUPLED
TO RFDS ASU 1
(See Figure H-16)
ANT COUPLED
TO RFDS ASU 1
(See Figure H-16)
BTS COUPLED
TO RFDS ASU 2
(See Figure H-16)
3B
2B
1B
3A
6B
5B
4B
6A
2A
5A
TO RFDS
ASU1 & ASU2
1A
4A
DRDC CAGE
FW00709
ANT COUPLED
TO RFDS ASU 2
(See Figure H-16)
H-24
SC
4812ET BTS Optimization/ATP — CDMA LMF
Jan 2002
RF Cabinet Interconnect Cables – continued
50 Pair Punchblock
The 50 pair punchblock is the main interface point for RGPS, span lines,
customer I/O, Power Cabinet alarm lines, and the modem. The
punchblock provides primary protection for all lines. Refer to
Figure H-18 and Table H-4 for punchblock pin–out.
CAUTION
SC4812ET Span Line Labeling for Span B and Span C is
swapped
– On the SC4812ET’s, the span cabel internal to the base
station that connects the 50 pin header on the I/O plate to
the CSU has Span B and Span C (RJ–45) connectors
mis–labeled.
– CFE will punch down the span on the 50 pair bunchblock
as per Motorola documentation and punchdown chart.
When conecting the span input to the CSU re–label
“Span B” cable to”Span C” cable to “Span B”. Connect
to CSU as per documentation
– Note: The labeling issue on the cable from the I/O plate
to the CSU Part Number 3086601H01 Rev C shall be
corrected on revision “D” to address this issue. The cut
over date to Rev. D will be approximately January 30,
2001.
CAUTION
A wiring discrepancy exists between the manuals and the
frame for remote GPS.
– The TX and RX are reversed in the ETIB, leading to inoperability of the RGPS. The RGPS will not work in either a single standalone or multiple frame configuration.
– Swap the White and White/Bk wires to punch pins 44T
and 44R. The Green and Green/Bk go to 45T and 45R.
This will correct non–expansion configurations.
– Single frame and expansion BTSs without RGPS can use
this workaround as a permanent solution.
– For expansion with RGPS required a new cable (P/N
3086433H10 ) will correct the problem.
Jan 2002
SC
4812ET BTS Optimization/ATP — CDMA LMF
H-25
RF Cabinet Interconnect Cables
– continued
Figure H-18: 50 Pair Punchblock
TO MODEM
CONNECTOR TO ALARMS
CONNECTOR
STRAIN RELIEVE
INCOMING CABLE TO
BRACKET WITH TIE WRAPS
TO SPAN
CONNECTOR
RF Cabinet I/O Area
TO RGD/RGPS
CONNECTOR
TOP VIEW OF
PUNCH BLOCK
2R
2T
LEGEND
1T = PAIR 1 – TIP
1R = PAIR 1 –RING
”
”
”
”
”
”
1R
1T
SeeTable H-4
for Pin–Out.
49T
49R
50T
1T 1R 2T 2R
50R
FW00162–REF
H-26
SC
4812ET BTS Optimization/ATP — CDMA LMF
Jan 2002
RF Cabinet Interconnect Cables – continued
Alarm and Span Line Cable
Pin/Signal Information
Table H-4 lists the complete pin/signal identification for the 50–pin
punch block.
Table H-4: Pin–Out for 50–Pair Punchblock
Punchblock
Cable
Connector
Signal Name
Punch Pin
Function
Power Cabinet
ALARM
HSO/LFR
Extension
LFR Antenna
Pilot Beacon
Ext. Cable Wire
Color
Power Cab Control – NC
1T
Blue
Power Cab Control – NO
1R
Blk/Blue
Power Cab Control–Com
2T
Yellow
Reserved
2R
N/C
Rectifier Fail
3T
Blk/Yellow
AC Fail
3R
Green
Power Cab Exchanger Fail
4T
Blk/Grn
Power Cab Door Alarm
4R
White
Power Cab Major Alarm
5T
Blk/White
Battery Over Temp
5R
Red
Power Cab Minor Alarm
6T
Blk/Red
Reticifier Over Temp
6R
Brown
Power Cab Alarm Rtn
7T
Blk/Brn
LFR_HSO_GND
7R
EXT_1PPS_POS
8T
EXT_1PPS_NEG
8R
CAL_+
9T
CAB_–
9R
LORAN_+
10T
LORAN_–
10R
Pilot Beacon Alarm – Minor
11T
Pilot Beacon Alarm – Rtn
11R
Pilot Beacon Alarm – Major
12T
Pilot Beacon Control–NO
12R
Pilot Beacon Control – COM
13T
Pilot Beacon Control – NC
13R
. . . continued on next page
Jan 2002
SC
4812ET BTS Optimization/ATP — CDMA LMF
H-27
RF Cabinet Interconnect Cables
– continued
Table H-4: Pin–Out for 50–Pair Punchblock
Punchblock
Cable
Connector
ALARM
Signal Name
Punch Pin
Function
Customer Outputs
Customer Outputs 1 – NO
14T
Customer Outputs 1 – COM
14R
Customer Outputs 1 – NO
14T
Customer Outputs 1 – COM
14R
Customer Outputs 1 – NC
15T
Customer Outputs 2 – NO
15R
Customer Outputs 2 – COM
16T
Customer Outputs 2 – NC
16R
Customer Outputs 3 – NO
17T
Customer Outputs 3 – COM
17R
Customer Outputs 3 – NC
18T
Customer Outputs 4 – NO
18R
Customer Outputs 4–COM
19T
Customer Outputs 4 – NC
19R
Ext. Cable Wire
Color
. . . continued on next page
H-28
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4812ET BTS Optimization/ATP — CDMA LMF
Jan 2002
RF Cabinet Interconnect Cables – continued
Table H-4: Pin–Out for 50–Pair Punchblock
Punchblock
Cable
Connector
ALARM
Signal Name
Punch Pin
Function
Customer Inputs
Customer Inputs 1
20T
Cust_Rtn_A_1
20R
Customer Inputs 2
21T
Cust_Rtn_A_2
21R
Customer Inputs 3
22T
Cust_Rtn_A_3
22R
Customer Inputs 4
23T
Cust_Rtn_A_4
23R
Customer Inputs 5
24T
Cust_Rtn_A_5
24R
Customer Inputs 6
25T
Cust_Rtn_A_6
25R
Customer Inputs 7
26T
Cust_Rtn_A_7
26R
Customer Inputs 8
27T
Cust_Rtn_A_8
27R
Customer Inputs 9
28T
Cust_Rtn_A_9
28R
Customer Inputs 10
29T
Cust_Rtn_A_10
29R
Ext. Cable Wire
Color
. . . continued on next page
Jan 2002
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4812ET BTS Optimization/ATP — CDMA LMF
H-29
RF Cabinet Interconnect Cables
– continued
Table H-4: Pin–Out for 50–Pair Punchblock
Punchblock
Cable
Connector
Signal Name
Punch Pin
Function
Span 1
Span 2
Span 3
SPAN I/O
Span 4
Span 5
Span 6
RCV_TIP_A
30T
RCV_RING_A
30R
XMIT_TIP_A
31T
XMIT_RING_A
31R
