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Troubleshooting ManualM900/M1800 Base Station Subsystem
Chapter 5 Troubleshooting for Clock
Chapter 5 Troubleshooting for Clock
5.1 Overview
5.1.1 Description and Fault Causes in BSC Clock System
Table 1.1 Description and fault causes in BSC clock system
Fault causes Description
Reference
source fault
The alarms DDS control data abnormal and Clock crystal oscillator override are
reported on BSC alarm console. GCKS MOD indicator flashes slowly and most of
the BTSs clock are out of lock.
The alarms Clock source changed and Clock reference source abnormal/normal
(alternatively) are displayed at the BSC alarm console. The MOD indicator or the
F0/REFA indicator on the GCKS is constantly ON.
After pulling out the two cables that introduces the two clock sources in the clock
frame, the output 2MHz clock in the clock frame turns normal and most of the BTSs
become locked.
Board fault in
clock frame
On the maintenance console, GCKS is displayed red, or GCKS indicator is
displayed abnormal, but turns normal after GCKS replacement.
Clock alarms are displayed at the alarm console, but are removed after GCKS
replacement.
After pulling out the two cables that introduce the two clock sources in the clock
frame, the CKB output clocks (including 2MHz, 4MHz, 8kHz and 32MHz) are tested
abnormal and cannot recover even after GCKS replacement.
Connection cable
fault in clock
frame
On the maintenance console, GCKS is displayed red, the CLK indicator on GCKS
flashes slowly. The fault cannot be removed even after GCKS replacement.
On the maintenance console, GCTN/GSNT clock fault is reported, but the CKBoutput clock (including 2MHz, 4MHz, 8kHz and 32MHz) is tested normal by the
frequency meter.
Clock reference source fault alarm is reported on the BSC alarm console, and the
F0/REFA indicator on the GCKS is ON.
Data
configuration
fault
On the maintenance console, GCKS is displayed red, the CLK indicator on the
GCKS flashes slowly. The fault cannot be removed after GCKS replacement.
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5.1.2 Description and Fault Causes in BTS Clock System
I. Description and fault causes in BTS3X clock system
Table 1.1 Description and fault causes in BTS3X clock system
Fault causes Description
Reference source
problem
13MHz clock out of lock alarm is reported.
The BTS3X BSIC cannot be decode.
The cell handover success rate is very low. The output 2MHz deviation of the
MMU tested at the local end is large.
Connection cable fault Clock-related alarms and test phase-lock ring alarm occur to all TRXs in the
slots, accompanied with TRX repeated loading, TRX communication alarm
and alarm removal report etc. But, no alarms occur to TMU, TDU indicators
switches work normally and DIP switches set correct.
Onsite operation error
or BTS3X clock aging
13MHz clock out-of-lock alarm occurs.
Call drop occurs frequently.
Handover success rate drops substantially.
The output 2MHz clock of the TMU tested at the local end is normal.
Board fault (TMU, TDU
and TRX)
TMU mailbox fault alarm occurs.
TMU clock fault occurs. Clock-related alarm and repeated reset occur to all
TRXs.
Connection cables and TMU work normally, and DIP switches are correctly
set. But, clock-related alarm and repeated reset occur to all TRXs.
Clock-related alarm occurs to some TRXs.
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Chapter 5 Troubleshooting for Clock
5.2 Fundamental Knowledge
5.2.1 Introduction to BSC
I. Introduction to BSC clock signal flow
TCSM
MSC
E3M
GCKS
GCTN
GFBI
GOPT
GNET
GNOD/GLAP/GMC2
E3M GSNT
GMCC
CKV BIE
8kHz
8kHz
2MHz32MHz
8kHz
32MHz
Figure I.1 Multi-module BSC clock signal flow
As shown in Figure I.1, the path for multi-module BSC clock signals is as follows. Theclock is abstracted from MSC and is transmitted via TCSM and E3M to GCKS as8kHz reference source. GCKS traces the external reference signals and filters thejittering and drifting of the external reference signals to provide the high-stability clocksignals (32MHz, 8kHz and 4MHz) which the BSC required. The clocks output fromGCKS are first provided to the GCTN (32MHz, 4MHz and 8kHz) and the GSNT(32MHz and 8kHz) in AM. Then, they are driven by the GCTN to output the clocksignals (32MHz, 8kHz and 4MHz) to GFBI. Clock signals are transmitted to BMthrough the optical paths, and GOPT extracts the clock signals (2MHz and 8kHz) andtransmits them to the GNET in BM.
The clock signals of the boards (GNOD, GLAP/LPN7 and GMC2) in the main controlframe in BM are provided by GNET. The clock signals extracted by GCTN are firstdriven by CKV, and then transmitted to the boards in BTS interface frame throughexternal HW clock cables.
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II. Introduction to theinput reference source signals in BSC clock frame
There are three channels of input reference source in BSC clock frame.
1) 8kHz differential signal source from E3M (including 8kHz0
and 8kHz1)
8kHz0 and 8kHz1 are two sets of 8kHz reference source, most commonly used byBSC. They can be input to GCKS by JC1 or JC2 through differential cables (twistedpairs).
The cable connection is illustrated in Figure II.1. The 8kHz differential signal sourcesfrom the trunk system are input by the 4-core sockets JC1 and JC2. Note that JC1and JC2 are connected in parallel, i.e., if the two channels of 8kHz differential signalsources from the trunk frame are input from one 4-core connector, the differentialcables can be connected either to JC1 or JC2.
8k0-8k0+
JC1JC2
8K1-
8K1+
Figure II.1 The cable connection when the 8kHz differential reference sources come from the same
trunk frame
If the two channels of 8kHz differential signal sources come from different trunkframes, the cable connection must be handled with care. Only two differential cablescan be connected to either 4-core sockets, as shown in Figure II.2.
8k0-
8k0+
8k1-
8k1+
JC1JC2
Figure II.2 Cable connection when the 8kHz differential reference sources come from different trunk
frames
2) The 2.048Mbit/s (E1 signals and HDB3 codes are converted on GCKS to
2.048MHz clocks) input reference source (including ER1 and ER2) from BITS
equipment
3) The 2.048MHz TTL clock signal input reference source (including 2MR1 and
2MR2) from BITS equipment
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III. Introduction to the output signals in BSC clock frame
1) To GSNT: 8kHz, 32MHz
2) To GCTN: 8kHz, 32MHz and 4MHz
Note:
8kHz and 32MHz clock signals are simultaneously output to the backplane of GSNTand that of GCTN, with the output matching resistance as 75 (150 for each board).The 4MHz signals only output to the GCTN, with the output matching resistance as75. Therefore, set the frequency meter to the state of low resistance matching whentesting the 8kHz, 32MHz and 4MHz clock signals with the meter. Otherwise, the testresult might be inaccurate.
