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GSM Alarm

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Slide 1
Troubleshooting Common
Ericsson GSM Alarms
A step by step guide.
Slide 2
Common Ericsson GSM Alarms
• MO FLT= OML FAULT
• DIGITAL PATH FAULT SUPERVISION
• CELL LOGICAL CHANNEL
AVAILABILITY SUPERVISION
• MO FLT= PERMANENT FAULT
• MO FLT= BTS INTERNAL
Slide 3
Common Ericsson GSM Alarms
Cont.
• EXTERNAL ALARMS; see Additional Info
• PWR COMMERCIAL;RECT 24V
MAINS;BATTERY
• CORRELATED LIKE: MO FLT= TS
SYNC FAULT
• CELL LOGICAL CHANNELS SEIZURE
SUPERVISION
• CP AP COMMUNICATION FAULT
Slide 4
Common Ericsson GSM Alarms
Cont.
• MO FLT= LOOP TEST FAILED
• LOCAL MODE & OPERATOR
CONDITION
Slide 5
MO FLT= OML FAULT
• A fault exists in the communications link
between the BSC and the BTS.
• Alarm can come in as either Major or Critical.
• Can come in on the CF, TRX, or both.
• 90% of the time is due to a down or faulty T1.
• Can also result from a faulty TRX or loss of
communication from the BSC to the TRX.
NOTE:
Prior to troubleshooting this or any other Ericsson alarm, always perform a right
click on the alarm in Netcool and chose the ―View alarms at this Location‖
option to view all alarms at this site to see if this could be a secondary affect
caused by power, maintenance, ECT and always search CTS to see if there is an
existing Ticket on the site for this or any related issue.
Slide 6
Recommended Troubleshooting
Steps
SKCAB07
SCRMCAT021
MO=RXOCF-55 SLOGAN=OML FAULT
1. Log into appropriate Complex/BSC and
retrieve an alarm list for the parent RXOTG
by running the RXASP:MO=RXOTG-__;
for the CF listed.
The TG number will be the same as the CF listed in the alarm.
Slide 7
RXASP:MO=RXOTG-55;
Connecting to SKCAB07... (Use 'quit' to logoff)
<rxasp:mo=rxotg-55;
RADIO X-CEIVER ADMINISTRATION
MANAGED OBJECT ALARM SITUATIONS
MO
RXOTG-55
RXOCF-55
RXOTRX-55-0
RXOTRX-55-1
RXOTRX-55-2
RXOTRX-55-3
RXOTRX-55-4
RXOTRX-55-5
RXOTRX-55-6
RXOTRX-55-8
RXOTRX-55-9
RXOTRX-55-10
RSITE
ALARM SITUATION
SCRMCAT021
SCRMCAT021
OML FAULT
SCRMCAT021
OML FAULT
SCRMCAT021
OML FAULT
SCRMCAT021
OML FAULT
SCRMCAT021
OML FAULT
SCRMCAT021
OML FAULT
SCRMCAT021
OML FAULT
SCRMCAT021
OML FAULT
SCRMCAT021
OML FAULT
SCRMCAT021
OML FAULT
SCRMCAT021
OML FAULT
END
As we can see the MO’s in this TG show multiple OML faults indicating a down or
dirty T1. The next step is to status the primary DIP for the site to determine if it is
blocked.
Slide 8
2. Status the primary DIP
<dtstp:dip=55rb3;
DIGITAL PATH STATE
DIP
TYPE
55RB3 IEX
STATE LOOP TSLOTL DIPEND FAULT
ABL
AIS
SECTION
END
Use the DTSTP:DIP=55rb3; command to status the DIP. This printout shows the
state of the DIP is ABL or Automatically Blocked and has an AIS (Alarm
Indication Signal).
This indicates that this site has a dead T1 and a Ticket should be created and
escalated to Telco to test the circuit.
Slide 9
3. Create a CTS Ticket
Connecting to SKCAB07... (Use 'quit' to l ogoff)
<rxasp:mo=rxotg-55;
RADIO X-CEIVER ADMINISTRATION
MANAGED OBJECT ALARM SITUATIONS
MO
RXOTG-55
RXOCF-55
RXOTRX-55-0
RXOTRX-55-1
RXOTRX-55-2
RXOTRX-55-3
RXOTRX-55-4
RXOTRX-55-5
RXOTRX-55-6
RXOTRX-55-8
RXOTRX-55-9
RXOTRX-55-10
RSITE
ALARM SITUATION
SCRMCAT021
SCRMCAT021 OML FAULT
SCRMCAT021 OM L FAULT
SCRMCAT021 OM L FAULT
SCRMCAT021 OM L FAULT
SCRMCAT021 OM L FAULT
SCRMCAT021 OM L FAULT
SCRMCAT021 OM L FAULT
SCRMCAT021 OM L FAULT
SCRMCAT021 OM L FAULT
SCRMCAT021 OM L FAULT
SCRMCAT021 OML FAULT
END
<dtstp:dip=55rb3;
DIGITAL PATH ST ATE
DIP
T YPE STATE LOOP TSLOTL DIPEND FAULT
55RB3 IEX
ABL
AIS
END
SECTION
Open a CTS ticket on this site from the OML fault alarm. Paste this information
along with the RXASP printout and the Granite (ED) path into the Ticket and
send it to Telco to have the circuit tested. No further actions will be needed at this
point.