RCV_TIP_B
32T
RCV_RING_B
32R
XMIT_TIP_B
33T
XMIT_RING_B
33R
RCV_TIP_C (Note)
34T
RCV_RING_C (Note)
34R
XMIT_TIP_C (Note)
35T
XMIT_RING_C(Note)
35R
RCV_TIP_D (Note)
36T
RCV_RING_D (Note)
36R
XMIT_TIP_D (Note)
37T
XMIT_RING_D(Note)
37R
RCV_TIP_E (Note)
38T
RCV_RING_E (Note)
38R
XMIT_TIP_E (Note)
39T
XMIT_RING_E(Note)
39R
RCV_TIP_F (Note)
40T
RCV_RING_F (Note)
40R
XMIT_TIP_F (Note)
41T
XMIT_RING_F(Note)
41R
Ext. Cable Wire
Color
NOTE
Span 3 through 6 are spares for expansion purposes
. . . continued on next page
H-30
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4812ET BTS Optimization/ATP — CDMA LMF
Jan 2002
RF Cabinet Interconnect Cables – continued
Table H-4: Pin–Out for 50–Pair Punchblock
Punchblock
Cable
Connector
Signal Name
Punch Pin
Function
Ext. Cable Wire
Color
GPS_Power_A
42T
Yellow
GPS_Power_A_Return
42R
Yellow/Black
GPS_Power_B
43T
Blue
GPS_Power_B_Return
43R
Blue/Black
GPS_TXD+
44T
White
GPS_TXD–
44R
White/Black
GPS_RXD+
45T
Green
GPS_RXD–
45R
Green/Black
Signal Ground (TDR+)
46T
Red
Signal Ground (TDR–)
46R
Red/Black
GPS_1PPS+
47T
Brown
GPS_1PPS–
47R
Brown/Black
GPS_Power_A
42T
Yellow
GPS_Power_A_Return
42R
Yellow/Black
GPS_Power_B
43T
Blue
GPS_Power_B_Return
43R
Blue/Black
GPS_TXD+
44T
White
GPS_TXD–
44R
White/Black
GPS_RXD+
45T
Green
GPS_RXD–
45R
Green/Black
Signal Ground (TDR+)
46T
Red
Master Frame (TDR–)
46R
Red/Black
GPS_1PPS+
47T
Brown
GPS_1PPS–
47R
Brown/Black
Reserved
48T
MODEM
Reserved
48R
RGD/RGPS
Chassis Ground
49T
N/A
None
No Connection
49R
None
Reserved
50T
None
Reserved
50R
None
RGD/RGPS
RGD/RGPS
ALARM
Jan 2002
For frame
without RGD
Expansion
Punchblock
Single Frame
BTS;RGPS Head
Connection
OR
Multiple Frame
BTS; RGD
Connection at
RGPS Secondary
Frame
For frame with
RGD Expansion
Punchblock
OR
Multiple Frame
BTS; RGPS Head
Connection at
RGPS Primary
Frame
SC
4812ET BTS Optimization/ATP — CDMA LMF
H-31
RF Cabinet Interconnect Cables
– continued
Figure H-19: SC 4812ET RF Cabinet Parts Locator
INDEX:
1. Door Switch
2. Door Switch (Main)
3. DC Power Distribution
4. EBA Blower Assembly
FW00440–REF
H-32
SC
4812ET BTS Optimization/ATP — CDMA LMF
Jan 2002
Appendix I: GPIB Addresses
Appendix Content
GPIB Addresses
Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
HP437 Power Meter GPIB Address . . . . . . . . . . . . . . . . . . . . . . . . . . .
Gigatronics 8541C Power Meter GPIB Address . . . . . . . . . . . . . . . . . .
Motorola CyberTest GPIB Address . . . . . . . . . . . . . . . . . . . . . . . . . . . .
HP8935 Test Set GPIB Address . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Setting HP8921A and HP83236A/B GPIB Address . . . . . . . . . . . . . . .
Advantest R3465 GPIB Address . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
RS232 GPIB Interface Box . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
I-1
I-1
I-2
I-3
I-4
I-6
I-8
I-9
CDMA 2000 Test Equipment Preparation
Advantest R3267 Spectrum Analyzer GPIB Address . . . . . . . . . . . . . .
Advantest R3562 Signal Generator GPIB Address . . . . . . . . . . . . . . . .
Agilent E4406A Transmitter Tester GPIB Address . . . . . . . . . . . . . . . .
Agilent E4432B Signal Generator GPIB Address . . . . . . . . . . . . . . . . .
I-10
I-11
I-12
I-14
Jan 2002
SC
4812ET BTS Optimization/ATP — CDMA LMF
Table of Contents
– continued
Notes
SC
4812ET BTS Optimization/ATP — CDMA LMF
Jan 2002
GPIB Addresses
Introduction
Use the procedures in this appendix to verify and/or change the GPIB
addresses of the applicable test equipment.
HP437 Power Meter GPIB
Address
Follow the steps in Table I-1 to verify and, if necessary, change the
HP437 GPIB address.
NOTE
This procedure assumes that the test equipment is set up
and ready for testing.
Table I-1: Verify and/or Change HP437 Power Meter GPIB Address
Step
Action
Press Shift and PRESET (see Figure I-1).
Use the arrow key to navigate to HP–IB ADRS and press ENTER.
The HP–IB address is displayed.
NOTE
HP–IB is the same as GPIB.
If the current GPIB address is not set to 13, perform the following to change it:
– Use the
arrow keys to change the HP–IB ADRS to 13.
– Press ENTER to set the address.
Press Shift and ENTER to return to a standard configuration.
Figure I-1: HP437 Power Meter
PRESET
SHIFT (BLUE) PUSHBUTTON –
ACCESSES FUNCTION AND
DATA ENTRY KEYS IDENTIFIED
WITH LIGHT BLUE TEXT ON
THE FRONT PANEL ABOVE
THE BUTTONS
ENTER
Jan 2002
SC
4812ET BTS Optimization/ATP — CDMA LMF
REF FW00308
I-1
GPIB Addresses – continued
Gigatronics 8541C Power
Meter GPIB Address
Follow the steps in Table I-2 to verify and, if necessary, change the
Gigatronics 8541C power meter GPIB address.
NOTE
This procedure assumes that the test equipment is set up
and ready for testing.
Table I-2: Verify and/or Change Gigatronics 8541C Power Meter GPIB Address
Step
Action
! CAUTION
Do not connect/disconnect the power meter sensor cable with AC power applied to the meter.
Disconnection could result in destruction of the sensing element or miscalibration.
Press MENU (see Figure I-2).
Use the
Use the arrow key to select GPIB and press ENTER.
The current Mode and GPIB Address are displayed.
If the Mode is not set to 8541C, perform the following to change it:
Use the
arrow keys as required to select MODE.