IV. Introduction to BSC clock hardware configuration
1) Introduction to GCKS
GCKS is the board that generates the reference clock source in the clock system ofthe switch. In the board, there is a stratum-2 Oven voltage Control Oscillator(OCXO) inGCKS. GCKS traces the external reference signals and filters their jittering anddrifting to ensure high frequency accuracy and stability of the timing signals outputand provide the switch a high-quality clock source. The GCKS can provide bothstratum-2 and stratum-3 clocks.
GCKS works under four modes. When GCKS is first powered on, the OCXO in it willhave been heated for 3 minutes. In the 3 minutes, its MOD indicator is OFF. Then, theboard starts to work, its OCXO enters free-run state and the MOD indicator is OFF. Ifthere is no reference source, the OCXO will continue in its free-run state. If there isreference source, GCKS will first check its frequency deviation. If the deviation is big,REFA indicator will be ON. If the deviation is normal, the OCXO will enter fast pull-in
state and the MOD indicator will flash quickly. Usually fast pull-in state will last 10~15minutes. After the 10~15 minutes, if the reference source is abnormal, the OCXO willenter free-run state. If the reference source is normal, the OCXO will enter lockedstate, MOD indicator will flash slowly and GCKS starts to work. If the referencesource is abnormal during the locked state, the OCXO will enter holdover state andMOD indicator will be ON. But when the reference source resumes normal, theOXCO will re-enter locked state.
2) Important DIP switches
(a) Configuration of GMPU and GCKS communication rate
There are DIP switches on both GCKS and CKB for configuration of communicationbetween GCKS and GMPU. Only when the DIP switches on both GCKS and CKB arecorrectly set, can the communication between GMPU and GCKS be normal.
Otherwise, GCKS fault will occur.
Table 1.1 The DIP switches for configuring the communication rate between GCKS and CKB
BSC type GCKS
S5.1
CKB
S4.1 S4.2 S4.3 S4.4
Communication mode
Multi
module
OFF ON ON ON ON Point to multi-point, high
baud rate
Single
module
ON OFF OFF OFF OFF Point to point, low baud rate
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(b) Other DIP switches on GCKS
There are other two DIP switches on GCKS for configuring the clock stratum andphase lock mode of GCKS. Usually they are set as follows.
DIP switch Common setting in BSC Description
S5.2 ON ON: PDH phase lock mode
OFF: SDH phase lock mode
S5.3 ON ON: stratum-3 clock
OFF: stratum-2 clock
3) Indicator on GCKS
Indicator Color and normal
state
Meaning and description
RUN Red, flashing once
every second when the
communication is
normal.
The RUN indicator flashes once every second when the
communication is normal, 4 times every second when the
communication is abnormal. The normal communication depends
on the correct settings of the DIP switches. GCKS communicates
with SLT or ALM with low baud rate when there is an SLT in the
clock frame or there is a clock frame in the independent C&C08B
standalone exchange. If the RUN indicator flashes quickly after
GCKS is powered on, first check the DIP switches on the GCKS.
ACT Green ON when the GCKS is active and OFF when the GCKS is standby.
F0 Green, OFF when the
reference source is
normal
Indicator for the status of the external reference source selected.
ON when the reference source is abnormal, On when the
reference source is normal, flashing when the software is re-
capturing the reference source, OFF again when the reference
source is locked. If F0 is ON after GCKS is powered on, check to
ensure the reference source is correctly accessed to the GCKS.
There can be six types of reference source to be accessed. Seen
from the back of the backplane, J1 and J2 are the input terminals
for 2048kbit/s reference source, J3 and J4 are the input terminals
for 2048kHz reference source. Under locked state (MOD indicator
flashes slowly. Refer to the description below), when F0 indicator
flashes, GCKS is re-capturing the reference source and it will be
OFF again after it locks the reference source. If F0 flashes
frequently, check if SDH mode is required. For F0 flashing under
other modes, check the quality of the reference source accessed.
F1 Green, OFF when the
board works normally
OFF when the system works normally (including VCXO, DDS,
88915). If F1 on the GCKS is ON, GCKS fault occurs (including
VCXO, DDS AND 88915 fault). Normally GCKS will be switched
over automatically (if it is standby, no switchover will be
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Indicator Color and normal
state
Meaning and description
performed). Maintenance personnel shall replace the faulty board
timely according to the status of other indicators.
LOF Green, OFF when the
board works normally
ON when the 88915 is out of lock. Under this case, the board will
be automatically switched over (if it is standby, then no switchover
will be implemented). Due to 88915 out-of-lock, the clock signals
(frequency and amplitude) output from the board will be abnormal,
so the maintenance personnel shall replace the board timely.
DDS Green, OFF when DDS
output is normal
OFF when DDS output is normal, ON when the DDS components
on GCKS work abnormally. When DDS is ON, automatic
switchover of the GCKS shall occur (if the board is standby, no
switchover will occur). The abnormal DDS components will make
the clock signals output by the board abnormal (frequency and
amplitude). DDS output abnormal is most probably caused by the
inaccuracy of the reference source. Therefore, first check the
reference source. If the reference source is normal, replace the
board timely.
LOCK Green, OFF when
88915 is normal
ON when 88915 is out of lock.
The meaning of LOCK indicator is completely the same as that of
LOF indicator.
CLK Green, OFF when58274 is normal
OFF when the time chip 58274 has calibrated the time and worksnormally. Otherwise, it flashes. The time chip 58274 in the
C841CKS provides time to the switch, but the initial time shall be
configured on the BAM. CLK indicator is OFF when 58274 works
normally. If no initial time has been configured at the BAM, or
58274 chips work abnormally, CLK indicator will flash once every
second.
R8K0 Green,ON when R8K0
is selected
The 8kHz reference source from the trunk. There are altogether 6
reference source indicators on C841CKS. When the external
reference source is selected, its corresponding indicator will be ON.
Otherwise, the corresponding indicator will be OFF. R8K0 is default
reference source with highest priority (unless other reference
source has been configured with higher priority than R8K0 on the
BAM). As long as R8K0 is available, it will be configured as the
default reference source. If it is unavailable, select R8K1 as the
default reference source. By analog, the rest can be selected as
the default reference source when all the reference sources before
it in numbering are not available. If the active reference source is
not available after GCKS is powered on, F0 indicator will be ON
and the indicator for the active reference source will also be ON
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Indicator Color and normal
state
Meaning and description
(R8K0 by default). If stratum-3 clock is configured for GCKS (by
setting SW3.5 as ON or configuring it on the GMPU), GCKS can
capture suitable reference source as active. Its stratum-2 clock will
be configured by the GMPU. The active reference source states
(normal or abnormal) are indicated by F0.
REFA Green, OFF when the
clock deviation is
normal
ON when the clock deviation is too large and OFF when the clock
deviation is normal. REFA indicates the clock deviation when the
clock is under holdover or free-run state, and it indicates the output
of clocks under fast pull-in or locked state.