Use the
arrow keys as required to set MODE to 8541C.
If the GPIB address is not set to 13, perform the following to change it:
Use the arrow key to select ADDRESS.
Use the
arrow keys as required to set the GPIB address to 13.
Press ENTER to return to normal operation.
arrow key to select CONFIG MENU and press ENTER.
Figure I-2: Gigatronics 8541C Power Meter Detail
MENU
I-2
ENTER
ARROW
KEYS
SC
4812ET BTS Optimization/ATP — CDMA LMF
REF FW00564
Jan 2002
GPIB Addresses – continued
Motorola CyberTest GPIB
Address
Follow the steps in Table I-3 to verify and, if necessary, change the
GPIB address on the Motorola CyberTest. Changing the GPIB address
requires the following items:
Motorola CyberTest communications analyzer
Computer running Windows 3.1/Windows 95
Motorola CyberTAME software program “TAME”
Parallel printer port cable (shipped with CyberTest)
NOTE
This procedure assumes that the test equipment is set up
and ready for testing.
Table I-3: Verify and/or Change Motorola CyberTest GPIB Address
Step
Action
On the LMF desktop, locate the CyberTAME icon. Double click on the icon to run the CyberTAME
application.
In the CyberTAME window taskbar, under Special, select IEEE.488.2.
CyberTAME software will query the CyberTest Analyzer for its current GPIB address. It then will
open the IEEE 488.2 dialog box. If the current GPIB address is not 18, perform the following
procedure to change it:
– Use the up or down increment arrows, or double–click in the field and type the number.
– Click on the OK button.
The new address will be written to the CyberTest via the parallel port and saved.
NOTE
Verify that the address has been set by repeating steps 2 and 3. The new address should now appear in
the IEEE 488.2 dialog box Address field.
Jan 2002
SC
4812ET BTS Optimization/ATP — CDMA LMF
I-3
GPIB Addresses – continued
HP8935 Test Set GPIB
Address
Follow the procedure in Table I-4 to verify and, if necessary, change the
HP8935 GPIB address.
NOTE
This procedure assumes that the test equipment is set up
and ready for testing.
Table I-4: Verify and/or Change HP8935 GPIB Address
Step
Action
* IMPORTANT
The HP I/O configuration MUST be set to Talk & Listen, or NO device on the GPIB bus will be
accessible. (Consult test equipment OEM documentation for additional information as required.)
To verify that the GPIB addresses are set correctly, press Shift and LOCAL on the HP8935 (see
Figure I-3). The current HP–IB address is displayed at the top of the screen.
NOTE
HP–IB is the same as GPIB.
If the current GPIB address is not set to 18, perform the following to change it:
– Press Shift and Inst Config.
– Turn the Cursor Control knob to move the cursor to the HP–IB Adrs field.
– Press the Cursor Control knob to select the field.
– Turn the Cursor Control knob as required to change the address to 18.
– Press the Cursor Control knob to set the address.
 Press Preset to return to normal operation.
I-4
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4812ET BTS Optimization/ATP — CDMA LMF
Jan 2002
GPIB Addresses – continued
Figure I-3: HP8935 Test Set
Preset
Local
Inst Config
Shift
Cursor Control
FW00885
Jan 2002
SC
4812ET BTS Optimization/ATP — CDMA LMF
I-5
GPIB Addresses – continued
Setting HP8921A and
HP83236A/B GPIB Address
Follow the procedure in Table I-5 to verify and, if necessary, change the
HP8921A HP83236A GPIB addresses.
NOTE
This procedure assumes that the test equipment is set up
and ready for testing.
Table I-5: Verify and/or Change HP8921A and HP83236A GPIB Addresses
Step
Action
To verify that the GPIB addresses are set correctly, press Shift and LOCAL on the HP8921A (see
Figure I-4). The current HP–IB address is displayed at the top of the screen.
NOTE
HP–IB is the same as GPIB.
If the current HP–IB address is not set to 18, perform the following to change it:
– Turn the Cursor Control knob to move the cursor to More and press the knob to select the field.
– Turn the Cursor Control knob to move the cursor to I/O Config and press the knob to select the
field.
– Turn the Cursor Control knob to move the cursor to Adrs and press the knob to select the field.
– Turn the Cursor Control knob to change the HP–IB address to 18 and press the knob to set the
address.
– Press Shift and Preset to return to normal operation.
To set the HP83236A (or B) PCS Interface GPIB address=19, set the dip switches as follows:
– A1=1, A2=1, A3=0, A4=0, A5=1, HP–IB/Ser = 1
I-6
SC
4812ET BTS Optimization/ATP — CDMA LMF
Jan 2002
GPIB Addresses – continued
Figure I-4: HP8921A and HP83236A/B
Local
Preset
Shift
Cursor Control
Jan 2002
SC
4812ET BTS Optimization/ATP — CDMA LMF
I-7
GPIB Addresses – continued
Advantest R3465 GPIB
Address
Table I-6 describes the steps to verify and, if necessary, change the GPIB
address for the Advantest R3465.
NOTE
This procedure assumes that the test equipment is set up
and ready for testing.
Table I-6: Verify and/or Change Advantest R3465 GPIB Address
Step
Action
To verify that the GPIB address is set correctly, perform the following procedure:
– Press SHIFT then PRESET (see Figure I-5).
– Press LCL.
– Press the GPIB and Others CRT menu key to view the current address.
If the current GPIB address is not set to 18, perform the following to change it:
– Turn the vernier knob as required to select 18.
– Press the vernier knob to set the address.
To return to normal operation, press Shift and Preset.
Figure I-5: R3465 Communications Test Set
GPIB and others
REF UNLOCK
EVEN
SEC/SYNC IN
CDMA
TIME BASE IN
POWER
BNC
“T”
OFF
ON
Vernier
Knob
LCL
I-8
Shift
Preset
REF FW00337
SC
4812ET BTS Optimization/ATP — CDMA LMF
Jan 2002
GPIB Addresses – continued
RS232 GPIB Interface Box
Ensure that the RS232 GPIB interface box dip switches are set as shown
in Figure I-6.
Figure I-6: RS232 GPIB Interface Box
DIP SWITCH SETTINGS
S MODE
DATA FORMAT
BAUD RATE
ON
GPIB ADRS
G MODE
RS232–GPIB
INTERFACE BOX
Jan 2002
SC
4812ET BTS Optimization/ATP — CDMA LMF
I-9
CDMA 2000 Test Equipment Preparation
Advantest R3267 Spectrum
Analyzer GPIB Address
Perform the procedure in Table I-7 and refer to Figure I-7 to verify and,
if necessary, change the Advantest R3267 spectrum analyzer GPIB
address.
Table I-7: Verify and Change Advantest R3267 GPIB Address
Step
Action
If the REMOTE LED is lighted, press the LCL key.
– The LED turns off.
Press the CONFIG key.
– The CONFIG softkey labels will appear in the softkey label display area of the instrument
display.
– The current GPIB address will be displayed below the GPIB Address softkey label.