REFA will be ON when the output frequency deviation is bigger
than 0.4ppm or 4.6ppm respectively under the case that stratum-2
clock or stratum-3 clock is configured to GCKS. Only when the
GCKS is in locked state, That frequency deviation check would be
performed to the reference source. If the deviation is detected too
big, GCKS will enter holdover state, and it returns into locked state
when the reference source resumes normal.
MOD Green OFF: free run (just powered on/the reference source is abnormal
after fast pull-in)
Flash quickly: fast pull-in (quickly lock the reference source)
Flash slowly: locked (normal)
ON: holdover (the reference source is abnormal after being locked)
+12V Green, ON when the
12V power supply is
normal
12V power supply indicator. OFF when it is normal. +12V is the
power supplied to the OCXO on GCKS. If the 12V power supply is
abnormal, there will be no output from the OCXO and the GCKS
cannot work normally.
V. Introduction to BSC clock data configuration
Table 1.1 Tables required to be configured for BSC clocks
Table name Function
[Clock description table] Describes the clock source of the GNET
[AM_CKS clock configuration table] Describes the work mode selection of the clock
module
For multi-module BSC, the two tables in the above table are required for BSC clockdata configuration.
[Clock description table] configuresthe clock source of GNET. For multi-module BSC,
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select hardware selection (module B/C2K network) and select clock frame clock (Bindependent office) for C&C08B standalone exchange BSC.
[AM_CKS clock configuration table] configures the stratums and reference sources ofthe clock.
[Select clock reference source]
There are 3 categories, 6 types of clock reference sources, i.e., 8kHz differentialsignals 8K0 and 8K1, 2Mbit/s E1 signals 2MB0 and 2MB1, 2MHz TTL signals 2M0and 2M1. Usually 8kHz differential signals are used. Generally all are selected.
[Configure the priority of the reference source]
Usually the priority level for reference source selection from higher to lower is 8K0,8K1, 2MB0, 2MB1, 2M0 and 2M1. Generally all are selected.
[Select the active clock after power on]
Select the GCKS first used after the clock frame is powered on. Usually the activeGCKS0 is firstly selected.
[Set clock stratum]
For GCKS combines the stratum-2 and stratum-3 clocks, this parameter is designed.Usually stratum-2 is selected for MSC and HLR, and stratum-3 for BSC.
[Set clock phase lock mode]
Select the PDH mode.
[Select clock module work mode]
Usually automatic adjustment mode is selected. Controlled mode is selected only forcommissioning and clock network access acceptance test.
VI. Troubleshooting for BSC clocks
1) Check indicators on GCKS
Note especially the state of MOD and REFA indicators during the normaloperation of GCKS. If the MOD indicator flashes slowly, it means GCKS istracing normally the MSC clocks. If the MOD indicator is OFF, it means theGCKS is working under free-run mode (usually the free-run mode is not takenunless when the frequency deviation of the clock reference source obtained fromMSC is too big). If the MOD indicator is in the states other than ON and OFF, itmeans the GCKS is working abnormally. In addition, if the REFA indicator is ON,it means the frequency deviation of the GCKS output clock is too big. Check the
status of F0 indicators. If the F0 indicator is ON, it means the reference source isabnormal. If the F0 indicator is OFF, it means the reference source is locked. Ifthe F0 indicator is flashing, it means the software is now tracing the referencesource. When CLK indicator is ON, it means there is communication faultbetween GCKS and GMPU.
2) Query on the maintenance console
(a) Query whether GCKS is faulty or abnormal on the maintenance console.
(b) Query the state of the clock source by selecting the menu [Controloptions/ /GCKS Board Control/Query Clock Source State]
Select the menu above to query the state of the clock source. Note that thefrequency deviation queried on the maintenance console is not accurate enough.
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Therefore, usually the average value of multiple frequency deviations queried onthe maintenance console is taken for reference.
(c) Query the work state of GCKS by using the right-key menu on themaintenance console.
3) Query clock-related alarms on the alarm console
Query whether there are clock-related alarms on the alarm console, such asClock reference source abnormal, Clock configuration data error, BTS 8kHzclock alarm, 13MHz clock out of lock, DDS control data abnormal, Clockreference source switchover and GCTN clock fault alarm etc.
4) Check related components with meters
The most commonly used test instrument for clocks is frequency meter. Thecommonly used frequency meter is HP53132A, used to measure the frequencyaccuracy. Oscillometer is used to check whether the waveforms of the clocksignals are deformed and whether the phases are normal.
Clock test can be performed at MSC side, BSC side and BTS side. Refer to theBSC clock test point below for clock test accuracy requirement. Usually the clocktest follows a process below.
5) First test whether the clocks output from the BSC clock frame are accurate.
6) If the BSC clocks are accurate, test the clocks at BTS side.
7) If the BSC clocks are not accurate, test the clock at MSC side.
8) If the clock at MSC side are also inaccurate, test the clock reference source of
MSC.
9) If the MSC clocks are accurate, test whether there are faults on the clock
transmission path between MSC and BSC.
VII. BSC clock test point
1) Output 2MHz clock in GCKS
Test instrument: frequency meter
Test point: 2MH-OUT test point on the backplane of the clock frame, J16 in the
Figure 1-4. This is the most commonly used clock test point and it exists in the
clock frame of both MSC and BSC.
Grounding point: coaxial shield layer of the clock frame can be used as the
grounding point.
Test requirement:
Stratum-2 clock is adopted at the MSC side and its clock accuracy should bef/f1E-8.
Stratum-2 clock is adopted at the BSC/BTS side and its clock accuracy shouldbe f/f5E-8.
Therefore, the frequency deviation allowed at the MSC side is 2048000.000 1E 8 = 0.02Hz.
And the frequency deviation allowed at the BSC/BTS side is 2048000.000 5E 8 = 0.1Hz.
If there is too big frequency deviation, check whether the reference source,GCKS and CKB are normal.
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See Figure VII.1 for 2MHz test point.
8K0-8K0+8K1-8K1+
2MH-OUT1
8K-IN
JC1JC2
J16
Figure VII.1 2MHz clock output from the backplane of the clock frame
2) 8kHz reference source accuracy on the CKB of the clock frame
Take the 8kHz clock reference source as the example.
Test instrument: Frequency meter
Test point: It depends on the reference source selected, as shown in Figure 1-5.
Grounding point: The GND point in Figure VII.2 is recommended, or the coaxial
shield layer of the clock frame can also be used as the grounding point.
Test requirement:
The allowed frequency deviation of the 8kHz reference source at the MSC sideis 8000.000 1E 8 = 8 1E 5 Hz
The allowed frequency deviation of the 8kHz reference source at the BSC/BTS side is
8000.000 5E 8 = 4 E 4 Hz
Figure VII.2 Test point for 8kHz clock reference source on CKB
3) Clock test at the back of MSM
Test instrument: Oscillometer
Test point: As shown in Figure VII.3, connect the oscillometer on the upper part
of pins at the back of MSM on TCB to test the 8kHz, 2MHz and 4MHz clocks.