If the current GPIB address is not set to 18, perform the following to change it:
– Press the GPIB Address softkey.
–– A GPIB Address entry window will open in the instrument display showing the current
GPIB address.
– Enter 18 on the keypad in the ENTRY section of the instrument front panel.
–– Characters typed on the keypad will replace the address displayed in the GPIB Address
entry window.
3a
3b
NOTE
To correct an entry, press the BS (backspace) key at the lower right of the keypad to delete one
character at a time.
3c
– Press the ENTR key to the lower right of the keypad to enter the address.
–– The GPIB Address entry window closes.
–– The new address is diplayed in the bottom portion of the GPIB Address softkey label.
I-10
SC
4812ET BTS Optimization/ATP — CDMA LMF
Jan 2002
CDMA 2000 Test Equipment Preparation – continued
Figure I-7: Setting Advantest R3267 GPIB Address
Softkey Lable
Display Area
Softkey
Buttons
on
REMOTE
LED
LCL Key
CONFIG
Key
Keypad
BS
Key
ENTR
Key
Advantest R3562 Signal
Generator GPIB Address
Set the GP–IB ADDRESS switch on the rear of the Advantest R3562
signal generator to address 1 as shown in Figure I-8.
Figure I-8: Advantest R3562 GPIB Address Switch Setting
GPIB Address set to “1”
GP–IP ADDRESS
5 4 3 2 1
Jan 2002
SC
4812ET BTS Optimization/ATP — CDMA LMF
I-11
CDMA 2000 Test Equipment Preparation – continued
Agilent E4406A Transmitter
Tester GPIB Address
Follow the procedure in Table I-8 and refer to Figure I-9 to verify and, if
necessary, change the Agilent E4406A GPIB address.
Table I-8: Verify and Change Agilent E4406A GPIB Address
Step
Action
In the SYSTEM section of the instrument front panel, press the System key.
– The softkey labels displayed on the right side of the instrument screen will change.
Press the Config I/O softkey button to the right of the instrument screen.
– The softkey labels will change.
– The current instrument GPIB address will be displayed below the GPIB Address softkey label.
If the current GPIB address is not set to 18, perform the following to change it:
3a
– Press the GPIB Address softkey button.
–– In the on–screen Active Function Area, GPIB Address will be displayed followed by the
current GPIB address.
3b
– On the front panel Data Entry keypad, enter the communications system analyzer GPIB address of
18.
–– The GPIB Address label will change to Enter.
–– Digits entered with the keypad will replace the current GPIB address in the display.
NOTE
To correct an entry, press the Bk Sp key at the upper right of the keypad to delete one character at a
time.
3c
– Press the Enter softkey button or the keypad Enter key to set the new GPIB address.
–– The Config I/O softkey labels will reappear.
–– The new GPIB address will be displayed under the GPIB Address softkey label.
I-12
SC
4812ET BTS Optimization/ATP — CDMA LMF
Jan 2002
CDMA 2000 Test Equipment Preparation – continued
Figure I-9: Setting Agilent E4406A GPIB Address
Active Function
Area
Softkey Label
Display Area
Softkey
Buttons
System
Key
Data Entry
Keypad
Bk Sp
Key
Enter
Key
Jan 2002
SC
4812ET BTS Optimization/ATP — CDMA LMF
I-13
CDMA 2000 Test Equipment Preparation – continued
Agilent E4432B Signal
Generator GPIB Address
Follow the procedure in Table I-9 and refer to Figure I-10 to verify and,
if necessary, change the Agilent E4432B GPIB address.
Table I-9: Verify and Change Agilent E4432B GPIB Address
Step
Action
In the MENUS section of the instrument front panel, press the Utility key.
– The softkey labels displayed on the right side of the instrument screen will change.
Press the GPIB/RS232 softkey button to the right of the instrument screen.
– The softkey labels will change.
– The current instrument GPIB address will be displayed below the GPIB Address softkey label.
If the current GPIB address is not set to 1, perform the following to change it:
3a
– Press the GPIB Address softkey button.
–– The GPIB Address label and current GPIB address will change to boldface.
–– In the on–screen Active Entry Area, Address: will be displayed followed by the current
GPIB address.
3b
– On the front panel Numeric keypad, enter the signal generator GPIB address of 1.
–– The GPIB Address label will change to Enter.
–– Digits entered with the keypad will replace the current GPIB address in the Active Entry
display.
NOTE
To correct an entry, press the backspace key at the lower right of the keypad to delete one character at
a time.
3c
– Press the Enter softkey button to set the new GPIB address.
–– The new GPIB address will be displayed under the GPIB Address softkey label.
I-14
SC
4812ET BTS Optimization/ATP — CDMA LMF
Jan 2002
CDMA 2000 Test Equipment Preparation – continued
Figure I-10: Setting Agilent E4432B GPIB Address
Active Entry
Area
Softkey Label
Display Area
Utility
Key
Softkey
Buttons
Numeric
Keypad
Backspace
Key
Jan 2002
SC
4812ET BTS Optimization/ATP — CDMA LMF
I-15
CDMA 2000 Test Equipment Preparation – continued
Notes
I-16
SC
4812ET BTS Optimization/ATP — CDMA LMF
Jan 2002
Appendix J: Download ROM Code
Appendix Content
Downloading ROM Code with the LMF . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Exception Procedure – Downloading ROM Code . . . . . . . . . . . . . . . . .
J-1
J-1
Jan 2002
SC
4812ET BTS Optimization/ATP — CDMA LMF
Table of Contents
– continued
Notes
SC
4812ET BTS Optimization/ATP — CDMA LMF
Jan 2002
Downloading ROM Code with the LMF
Exception Procedure –
Downloading ROM Code
This procedure is not part of a normal optimization.
Perform this procedure only on an exception basis when no alternative
exists to load a BTS device with the correct version of ROM code.
NOTE
One GLI must be INS_ACT (bright green) before ROM
code can be downloaded to non–GLI devices.
CAUTION
The correct ROM and RAM codes for the software release
used on the BSS must be loaded into BTS devices. To
identify the correct device ROM and RAM code loads for
the software release being used on the BSS, refer to the
Version Matrix section of the SC
 CDMA Release Notes
(supplied on the tape or CD–ROM containing the BSS
software).
All devices in a BTS must be loaded with the ROM and
RAM code specified for the software release used on the
BSS before any optimization or ATP procedures can be
performed.
If a replacement device is loaded with ROM code which is
not compatible with the BSS software release being used,
the device ROM code can be changed using the LMF
before performing the BTS optimization and ATPs. A
device loaded with later release ROM code can not be
converted back to a previous release ROM code in the field
without Motorola assistance
If it is necessary to download ROM code to a device from the LMF, the
procedure in Table J-1 includes steps for both ROM and RAM code
download using the LMF.
Prerequisites
Prior to performing this procedure, ensure the correct ROM and RAM
code files exist in the LMF computer’s applicable :\\cdma\loads\\code folder for each of the devices
to be loaded.