Grounding point: The GND points in Figure VII.3 are recommended.
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Test requirement: The waveform is normal.
In addition, to test the accuracy of the 8kHz clock reference source, lead the MSM TxE1 cables to the test TMU to test the 2MHz clocks extracted by the TMU. Theaccuracy requirement is the same as that in testing the clocks at the back of CKB.
Pin in Up Socet of MSM Backplane
2M-2M+
4M-4M+
8K-8K+
25
26
27
A B CGND
GND
GND
Figure VII.3 MSM clock signal test point
4) Clock accuracy at the back of GCTN
Test instrument: Oscillometer
Test point: As shown in Figure VII.4, connect the oscillometer on the upper part
of pins at the back of the backplane of corresponding GCTN to test the 8kHz,
32MHz and 4MHz clocks (two groups for each).
Grounding point: The grounding points in Figure VII.4 are recommended.
Test requirement: The waveform is normal.
32M132M0
8k 18k 0
4M14M0
45
46
47
A B CGND
GND
GND
Pin in Up Socet of CTN Backplane
Figure VII.4 Test points for the clock signals on the backplane of GCTN
5) GSNT clock accuracy
Test instrument: Oscillometer
Test point: As shown in Figure VII.5, connect the oscillometer on the back of
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backplane of corresponding GSNT to test the 8kHz and 32MHz clocks (two
groups for each).
Grounding point: The GND points in Figure VII.5 are recommended.
Test requirement: The waveform is normal.
SNT Backplane
8k 0
8k 1
32M0
32M1
4
34
35
A B C
GND
Figure VII.5 Test points for the clock signals on the backplane of GSNT
5.2.2 Fundamental Knowledge of BTS Clock System
BTS clock system performs radio link time division and radio frequency calibration
function in GSM system. It plays an important role in the normal serviceimplementation of GSM system.
I. BTS reference clock
When BTS clock reference source comes from BSC, the BTS is connected to the BIEof the BSC through the E1 cables of the BIU (BTS Interface Unit). BIU selects andprocesses one channel of clocks among the clocks extracted from E1 interface line,then takes it as the reference clock for the MCK module of the BTS high-precisionclock. Under some cases, BIU can also provide the input for the external referenceclocks. It selects one channel of clocks from the two channels of clocks it extractsfrom the E1 as the reference source clock for MCK module. The deviation of the clockis required to be no more than 0.05ppm.
II. BTS system clock
The OXCO, frequency divider, frequency verification unit, CPU and D/A in the MCKmodule comprises a closed-loop frequency calibration system to automatically tracethe reference source input and provide the BTS high-performance 13MHz referenceclock, as shown in Figure II.1.
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Reference sourceCPU D/A OCXO System clock
Frequency division
System clockPhase discrimination
Figure II.1 MCK module phase-locked loop
All clock signals used by the BTS are generated by the 13MHz signals. MCK modulecan decide the precision of the external reference signals, automatically pull in andlock the reference clock signals and filter their jittering so that the clock signals outputcan have high frequency precision and stability and can work under free-run orholdover state when the external reference clock source gets lost.
There are two BTS clock software versions currently in service, V 0407 and V0529.Their algorithms are not the same.
For V0407, when the phase discrimination deviation is less than 4Hz, the clocks will
trace and lock the reference clock. Otherwise, they will not trace and lock thereference clock and they stay in free-run mode.
For V0529, the clocks always trace and lock the reference source.
MCK module has three phase lock states, free-run, pull-in and locked.
Free-run state occurs under the following scenarios:
When the reference source jitters terribly and cannot stay stable for the clocks to
pull in.
When the reference source gets lost, MCK will enter free-run state immediately
no matter what state it is in.
13MHz clock out-of-lock alarm will be reported under both the above scenarios. When the reference source is set as the internal clock on the local MMI, the MCK
module will be forced into free-run state.
Pull-in state occurs under the following scenarios.
When the reference source jittering is less than 4Hz (BTS3X) or 5Hz
(BTS3001C) under free-run state, MCK module will enter pull-in state.
When the clock deviation frequently exceeds the security range under the locked
state, MCK module will enter pull-in state.
The locked state occurs under the following scenarios.
The 13MHz clock deviation has been less than 0.2Hz for long time; the MCK module will enter locked state.
III. The generation of BTS system clock signals
GSM system is a TDMA (Time Division Multiple Access) system, i.e., the multipleaccess function is accomplished through time division. Both the TDMA principle andGSM05.10 specification regulate that four signals are required for the timing at theradio interfaces, FCLK (Frame Clock), FN (Frame No.), TSCLK (Timeslot Clock) andOBCLK (Octet bit clock).
As defined in GSM specification, system clock signals can be generated through thefrequency division of the master clock of 13MHz. Among the clock signals, OBCLK is
the sixth frequency division of the 13MHz, i.e., 136=2.16MHz. The FCLK, OBCLK
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and SREF signals are aligned with the rising edge of the 13MHz clocks (10-20 nsdelay allowable).
SREF: Frequency 13MHz/4=3.25 MHz, period 307.7 ns, duty ratio 50%
OBCLK: Frequency 13MHz/6=2.167 MHz, period 461.5 ns, duty ratio 50%
FCLK: Frequency 13MHz/6/10000=216.7Hz, period 4.615 ms, duty ratio 50%
13MHz: Frequency 13MHz, duty ratio 50%
The period relationship between clocks of different systems is as the following:
1 FCLK=8TSCLK
1 TSCLK=156.25 BCLK=1250 OBCLK
IV. The calibration of 13MHz clocks
Because the frequency dispersion of the 13MHz OCXO is rather large in actualmanufacturing, the 13MHz output frequencies of different boards differ greatly.Therefore, to ensure an accurate 13MHz reference clock for each board, all the13MHz clocks are required to be calibrated respectively before the boards start towork. In addition, the 13MHz clocks are required to be calibrated once every year toavoid the 13MHz clock deviation due to clock aging.
1) Required equipment and environment
One frequency meter, one serial port communication cable and MMI BTSmaintenance system.
2) 13MHz clock calibration process
Check to ensure the board is in normal service (warm-up end). Connect the
frequency meter to the board 13MHz clock port, and the serial port
communication cable to the MMI BTS maintenance system control console.
Start MMI control, obtain administration authority and complete the board
configuration.
Select board management and clock configuration item.
Select Internal clock in clock configuration interface, adjust the default DA
control value so that the difference between the 13MHz value on the frequency
meter and the actual 13MHz is controlled within 0.1Hz.
Select store to Flash Memory and press in the [CLK configuration]
interface.
Note: Press Ctrl + Alt + F to perform clock hardware parameter configuration.
Exit the configuration item and complete the 13MHz clock calibration.
The clock system principles for all Huawei BTS series are basically the same. Toget a comprehensive understanding of Huawei BTS clock system signal flow canhelp a lot for clock system troubleshooting.
V. Huawei BTS clock system signal flow
1) BTS30 clock system signal flow
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BTS
TDU
Board
JP3
JP4BTS JP2
JP1 JP3
JP3
TRB
CMB
U5
U7
U6
U8
U2
U4
U1
U3
SIX TRX
Matching
TMU
Wring2
Wring1
Wring3
Wring4
Figure V.1 BTS30 clock system signal flow
BTS30 clock system signal flow is illustrated in Figure 5-10. The path in the major
cabinet is TMU CMU (JP3) TDU (JP2) TDU (JP4 and JP3 Extension
cabinet) JP1TRB (JP3) 6 TRXs in the local cabinet. During the path, signals
might pass four wiring points: wiring 1 and wiring 2 (to the extension cabinet), wiring 3(TDU to TRB) and wiring 4 (from the CMB of the major cabinet to the TDU).
The path in the major cabinet is TDU (JP3 or JP4) TDU (JP1) TRB (JP3) the
6 TRX in the local cabinet. During the path, signals might pass three wiring points:wiring 1 and wiring 2 (to the major cabinet and next level of extension cabinet), wiring3 (to TDU and TRB).
The signal flow of BTS312 is similar to that of BTS30. Clock signals are forwarded viaTDU.
2) BTS3001C clock system signal flow
Because BTS3001C cabinets are encapsulated and not allowed to be opened in thefield, only clock source and operation problems, no internal signal flow, are describedhere.
VI. Board indicators of BTS series
1) Indicators of clock-related boards in BTS3X series
Table 1.1 TMU indicator
Indicator Color Meaning Description Normal state
PLL Green Phase
discrimination
indicator
ON: free run
Flash quickly (4 Hz): pull-in
Flash slowly (1 Hz): locked
OFF: abnormal
Flash slowly (1 Hz)
2) BTS3001C clock-related indicator
There is no clock-related indicator in BTS3001C.
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VII. Huawei BTS series clock test points
1) BTS3X series
The T2MHz and 13MHz test output in TMU is illustrated in Figure VII.1.
PWR
RUN
LI3
LI1
LI2
M/S
PLL
DBG
MMI
LI4
T2M
FCLK
T13M
Figure VII.1 TMU clock test point
2) BTS3001CBTS3001C test points are illustrated in Figure VII.1. The 13MHz output point is13MCLK, and FCLK output point is 2M (output shift is performed by executingcustom commands).
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13MCLKFCLK
SLAVE
SLAVE
MASTER
IOPOWER
MMI
ASUO&M
PWRRUNACTMODLIU
S3
ONOFF
MSB
LSB
Figure VII.2 BTS3001C O&M cavity (REV.C)
5.2.3 Specifications about BTS Clock System
The requirement about GSM BTS frequency accuracy in GSM specifications is as thefollowing.
The frequencies of radio part and baseband part of the BTS must derive from thesame signal source. For BTS of any type, no matter whether they support slow rateFH (Frequency Hopping), the absolute frequency error of their transceivers and therelative frequency error between transceivers must be less than 0.05ppm under alltest conditions.
5.3 Trouble Handling
5.3.1 Trouble Handling for BSC
I. Trouble handling for reference source
1) Description
F0 indicator is ON or flashing after GCKS enters normal service. Clock referencesource abnormal and Reference source replacement alarms are displayed on thealarm console. Sometimes most of the BTSs clock are out of lock.
2) Introduction to indicators
F0 indicator indicates the state of the reference source.
OFF: Reference source unavailable and GCKS in free-run state
Flash quickly: Reference source available, GCKS in fast pull-in state for about half anhour.
Flash slowly: GCKS in locked state (normally working state)
ON: Reference source gets lost when GCKS is in locked state, GCKS enters holdoverstate.
3) Analysis
Remove the cables for the 8K0 and 8K1 reference sources from E3M and check
if there are alarms related to reference source and if the BTS has locked the
clocks of BSC.
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If after the cables are removed, reference source alarms disappeared and theBTS normally locks the clocks of BSC, reference source fault can be confirmed.
If there is frequency meter available, test the deviation of the output 2MHz clocks
in the clock frame before the cable removal and after the cable removal. If theoutput clock deviation is large before the cable removal, but normal after the
removal, reference source fault can be confirmed.
Check board indicator
When F0 indicator is ON, no reference source is available. When F0 is flashing, thereference source is not stable.
4) Handling process
If the reference source fault is confirmed, take the following steps for troubleshooting.
Check whether the cables are correctly and reliably connected. Note that 8K0
and 8K1 come from different offices and are connected to different sockets (JC1
and JC2). IF possible, replace clock input cables to remove the problems caused
by the clock input cable fault.
Check the clock generation channels in E3M and TCSM frame. Connect the
clock access cables to other E3Ms and TCSM frames to check whether there is
E3M or TCSM frame fault. If there is, check whether the E3M interfaces are
damaged or whether TCSM frame is not in normal service. Replace E3M or the
DRC on the back of the backplane.
If the reference source fault still cannot be removed, test in sequence the MSC
CKS output clock, MSM clock and the 8kHz reference source clock input from
the BSC CKB. If the MSC clocks are not accurate, check the reference source and the
operating status of the clock frame of the MSC.
If the MSM clock is not accurate, check the E1 cables between BSC and MSC. Ifthere is transmission between BSC and MSC, the transmission exerts great impacton the clocks and has to be tested.
II. Trouble handling for the clock frame
1) Components of the clock frame
The clock frame is composed of GCKS, CKB and PWC. There are two GCKSs,
working in active/standby mode in slot 4 and slot 6.2) Description
On the maintenance console, GCKS is displayed red and GCKS indicator worksabnormally. Clock-related alarms are displayed on the alarm console.
3) Analysis
The most probable causes for clock frame fault is GCKS or CKB fault (including DIPswitches error).
When the above scenario occurs, if the fault is removed after GCKS replacement,check whether the DIP switches are correctly set. If the DIP switches are correctlyset, it can be confirmed that the GCKS is faulty. Replace the corresponding GCKS.
After GCKS replacement, if the fault still exists, remove the cables for the two
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reference sources in the clock frame and test the CKB output clock (including 2 MHz,4 MHz, 8 kHz and 32 MHz). If the CKB output clock is abnormal (the waveform of thefault is difficult to obtain and the sampling will be long by using oscillometer), CKBmust be faulty. Replace CKB.
III. Trouble handling for the cables
1) Clock-related cables
(a) Maintenance cables
Maintenance cables are used to connect GMCCM and GCKS. GMCCM performsO&M to the two GCKSs through 2 serial ports.