Jan 2002
SC
4812ET BTS Optimization/ATP — CDMA LMF
J-1
Downloading ROM Code with the LMF – continued
CAUTION
The Release level of the ROM code to be downloaded
must be the one specified for the software release installed
in the BSS. The release level of the ROM code resident in
the other devices in the BTS must also be correct for the
BSS software release being used. ROM code must not be
downloaded to a frame loaded with code for a BSS
software release with which it is not compatible.
This procedure should only be used to upgrade
replacement devices for a BTS. It should NOT be used to
upgrade all devices in a BTS. If a BTS is to be upgraded
from R15.x to R16.0, the upgrade should be done by the
OMC–R using the DownLoad Manager.
Table J-1: Download ROM and RAM Code to Devices
Step
Action
Click on the device to be loaded.
NOTE
More than one device of the same type can be selected for download by either clicking on each one to
be downloaded or from the BTS menu bar Select pull–down menu, select the device item that applies.
Where: device = the type of device to be loaded (BBX, CSM, MCC)
From the BTS menu bar Device pull–down menu, select Status.
– A status report window will appear.
Make a note of the number in the HW Bin Type column.
NOTE
“HW Bin Type” is the Hardware Binary Type for the device. This code is used as the last four digits in
the filename of a device’s binary ROM code file. Using this part of the filename, the ROM code file
can be matched to the device in which it is to be loaded.
Click OK to close the status window.
Click on the device to be loaded.
* IMPORTANT
The LMF will not automatically select ROM code files for download. ROM code files must be
selected manually.
From the BTS menu bar Device pull–down menus, select Download > Code Manual.
– A file selection window will appear.
J-2
Double–click on the version folder with the desired version number for the ROM code file (for
example 2.16.0.x).
Double–click the Code folder.
– A list of ROM and RAM code files will be displayed.
. . . continued on next page
SC
4812ET BTS Optimization/ATP — CDMA LMF
Jan 2002
Downloading ROM Code with the LMF – continued
Table J-1: Download ROM and RAM Code to Devices
Step
Action
! CAUTION
A ROM code file with the correct HW Bin Type must be chosen. Using a file with the wrong HW Bin
Type can result in unpredictable operation and damage to the device.
10
Click on the ROM code file with the filename which matches the device type and HW Bin Type
number noted in step 3 (for example, file bbx_rom.bin.0604 is the ROM code file for a BBX with a
HW Bin Type of 0604).
– The file should be highlighted.
Click on the Load button.
– A status report window is displayed showing the result of the download.
NOTE
If the ROM load failed for some devices, load them individually by clicking on one device, perform
steps 6 through 10 for it, and repeat the process for each remaining device.
11
Click OK to close the status window.
12
From the LMF window menu bar Tools pull–down menus, select Update NextLoad > CDMA.
13
14
In the left–hand pane of the window which opens, click on the BTS number for the frame being loaded
(for example, BTS–14).
On the list of versions displayed in the right–hand pane, click the button next to the version number of
the folder that was used for the ROM code download (for example, 2.16.0.x) and click Save.
– A pop–up message will appear showing the CDF has been updated.
15
Click on the OK button to dismiss the pop–up message.
16
Click on the device that was loaded with ROM code.
NOTE
RAM code is automatically selected for download.
17
From the BTS menu bar Device pull–down menus, select Download > Code/Data to download RAM
code and dds file data.
– A status report is displayed showing the result of the download.
18
Click OK to close the status window.
19
Observe the downloaded non–GLI device to ensure it is OOS_RAM (yellow).
20
Click on the device which was loaded with code.
21
From the BTS menu bar Device pull–down menu, select Status.
Verify that the correct ROM and RAM version numbers are displayed in the status report window.
Click OK to close the status window.
22
Jan 2002
SC
4812ET BTS Optimization/ATP — CDMA LMF
J-3
Downloading ROM Code with the LMF – continued
Notes
J-4
SC
4812ET BTS Optimization/ATP — CDMA LMF
Jan 2002
K
Appendix K: Optimizing Companion Frame
Appendix Content
Optimizing Companion Frame
Optimizing the TX section of the Companion Frame – . . . . . . . . . . . .
Optimizing the RX section of the Companion Frame – . . . . . . . . . . . .
Jan 2002
SC
4812ET BTS Optimization/ATP — CDMA LMF
K-1
K-2
K
Table of Contents
– continued
Notes
SC
4812ET BTS Optimization/ATP — CDMA LMF
Jan 2002
Optimizing Companion Frame
Optimizing the TX section of
the Companion Frame –
The optimization/ATP procedure for the transmit side of the Companion
Frame is identical to that of the SC4812ET BTS.
Table K-1: Optimizing the TX section of the Companion Frame
Step
Action
Please refer to the TX Optimization/ATP – Chapter 3 of this manual for step–by–step TX
Optimization/ATP instructions for the standalone frame
Run the TX tests.
Figure K-1: Cabling of SC 4812ET Companion BTS to SC 4812ET Companion BTS (3 Sector)
ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ
Ì
Ï
ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ
Ì
Ï
ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ
Ï
Ì
ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ
Ì
Ï
ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÌÌÎÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÏÏ
ÌÌÎÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÏÏ
ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÏÏ
ÌÌ
ÏÏÎÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÌÌ
ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ
RX EXPANSION
RX
Ant–1A
C1
TX1
C2
C3
C4
RX1A
RX
Ant–2A
C1
TX2
C2
C3
C4
RX2A
RX
C1
TX3
Ant–3A
C2
C3
C4
RX3A
RX1A
RX2A
RX3A
MPC–A
EMPC–B
1A
2A
3A
1B
2B
3B
SC4812ET Companion
(Starter)
TX1
Ant–1A
C7
C8
RX1A
RX
C5
C6
TX2
C7
C8
Ant–2A
RX2A
TX3
Ant–3A
C7
C8
1A
2A
3A
RX
C5
C6
RX3A
MPC–A
RX1A
RX2A
RX3A
EMPC–B
1B
2B
3B
SC4812ET Companion
SURGE
ARRESTORS
Jan 2002
RX
C5
C6
SC
4812ET BTS Optimization/ATP — CDMA LMF
FW00407
K-1
K
Optimizing Companion Frame – continued
Optimizing the RX section of
the Companion Frame –
RX (Main) Optimization/ATP
To test the RX Main antenna system follow the instructions in Table K-2
and refer to illustration Figure K-1(3–sector configuration).
Table K-2: Optimizing the RX (Main) section of the Companion Frame
Step
Action
Connect the RX test cables to the antenna ports 1A–3A (for 3–sector optimization) or
antenna ports 1A–6A (for 6–sector optimization).
Login the LMF and select MPC (see Figure K-2 for display screen and field location).
Run the RX tests.
RX (Diversity) Optimization/ATP (Single Frame)
To test the RX Diversity antenna system follow the instructions in
Table K-3.
Table K-3: Optimizing the RX (Diversity) on a Single Frame
Step
Action
Connect the RX test cables to the expansion ports on the I/O plates labeled 1B–3B (for
3–sector optimization) or expansion ports 1B–6B (for 6–sector optimization).