One end of the maintenance cable is connected to JB33 on C821MCB (it is insertedfrom the first pin on the top). Another end of the cable has two connectors, one 4-coreconnector and one 2-core connector. The 4-core connector is connected to JB21 onCKB (inserted in the pins five pins above the bottom) and the 2-core socket is
connected to JB3 on CKB (inserted from the first pin on the top).
(b) Clock cables
There are two types of clock cables. One is the clock cable for synchronization(differential), which is connected to the fifth port at the back of E3M and inputssynchronization clock source to the clock frame. Another is the clock cable used totransmit the two sets of clocks (32MHz, 8kHz and 4MHz; 32MHz and 8kHz) output bythe clock frame to the GCTN and GSNT via corresponding backplane.
2) Analysis
On the maintenance console, GCKS is displayed red, GCKS CLK indicator flashesslowly and Clock reference source alarm is displayed on the alarm console. Thetrouble cannot be removed even after GCKS replacement. The F0/REFA indicator on
the GCKS is ON, and it might indicate reference source cable fault. GCTN clockfault and GSNT clock fault alarms might be displayed on the alarm console, but noother correlated alarms occur.
3) Handling process
When GCKS is displayed red, GCKS CLK indicator flashes slowly and the troublecannot be removed after GCKS replacement, replace the maintenance cables.
When Clock reference source fault alarm is reported and the F0/REFA indicator onGCKS is ON, the reference source cables might be faulty. Replace the referencesource cables.
When GCTN clock fault and GSNT clock fault alarms, but no correlated alarm, aredisplayed on the alarm console, the CKB output clock cable might be faulty. Replace
the CKB output clock cable.
5.3.2 Troubleshooting for BTS
I. Troubleshooting for the reference source
1) Description
Alarms 13MHz clock out-of-lock, BTS BSIC cannot be unlocked and the cellhandover success rate drops, but no other alarms, are reported.
2) Probable causes
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Refer to Table 1-2.
3) Handling process
Step 1 On the local MMI maintenance console, check whether the BTS MCK module
clock is in free-run state or fast pull-in state. Observe and record the D/A value in theboard information displayed.
Step 2 Test and record the jittering deviation of the 2MHz output clocks in differentBTSs. The jittering deviation within a short time frame should be in the MCK moduletracing range, i.e., within +/-5Hz or +/-4Hz.
Note that custom messages for clock signal switchover has to be sent through thelocal MMI maintenance console before the test of 2MHz output clocks in BTS3001C.
D4-00-FF-FF-FF-81-00-FF-02-72- [00-FCLK, 01-2MHz]
Step 3 Test the BTS 13MHz output clocks and write down the value.
Step 4 If the BTS 13MHz output clock is not accurate, set the BTS clock mode as
internal clock mode. Adjust the BTS D/A value to enable the BTS enter locked stateaccording to the deviations of the 13MHz clocks.
Step 5 If BTS 13MHz output clock is accurate, 13MHz clock out-of-lock might becaused by the reference source fault, which probably is incurred by transmission orBSC clock fault.
Step 6: Check whether 13MHz clock out-of-lock occurs to other BTSs of the sameBSC. Check whether the 2MHz clock of the BSC is accurate and normal.
Step 7 If the BSC clock is accurate, check whether other TS abstraction equipmentexist on the transmission channel and whether the transmission equipment clocksystem is normal.
II. Troubleshooting for field operation errors
1) Description
The alarms 13MHz clock out-of-lock alarm, BTS BSIC cannot be unlocked, Cellhandover success rate drops, but no other alarms, are displayed.
2) Probable causes
Refer to Table 1-2.
3) Handling process
Step 1 On the local MMI maintenance console, right click the MMU and observewhether the clock state in the board information displayed is free-run. Write down the
D/A value displayed.
Step 2 Set the BTS clock mode as the internal clock mode, test the 13MHz clockoutput by the BTS with the frequency meter and observe whether the 13MHz outputmeets the specification requirement.
Step 3 If errors occur to the 13MHz clock output by the BTS, manually adjust the D/Avalue and observe whether the 13MHz output clock varies accordingly.
Step 4 If D/A value can be successfully adjusted, it can be confirmed that the errors ofD/A value are causes by BTS clock aging or operation mistakes. Re-adjust the D/Avalue corresponding to the 13MHz BTS.
If the adjustment of D/A value cannot according adjust the 13MHz output frequency,boards must be faulty. Replace the boards.
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Detailed troubleshooting measures: under the internal clock mode, adjust the D/Avalue so that the BTS can output accurate 13MHz clocks and save the D/A value inthe Flash Memory of the BTS. Then reset the BTS clock work mode as the externalclock mode.
III. Troubleshooting for cables
1) Description
Clock-related alarms and phase-locked loop alarm occur to the TRXs in all the slots.
Repeated loading, TRX communication alarm and removal report occur to the TRXsof all slots.
No alarms occur to TMU.
TDU indicator and DIP switches are normal.
2) Probable causes
Refer to Table 1-2.
3) Analysis
Instrument required: multimeter
Step 1 According to the BTS30 clock system signal flow, check the rack cabling fromthe transmission source (the TMU in the major BTS) to TRB. Replace the faultycables if there is any, and observe whether the troubles have been removed.
If the troubles cannot be removed, it might be caused by board fault. Remove theboard fault accordingly.
IV. Troubleshooting for board fault
1) Description
Boards are repeatedly reset and loaded due to TMU major clock alarm, TRX frameNo. (TS No.) alarm and clock alarm etc.
TMU alarm and TRX alarm are most probably caused by board fault.
As described in the BTS30 clock system signal flow, TMU is the source of the clocksystem, CMB, TRB and TDU are the parts the clock signal flow passes and the TRXis the termination of the clock signals.
Therefore, TMU, TDU and CMB clock faults will lead to the abnormal working of allTRXs. The TMU fault alarm will be accompanied by TMU clock alarm
Therefore, when TMU, TDU and CMB clocks are faulty, all TRXs cannot worknormally. TMU fault is usually accompanied with TMU clock alarm, TDU fault will leadto the fault of all TRXs and CMB fault will also lead to TDU fault.
When TRB and TRX are faulty, usually clock alarms occur to the TRXs in some slots.
Usually board faults can be analyzed and located according to the system clocksignal flow.
2) Probable causes
Refer to Table 1-1.
3) Handling process
There are two ways to handle board faults. One is board replacement. Another is
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clock waveform test. The second way requires oscillometer on site to help the test.Test the clock wave form segment by segment according to the clock signal flow tolocate the faulty segment.
The following describes the process for board replacement.
Step 1 Check whether all TRXs are faulty and whether serious clock alarms occur toTMU.
If yes, go to Step 2.
If No, go to Step 7.
Step 2 Replace the board suspected to be faulty with a normal board and observewhether the BTS can normally working.