Login the LMF under EMPC (see Figure K-2 for display screen and field location).
Run the RX tests.
RX (Diversity) Optimization/ATP (Two Frame)
To test the RX Diversity antenna configuration on a two frame
Companion BTS system follow the instructions in Table K-4.
Table K-4: Optimizing the RX (Diversity) on a Two Frame Companion Site
Step
Action
Connect RX expansion cables from the expansion ports on the other Companion frame
labeled 1A–3A (for 3–sector optimization) or expansion ports 1A–6A (for 6–sector
optimization) to the 1B–3B (for 3–sector optimization) or expansion ports 1B–6B (for
6–sector optimization) see Figure K-1 for an illustration of the configuration.
NOTE
Connect the cables from the 2nd frame A ports to the B ports of the 1st frame.
Login using the LMF select MPC (see Figure K-2 for field location on LMF display screen)
NOTE
– Although the test will be done to one frame, the RX cable will be connected to the
other frame’s corresponding antenna ports.
– The other frame has to be powered up and include all the RX Path Components.
K-2
SC
4812ET BTS Optimization/ATP — CDMA LMF
Jan 2002
Optimizing Companion Frame – continued
Figure K-2: WinLMF Display Screen
Jan 2002
SC
4812ET BTS Optimization/ATP — CDMA LMF
K-3
K
Optimizing Companion Frame – continued
Notes
K-4
SC
4812ET BTS Optimization/ATP — CDMA LMF
Jan 2002
Index
Numbers
test matrix/detailed optimization, B-1
10BaseT/10Base2 Converter, 1-7
ATP – Code Domain Power, 4-11
2–way Splitter, 1-11
ATP – Frame Error Rate (FER), 4-13
3–Sector Duplexed Directional Coupler to RFDS
Cabling Table, H-22
ATP – Pilot Time Offset, 4-10
ATP – Reduced, 4-2
4812ET RF Cabinet Internal FRU Locations, H-3
ATP – Spectral Purity Transmit Mask, 4-7
6–Sector Duplexed Directional Coupler to RFDS
Cabling Table, H-23
ATP – Waveform Quality (rho), 4-9
ATP Report, 4-14
ATP Test Procedure, 4-6
Acceptance Test Procedures ATP , 1-1
Acronyms, 1-11
Basic Troubleshooting Overview, 6-1
ACTIVE LED
GLI, 6-25
MCC, 6-27
Battery Charge Test (Connected Batteries), 2-10
Advantest R3465, 3-46
GPIB, I-8
BBX, gain set point vs SIF output considerations, C-1
Alarm and Span Line Cable Pin/Signal Information,
3-6
BBX2 Connector, 6-14
Battery Discharge Test, 2-10
Bay Level offset calibration failure, 6-6
BBX2, 1-19
ALARM LED, GLI, 6-25
BBX2 LED Status Combinations, 6-27
Alarm Monitor window, 3-99
Broad Band Receiver. See BBX
Alarm Reporting Display, 3-99
All Cal/Audit Test, 3-86
All inclusive, TX ATP test outline – CCP shelf 1,
primary, 4-14
All tests fail on a single antenna, Troubleshooting,
RFDS, 6-21
AMR, 1-19
Applying AC Power, 2-5
ATP
generate failure report, 4-14
generate report, 4-14
Jan 2002
BTS
download, 3-28
Ethernet LAN interconnect diagram, 3-19
LMF connection, 3-9, 3-17
system software download, 3-3
BTS Cabinet, 1-27
Create CAL File, 3-87
C–CCP Backplane, H-6
C–CCP Backplane Troubleshooting, Procedure, 6-14
C–CCP shelf, 1-19
SC
4812ET BTS Optimization/ATP — CDMA LMF
Index-1
Index
– continued
cable calibration, automatic, test set–up, 3-50, 3-51
Advantest R3267/R3562, 3-51
Advantest R3465, 3-50
Agilent 8935, 3-50
Agilent E4406A/E4432B, 3-51
CyberTest, 3-50
HP 8921A, 3-50
cdpower test, 4-11
Cables Connection for 10 MHz Signal and GPIB ,
F-2, F-4
Channel Service Unit, 3-4
Calibrate BLO, 3-73
CIO Connectors, 6-14
Calibrating Cables, 3-67
CLI, 1-2
Calibrating Test Cable Setup, PCS Interface
HP83236B, F-11
Clock Sync Module. See CSM
Calibrating Test Equipment, 3-67
Cell Site
equipage verification, 2-1
types configuration, 3-2
Cell Site Data File. See CDF
Cell Site Field Engineer CFE, 1-1
CIO, 1-19
Code Domain Power and Noise Floor Levels, 4-12
Code Domain Power/Noise, 4-11
Calibration
data file calibration, BLO, 3-75
In–Service, G-15
Communication test set, rear panel, F-2, F-4
Calibration Audit failure, 6-7
Communications system analyzer , 1-8
calibration data file, description of, BLO, 3-75
Components Located on CIO Card, H-10
Cannot communicate to Communications Analyzer,
6-3
Cannot communicate to Power Meter, 6-2
Communications System Analyzer, 1-8
Connecting test equipment to the BTS, 3-45
Connector Functionality
Backplane, Troubleshooting, 6-13
Troubleshooting, Backplane, 6-13
Cannot Download DATA to any device card, 6-4
Copy CAL Files From Diskette to the CBSC, 5-2
Cannot ENABLE device, 6-5
Copy CDF Files from CBSC, 3-12
Cannot Log into cell–site, 6-2
Copy Files from LMF to Diskette, 5-1
Cannot perform carrier measurement, 6-9
Copying CAL files from CDMA LMF to the CBSC,
5-1
Cannot perform Code Domain Noise Power
measurement, 6-9
Copying CAL files to the CBSC, 5-2
Cannot perform Rho or pilot time offset
measurement, 6-8
CSM, 1-19
and LFR primary functions, 3-35
Cannot perform Txmask measurement, 6-8
CSM frequency verification, 3-37
CCD, 1-19
CSM LED Status Combinations, 6-23
CCP, shelf 1 – all inclusive TX ATP test outline,
primary, 4-14
Customer I/O, 1-20
CDF
site configuration, 3-2
site equipage verification, 3-3
site type and equipage data information, 2-1
CyberTest Communication Analyzer, 1-8
CDMA
allocation diagram for the North American, cellular
telephone frequency spectrum, D-4
optimization/ATP test matrix, B-1
Index-2
CyberTest, 3-46
DC Power Pre–test (BTS Frame), 2-7
DC Power Problems, C–CCP Backplane
Troubleshooting, 6-17
DC/DC Converter LED Status Combinations, 6-22
SC