If the BTS can resume normal working, it can be confirmed that TMU is faulty.Replace the faulty TMU.
If after TMU replacement, TMU major clock is removed, but TRX alarm cannot, go toStep 3.
Step 3 Observe whether the configuration of the rack indicated by TDU indicator iscorrect. If yes, replace the faulty TDU with a normal TDU working in other racks andobserve whether the fault is removed. If yes, go to Step 4.
Step 4 It can be confirmed that cabling fault is excluded.
Step 5 Replace CMB.
Step 6 Replace TRB.
Step 7 If faults of some TRXs still cannot be removed, pull put the faulty TRXs andinsert them into normally-working TRX slots. Observer if faults still persists. If yes, the
TRX must be faulty. If no, TRB corresponding slot or matching problem might happen.Replace TRB boards.
For matching problem, pull out, then push in connectors to adjust the clock bus loadso that the fault can be removed.
5.4 Examples
5.4.1 Troubleshooting Examples for BSC Clock Fault
I. Call drops during handover due to too large BTS clock frequency
deviation
Description
Sometimes the call dropped during handover in GSM1800 system. But the signallevel was high and there was no interference.
Handling process
The maintenance personnel found that the BTS frequency deviation was very bigaccording to the onsite test result. The 13MHz output frequency deviation of someBTSs reached 2.5Hz, greatly larger than the international standard 0.65Hz. 8KHZ
clock alarms of many BTSs were reported on the alarm console. MSC frequently
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reported Clock software phase lock normal/abnormal alarm, which indicated theinaccuracy of the clock at MSC side.
Analysis
From the above description, it can be inferred that the instability of BTS clock werethe major causes for call drops during handover. Therefore, the maintenancepersonnel re-adjusted the clock reference source of the MSC to make it stable, the8kHz input clock error alarm disappeared and the call drop during handoverdisappeared.
II. BTS clock frequency deviation too big due to configuration error in the
clock description table
Description
In single module BSC, the maintenance personnel queried the MCK clock of the BTSand found its the frequency deviation was very big. Then tested the clock from theGCTN and found its frequency deviation was also very big.
Handling process
The maintenance personnel queried the data configuration and found the clockselection in the clock description table wad configured as Multi-module BSC clockload-sharing mode and the GCTN extracted clocks from GOPT.
Analysis
In the single module BSC, the clock selection should be configured as C&C08Bstandalone exchange and the GCTN extracted clocks directly from the clock frame.After modifying the configuration, the maintenance personnel tested the clocks fromthe GCTN and found their frequency deviation very small. They queried the MCK
clocks and found the frequency deviation normal.
III. Clock fault due to cable problem from MCB backplane to FIO backplane
Description
During the equipment check after an upgrading in an office, the maintenancepersonnel found clock system alarms were reported and the ENA indicator on GCTN0in SCP4 was flashing quickly.
Handling process
The maintenance personnel at first thought it was caused by GCTN fault. But the faultcould not be removed after GCTN replacement. They performed GCKS switchoverand the system resumed normal. They then replace GCKS0 and switch GCKS0 overas active, but the fault still remained. After repeated verification, it was found thatwhenever GCKS0 is used, the alarm would be reported. But when the GCKS1 wasused, the system would work normally. The maintenance personnel performed GSNTswitchover clock cable plug/unplug test and inserted only one GCKS in the frame, butthe fault could not be removed.
Analysis
In the internal cable set of the BSC, the cable from MCB to FIO backplane isdisrupted, so GCTN cannot correctly select clocks after clock switchover.
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IV. BSC clock problem due to MSM fault
Description
In an office, BTS2.0 was used. After BTS cutover, most of the BTSs were in fast pull-in state and crystal oscillator override alarm was reported many times.
Handling process
The maintenance personnel queried BSC clock board and found it normal. The MODindicator of GCKS was flashing slowly and GCKS was in locked state. They checkedall the boards on the BSC maintenance console and found their state normal.
Analysis
After analyzing the faulty MSM, the maintenance personnel found that the matchingresistance of the E1 Rx/Tx chip of the faulty MSM is damaged. They replaced thedamaged resistance and the fault was removed.
V. BTS out of lock because E1 TS integrater cannot transmit the clock in
real time
Description
In a BSC module, 13MHz clock out-of-lock alarm was displayed at the BTS side.The TMUs of all the BTSs were in free-run state and could not lock BSC clocks.
This fault can be temporarily removed by resetting GCKS but cannot be removedfrom its root cause.
Handling process
The maintenance personnel checked the E1 channels on E3M 2. They connected TScrossover equipment in one E1 channel. They replaced the clock extraction E1 port ofthe BSC and extracted the clocks from the E1 that did not pass the TS crossoverequipment. The out-of-lock problem of the BTS was removed and the BTS started totrace its upper level clock.
VI. The reference source not available due to too small amplitude of 8k1
reference source
Description
After XX BTSs cutover, most of the BTSs were found in fast pull-in state and crystaloscillator override alarm was reported many times. The maintenance personnel
checked the BSC clocks and found them normal. They then checked MSC clocks andfound the 8kHz 1 reference source abnormal.
Handling process
The maintenance personnel tested the 2MHz differential signals output from the MSMon the pins at the back of the MSM backplane with an oscillometer and a frequencymeter. The square wave pulse voltage was only 68 mV and the frequency was onlyaround 2.048MHz.
Analysis
The fault was probably caused by too small signal level. After tested with thefrequency meter, it was 1.75MHz. After MSM replacement, the clocks resumed
normal. Therefore, it can be inferred that the fault was caused by MSM problem.
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VII. Clock fault due to CKB DIP switches setting error
Description
During batch GCKS replacement in the office X, the GCKS of the older versionworked normally in the slot 6 of the clock frame. But it was displayed faulty after beingreplaced with the GCKS of the new version.
Handling process
The maintenance personnel checked the DIP switches on CKB and found the S4 wasincorrectly set as ON ON ON OFF. Therefore it was the S4 setting error that causedthe abnormal working of new-version GCKS in slot 6.
Analysis
Under multi-module BSC, the communication between GCKS and GMCCM adoptspoint to multi-point mode. Since the serial port on GCKS0 in slot 4 in the clock frameis directly connected to the serial port cables communicating with GMCCS, the settingof the DIP switches exerts impact on the serial port communication of GCKS1 in slot6 instead of that of the GCKS0 in slot 4 in the clock frame.
VIII. Clock fault due to connection problem of clock cables and the
backplane
Description
In XX local network, there was no voice when calls were connected, and Group0clock fault alarm was reported to GCTN in AM/CM (Group0 clock refers to the clocksignals transmitted from GCKS0 to GCTN or to GSNT. Group1 clock refers to theclock signals from GCKS1 to GCTN or to GSNT).
Handling process
The maintenance personnel pulled out the active GCKS0 and performedactive/standby switchover to the boards. Then the network worked normally.