4812ET BTS Optimization/ATP — CDMA LMF
Jan 2002
Index
– continued
Detailed, optimization/ATP test matrix, B-1
Gigatronics 8542B power meter, illustration, I-2
Devices, download. See Download
Gigatronics Power Meter, 3-46
Digital Control Problems, 6-15
C–CCP Backplane Troubleshooting, 6-15
GLI. See Master (MGLI2) and Slave (SGLI2) Group
Line Interface
Digital Multimeter, 1-9
GLI Connector, 6-13
Directional Coupler, 1-9
GLI Ethernet A and B Connections, 6-14
Download
See also Devices
BTS, 3-28
BTS system software, 3-3
GLI LED Status Combinations, 6-25
GLI Pushbuttons and Connectors, 6-26
GLI2, 1-19
Download BLO Procedure, 3-81
download ROM and RAM code. See ROM code
Download/Enable MCCs, 3-34
Download/Enable MGLIs, 3-30
Duplexer/Directional Coupler DDC, 1-18, 1-19, 1-20,
1-21, 1-29
E1, isolate BTS from the E1 spans, 3-4
GLI2 Front Panel Operating Indicators, 6-26
GPIB, F-1, F-5, F-7
Advantest R3465, I-8
HP83236A/B, I-6
HP8921A, I-6
HP8935, I-4
power meter
Gigatronics 8542B, I-2
HP437B, I-1
set address, Motorola CyberTest, I-3
GPIB Cables, 1-8
GPS, receiver operation, test data sheets, A-5
Enable CSMs & BDCs, 3-32
GPS Initialization/Verification
estimated position accuracy, 3-38
surveyed position accuracy, 3-38
Equipment Overview, 1-14
Equipment warm-up, 3-49
GPS satellite system, 3-33
Ethernet LAN
interconnect diagram, 3-19
transceiver, 1-7
Graphical User Interface Overview , 3-21
Group Line Interface. See GLI
ETIB I/O Connectors, H-12
Every test fails, Troubleshooting, RFDS, 6-20
Hardware Requirements, 1-5
High Stability 10 MHz Rubidium Standard, 1-11
fer test, 4-13
High–impedance Conductive Wrist Strap, 1-10
Files, calibration data file, BLO, 3-75
HP 437B, 3-46
Folder Structure Overview, 3-13, 3-16
HP 83236A, F-5
Frame, equipage preliminary operations, 2-1
HP 8921, 3-46
FREQ Monitor Connector, CSM, 6-24
HP83236A/B, GPIB, I-6
Frequency counter, optional test equipment, 1-10
HP8921A, F-5
GPIB, I-6
HP8935, GPIB, I-4
Gain set point, C-1
HP8935 Analyzer, 1-8
General optimization checklist, test data sheets, A-4
HSO, 1-19
Jan 2002
SC
4812ET BTS Optimization/ATP — CDMA LMF
Index-3
Index
– continued
HSO Initialization/Verification, 3-35
LPAC Interface Board, H-11
I and Q values, E-1
major components, 1-17
In–Service Calibration, G-15
test set–up diagrams
DRDC, Advantest, 3-58
TRDC, Advantest, 3-60
Manual, layout, 1-1
Master Group Line Interface. See MGLI
MASTER LED, GLI, 6-25
MCC LED Status Combinations, 6-27
Initial HP8921A setup, F-11
MCC/CE, 4-11
Initial Installation of Boards/Modules, preliminary
operations, 2-1
Initial power tests, test data sheets, A-3
Installation and Update Procedures, 3-10
MGLI2, board detail, MMI port connections, 5-4
MMI common connections, 3-27
MMI Connection, 3-27
Internal FRU, 1-28
MMI Connector
CSM, 6-24
GLI, 6-26
Internal FRUs, 1-18
MMI Connectors, MCC, 6-27
Intercabinet I/O, 1-21
MMI equipment setup, 3-27
IS–97 specification, E-1
ISB Inter Shelf Bus connectors, 6-13
Model SLN2006A MMI Interface Kit, 1-8
Module status indicators, 6-22
Motorola, SC9600 Base Transceiver Subsystem, 1-1
LAN, BTS frame interconnect, illustration, 3-19
MPC, 1-19
LED Status Combinations for all Modules except
GLI2 CSM BBX2 MCC24 MCC8E, 6-22
Multi Channel Card. See MCC
Multi–FER test Failure, 6-10
LFR, 1-19
receiver operation, test data sheets, A-6
New Installations, 1-3
Line Build Out parameters
configure, 5-4
verify, 5-3
No AMR control, 6-16
No BBX2 control in the shelf, 6-16
LMF, 3-10, F-1, F-7
to BTS connection, 3-4, 3-9, 3-17
view CDF information, 3-3
No DC input voltage to Power Supply Module, 6-18
LMF Removal, 5-6
No GLI2 Control through span line connection, 6-15
Load Center Wiring, 2-5
No GLI2 Control via LMF, 6-15
Local Area Network (LAN) Tester, 1-10
No or missing MCC24 channel elements, 6-17
Logging In to a BTS, 3-22
No or missing span line traffic, 6-16
Logging Out, 3-25
North American, cellular telephone system frequency
spectrum, CDMA allocation, D-4
LORAN–C Initialization/Verification, 3-43
No DC voltage +5 +65 or +15 Volts to a specific
GLI2 BBX2 or Switch board, 6-19
Null modem cable detail, 1-8
LPA errors, 6-5
LPA Module LED, 6-28
LPA Shelf LED Status Combinations, 6-28
Online Help, 1-2
Index-4
SC
4812ET BTS Optimization/ATP — CDMA LMF
Jan 2002
Index
– continued
Optimization, 1-1
optimization/ATP, test set–up, 3-55
Advantest R3267/R3562
DRDCs, 3-58
TRDCs, 3-60
Advantest R3465, 3-55
Agilent 8935
DRDCs, 3-57
TRDCs, 3-59
Agilent E4406A/E4432B
DRDCs, 3-57
TRDCs, 3-59
CyberTest, 3-55
HP 8921A, 800 MHz, 3-56
HP 8921A, 1.9 GHz, 3-56
Preliminary operations
cell Site types, 2-1
test data sheets, A-2
Prepare to Leave the Site
External test equipment removal, 5-1
LMF Removal, 5-6
Reestablish OMC–R control, 5-7
Verify T1/E1, 5-7
Prepare to leave the site
re–connect BTS IFM connector, 5-6
re–connect BTS T1 spans, 5-6
Procedures to Copy CAL Files From Diskette to the
CBSC, 6-2, 6-3, 6-4
Product Description, 1-2
Optimization/ATP Test Matrix, 1-3
Pseudorandom Noise. See PN
Optional Test Equipment, 1-10
ptoff test, 4-10
Optional test equipment, frequency counter, 1-10
Punch Block, 3-6
Oscilloscope, 1-10
PWR/ALM and ACTIVE LEDs, MCC, 6-27
Pilot Time Offset. See PN
Ping, 3-19
PN
offset programming information, E-1
offset usage, E-1
PWR/ALM LED
BBX2, 6-27
CSM, 6-23
DC/DC Converter, 6-22
generic, 6-22
MCC, 6-27
MPC and EMPC Card, H-20
PN offset per sector, E-1
PN Offset Usage , E-1
RAM code, described, 3-28
Power Delta Calibration
Advantest, G-4
HP8921A, G-2
HP8935, G-7
Re–connect BTS IFM connector, 5-6
Re–connect BTS T1 Spans, 5-6
Receive Distribution Card RXDC, 1-29
Reduced ATP, 4-2
Power Input, 6-13
Reduced ATP passes but forward link problem
prevails, 6-8
Power Meter, 1-9
illustration, F-18, I-1
Pre–calibration, F-18
Reestablish OMC–R control, 5-7
Power meter
GPIB
Gigatronics 8542B, I-2
HP437B, I-1
illustration, Gigatronics 8542B, I-2
Removing and Installing LPAs for the SC 4812ET,
H-7
Required documents, 1-4, 1-28
Power Supply Module Interface, 6-13
Required Test Equipment
Ethernet LAN transceiver, 1-7
substitute equipment, 1-5
Pre–calibration, Power Meter, F-18
RESET Pushbutton, GLI, 6-26
Pre–power tests, test data sheets, A-3
Resetting BTS modules, 5-1
Jan 2002
SC
4812ET BTS Optimization/ATP — CDMA LMF
Index-5
Index
– continued
RF Adapters, 1-10
Setting Control Port, 3-5
RF Attenuators, 1-9
Setting Coupler Loss Value, 3-72
50 Pair Punchblock, H-25
SGLI2, board detail, MMI port connections, 5-4
RF Path Bay Level Offset Calibration, 3-73
SIF, output considerations vs BBX gain set point, C-1
RF Test Cable, 1-10
Site, equipage verification, 3-3
RFDS – Fault Isolation, 6-20
Site checklist, verification data sheets, A-2
RFDS Cabling Details, H-22
site equippage, CDF file, 3-2
RFDS calibration
description, 3-96
procedure, 3-96
Span Framing Format
configure, 5-4
verify, 5-3
RFDS FRU, H-14, H-22
SPAN I/O Functional Description, Introduction, H-13
RFDS Location, SC 4812ET, 1-23
Span Line (T1/E1) Verification Equipment, 1-10
RFDS parameters, 3-89
checking, 3-89
setting, 3-89
Span Line connector , 6-13
RFDS Test Subscriber Unit, 3-29
RFDS TSU Calibration Channel Frequencies, 3-96
Span Parameter Configuration
set, procedure, 5-4
verification, procedure, 5-3
Span Problems no control link, Troubleshooting, 6-29
SPANS LED, 6-25
rho test, 4-9
Spectrum Analyzer, 1-10
ROM code
described, 3-28
download caution, J-2
downloading, J-1
procedure, J-2
Spectrum Analyzer , HP8594E, 3-46
STATUS LED, GLI, 6-25
SYNC Monitor Connector, CSM, 6-24
RS–232 to GPIB Interface, 1-7
System Connectivity Test, F-5
Rubidium Standard Timebase, 3-46
RX, antenna VSWR, test data sheets, A-16
RX and TX paths fail, Troubleshooting, RFDS, 6-20
RX Frame Error Rate (FER) ATP, 4-13
T1, isolate BTS from the T1 spans, 3-4
Telco Interface Board TIB, 1-29
Set Span Parameter Configuration, procedure, 5-4
Test data sheets
Alarm verification, A-16
general optimization checklist, A-4
GPS receiver operation, A-5
initial power tests, A-3
LFR receiver operation, A-6
pre–power tests, A-3
preliminary operations, A-2
RX antenna VSWR, A-16
SCLPA convergence, A-7
site checklist, A-2
TX antenna VSWR, A-15
TX BLO, A-8, A-13
verification of test equipment used, A-1
Setting Cable Loss Values, 3-71
Test equipment, verification data sheets, A-1
SC 4812 BTS Optimization/ATP Test Matrix, B-2
SC 4812ET BTS Combiner, H-8, H-9, H-16, H-17,
H-18, H-19, H-21, H-24
SCLPA, convergence test data sheets, A-7
Selecting Test Equipment, 3-64
Set Antenna Map Data, 3-94
Set RFDS Configuration Data, 3-95
Index-6
SC
4812ET BTS Optimization/ATP — CDMA LMF
Jan 2002
Index
– continued
Test equipment connections , F-1
preliminary Agilent E4406A/E4432B set–up, F-10
Test Equipment Policy, 1-4
Test Equipment Setup, 3-45
Test Equipment Setup Calibration for TX Bay Level
Offset, 3-70, F-15
Test Equipment Setup Chart, 3-47
Test equipment setup RF path calibration, 3-77
Test Set Calibration, 3-63
Advantest R3465, 3-53
Agilent 8935, 3-52
Agilent E4406A, 3-54
CyberTest, 3-52
HP 8921A, 3-53
TX Code Domain Power ATP, 4-11
tx fine adjust, E-1
TX Mask Verification, spectrum analyzer display,
illustration, 4-8
Transmit TX path calibration, 3-78
TX Output Acceptance Tests – Introduction
Code domain power, 4-5
Pilot time offset, 4-5
Spectral purity TX mask, 4-5
Waveform Quality (rho), 4-5
Transmit/Receive Module TRX, 1-28
TX Path Calibration, 3-74
Troubleshooting
DC Power Problems, 6-17
Span Problems no control link, 6-29
TX and RX Signal Routing, 6-19
TX Pilot Time Offset ATP, 4-10
Troubleshooting CSM Checklist, 6-11
TX/RX OUT Connections, 4-3
Troubleshooting Forward Link Failure (BTS Passed
Reduced ATP), 6-8
txmask test, 4-7
Timing Reference Cables, 1-9
Transmit TX path audit, 3-82
TX Spectral Purity Transmit Mask ATP, 4-7
TX Waveform Quality (rho) ATP, 4-9
TSU NAM, programming
description, 3-92
parameter ranges, 3-93
parameters, 3-92
procedure, 3-98
Updating CDMA LMF Files, 5-1
TX
antenna VSWR, test data sheets, A-15, A-16
BLO test data sheets, A-8, A-13
TX & RX Path Calibration, 3-73
Verify, test equipment used, test data sheets, A-1
Verify GLI ROM code load, 3-29
Verify Span Parameter Configuration, procedure, 5-3
Virtual BTS, 1-14
TX and RX Frequency vs Channel , D-2
TX and RX Signal Routing, C–CCP Backplane
Troubleshooting, 6-19
TX Audit Test, 3-83
TX Bay Level Offset and TX ATP test equipment
setup calibration, 3-69
TX calibration, set–up, 3-52
Advantest R3267, 3-54
Jan 2002
Walsh channels, 4-11
XCVR Backplane Troubleshooting, 6-13
Xircom Model PE3–10B2, LMF to BTS connection,
3-17
SC
4812ET BTS Optimization/ATP — CDMA LMF
Index-7
Index
– continued
Notes
Index-8
SC
4812ET BTS Optimization/ATP — CDMA LMF
Jan 2002

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