Analysis
After test, it was confirmed that the fault was caused by the clock cable connectionproblem between the CKB and the group0 4MHz clock cable of GCTN 0. Replace theclock cable and the CKB, the fault can be removed.
5.4.2 Troubleshooting Examples for BTS Clock Fault
I. Clock fault because TMU13MHz clock cannot lock th external clock
Description
In office deployment, The maintenance personnel found that the BSIC of A BTS couldnot be unlocked and the TMU of BTS A was in free-run state. In the BSCconfiguration data, the working state of BTS A was set as Tracing BSC clocks, butthe actual state was free-run. The D/A value of TMU OXCO was 1470.
Troubleshooting process: The maintenance personnel tested the T2MHz and T13MHzoutput of the BTS TMU with a frequency meter and found the deviation of the twoclocks was very big, as given in the following.
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T2MHz 2047996Hz 2048006Hz
T13MHz 12999993Hz 12999994Hz
From the above test result, the clock deviation of the T2MHz was very big and it was
necessary to check whether it was poor transmission quality or the TMU 21Q554 chipproblem that caused the clock deviation.
The maintenance personnel selected a BTS B that was working normally in externalclock mode, and then they tested the output of the T2MHz and T13MHz clocks withthe frequency meter.
T2MHz 2047999Hz 2048000Hz
T13MHz 13000000Hz 13000000Hz
They switched the TMU of the BTS B to the BTS A and tested the clock output ofTMU with a frequency meter.
T2MHz 2047993Hz
2048009HzT13MHz 13000000Hz 13000000Hz
From the above test, it can be confirmed that the transmission of the BTS B was notstable and the clock deviation was big. But the TMU of BTS B could still lock theexternal clocks in BTS A and output standard 13MHz clocks. Therefore, though thetransmission quality was poor, it was not the cause for the free-run state of the TMUin BTS A.
After switching the TMU of BTS A back, they adjusted the D/A value of the OXCO withthe frequency meter. They found that the TMU could output standard 13MHz clocksand successfully locked the external clock when the D/A value was 1910.
Analysis
The following three conclusions can be drawn from the troubleshooting process.
1) The transmission quality of BTS A is poor, but it is not the cause for the problem
that the TMU cannot lock the external clock.
2) The chips of the TMU in BTS A are not damaged, because the TMU can work
normally when the D/A value is 1910.
3) The root cause for the fault is that the deviation between the setting of the D/A
value of the OXCO in the TMU of BTS A and the actual value is too big (1910-
1470=440).
The maintenance personnel had traced the status of the TMU in BTS A for three
weeks and found the value of the phase discriminator stayed around 1910 and theTMU worked normally. This means the fault has been removed.
II. Faults are located segment bu segment accoriding to the signal flow
Description
In site X, TRX could not be started normally.
Troubleshooting process: The maintenance personnel powered off the BTS, thenproceeded in the following procedures.
1) Replaced the connection cable between CMBJ25 and TRBJC3. But the TRX still
could not be started.
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2) Replaced the TRB and the TRX could be started. But, master clock alarms were
reported during the operation.
3) Checked the DIP switches, the cables and the matching connectors of the TDU,
CMB and TRB and found no error.
4) Pulled out, then pushed in all TRXs one by one, and powered on them. But the
fault could not be removed.
5) Replaced TMU and reset the BTS X. The fault disappeared.
6) Re-installed the replaced TMU and the master clock alarm occurred again.
Therefore, it can be confirmed that the TMU was faulty.
7) Replaced the faulty TMU with the normal one and tested the BTS X. The
operating status of boards was normal.
Analysis
The BTS worked normally after TMU was replaced and master clock alarm occurredto the original TMU. From the fact, it can be inferred that the TMU fault caused theTRX unable to be started normally.
III. Clock fault due to operation errors
Description
13MHz clock out-of-lock alarm was found in many BTSs in X area.
Troubleshooting process: The maintenance personnel configured the 13MHz clockunder free-run mode at the local end and tested the output T13M of the BTS. Theyfound the output deviation was around 5Hz. They adjusted the D/A value and foundthe 13MHz clocks working normally under free-run mode. They then configured theclocks of the BTS under Tracing the upper level clock mode and found the BTSnormal without any out-of-lock alarm.
Analysis
The fault was caused by operation errors. The default clock D/A value on the clockO&M interface was 2048, while the D/A value adjusted for the boards was between1100 and 1600. When the user queried the interface and pressed to exit theinterface, the system would start clock capturing with the default D/A value. Under thiscase, the output of the 13MHz clocks was around 13MHz+5Hz, 5Hz deviated from theex-factory 13MHz. The version of many clocks in the BTS in the field was 0407,which usually gave up clock capturing of the reference clocks 4Hz deviated from thevalue of the 13MHz phase discriminator and adopted free-run clock mode. Thus, the
13MHz clock out-of-lock alarm was reported.
IV. Troubleshooting example 1 for faulty TMU
Description
In the BTS in X area, TRX repeatedly loaded the software, TRX communicationalarm, TRX micro-processor fault and frame TS alarm was also reported.
Troubleshooting process: The maintenance personnel checked the output signalpulse of the 13MHz clocks of the TMU and found them intermittently disruptive. Theyreplaced the TMU and the BTS resumed normal.
Analysis
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Troubleshooting ManualM900/M1800 Base Station Subsystem
Chapter 5 Troubleshooting for Clock
TMU was damaged and 13MHz clocks were unstable.
V. Troubleshooting example 2 for faulty TMU
Description
In X local network, the TRX stayed in downloading state after BAM reset. There werehistory alarms such as 2166 TRX master clock alarm and 2136, test phase-lockedloop alarm, the clock of the TMU was in slave state, and to rest the TMU and TRXfrom the remote end failed.
Troubleshooting process: The maintenance personnel found that the transmission atthe local end was normal and the ALM indicator on the TRX was ON. He performeddebugging on the MMI and found there was no reset hole beside the RST silk print onthe handle bar. He first mistaken that the RST hole was covered by the yellow ESDlabel. But, he then found that the clock of the TMU was a slave clock and the softreset cannot be performed. On the local end, there was master clock alarm and E1local end alarm, and the TRX was still in alarm state after hard reset of TMU at thelocal end and the TRX repeatedly downloaded software. He replaced the TMU andthe BTS resumed normal.
VI. Troubleshooting examples for BTS3001C version fallback
Description
The cell handover success rate of BTS3001C microcell in X area drops sharply.
Troubleshooting process: The maintenance personnel tested the 13MHz clock outputdeviation of the BTS with a frequency meter and found it reached around 27Hz. Hechecked the version of the BTS and found the version of the BTS fell back from05.0301A to BOOT 03.0301A. He re-activated the software and the fault disappeared.
Analysis
After version fallback, the versions of the BTS are not matched, so deviation of theBTS clocks occurs.