If the DTSTP printout shows the DIP as WO or Working, the DIP may be working
but taking errors. In this case proceed on to step 4, checking the quality of the
DIP.
NOTE: The primary DIP is usually numbered the same as the RXOTG.
However, sometimes the OML links are placed onto the secondary DIP at
the site. If this is the case, the primary DIP may show WO when a portion
of the site is down (when in reality it is the second DIP that has faulted out).
You may need to determine what the secondary DIP is (if it exists) and
status it. It is important to get the correct DIP information to the field / telco
group so the correct circuit will be tested.
Slide 10
4. Status the DIP Quality
<dtqup:dip= 55rb3;
DIGITAL PATH QUALITY
UNACCEPTABLE PERFORMANCE LEVEL
INCOMING DIRECTION
DIP SECTION T1 N-ES N-SES N-UAS N-UAV SLIP SMI
55RB3
5
0
0
307
0
0
0
OUTGOING DIRECTION
DIP SECTION T1 F-ES F-SES F-UAS F-UAV SMI
55RB3
5 0
0
0
0
0
DEGRADED PERFORMANCE LEVEL
INCOMING DIRECTION
DIP SECTION T2 N-ES N-SES N-UAS N-UAV SLIP SMI
55RB3
10 0
0
4641 1
0
0
OUTGOING DIRECTION
DIP SECTION T2 F-ES F-SES F-UAS F-UAV SMI
55RB3
10 0
0
0
0
0
FRAME SLIPS
DIP SECTION SF V SFTI
55RB3
0
24
The next step would be to check the quality of the DIP by running the
DTQUP:DIP=___; command to see if it is taking errors
The quality printout shows this DIP is taking errors in the N-UAS section which is
the Unavailable seconds for unacceptable and degraded performance level for
the near end (incoming direction). In this case a ticket will need to be generated
and sent to telco as well with this printout, the RXSP printout and the ED path.
Any errors in these fields indicates a faulty T1 that will need to be ticketed and
tested by telco.
If the DIP counters read all zeros with no errors, the DIP appears clean and you
have verified the secondary DIP’s, then create a CTS ticket to send to telco with
your notes and troubleshooting steps and have them test the circuit to verify. If
the circuit tests clean and the OML faults are still present then forward the ticket
to the field to have them check the TRX’s. If the circuit test clean and the OML
faults clear, wait about 20 minutes and status the site again. If the OML faults
clear then the site has restored and you can close the TT. If the faults return then
send the ticket to the field tech with your troubleshooting notes to have him
investigate the issue.
It is important to note at this point that the CF/TG number are not always the
same as the DIP number. Secondary T1’s will have a number different than that
of the TG. There can be 2 or more DIP’s assigned to a CF/TG. In these cases
you will need to run a few extra commands to find the correct DIP number to
status and include in your ticket. Consider the following example using the same
commands used on the previous example.
Slide 11
MO FLT= OML FAULT MO= RXOCF-90 SLOGAN=OML FAULT
<rxasp:mo=rxotg-90;
RADIO X-CEIVER ADMINISTRATION
MANAGED OBJECT ALARM SITUATIONS
MO
RXOTG-90
RXOTRX-90-2
RXOTRX-90-4
RXOTRX-90-5
RXOTRX-90-6
RXOTRX-90-8
RSITE
LAD400
LAD400
LAD400
LAD400
LAD400
LAD400
ALARM SITUATION
OML FAULT
OML FAULT
OML FAULT
OML FAULT
OML FAULT
END
Status the TG using the RXASP command. As we can see there are OML faults
on this CF so the next step is to status the DIP as we did in the last example.
Slide 12
Status the DIP using the DTSTP
command
<dtstp:dip=90rb3;
DIGITAL PATH STATE
DIP
TYPE
90RB3 IEX
STATE LOOP TSLOTL DIPEND FAULT
WO
SECTION
END
As we see here the DTSTP printout indicates the DIP is in the WO or working
state so we will check the DIP quality printout for errors using the DTQUP
command.
Slide 13
Status DIP Quality DTQUP
<dtqup:dip=90rb3;
DIGITAL PATH QUALITY
UNACCEPTABLE PERFORMANCE LEVEL
INCOMING DIRECTION
DIP SECTION T1 N-ES N-SES N-UAS N-UAV SLIP SMI
90RB3
12 0
0
0
0
0 0
OUTGOING DIRECTION
DIP SECTION T1 F-ES F-SES F-UAS F-UAV SMI
90RB3
12 0
0
0
0
0
DEGRADED PERFORMANCE LEVEL
INCOMING DIRECTION
DIP SECTION T2 N-ES N-SES N-UAS N-UAV SLIP SMI
90RB3
14 0
0
0
0
0 1
OUTGOING DIRECTION
DIP SECTION T2 F-ES F-SES F-UAS F-UAV SMI
90RB3
14 0
0
0
0
1
FRAME SLIPS
DIP SECTION SFV SFTI
90RB3
0 24
END
As shown in the DIP quality printout there are no reported errors on this DIP. The
next step would be to look for a secondary DIP on this TG and then status it to
see if it is down or taking errors.
Slide 14
RXAPP Command
<rxapp:mo=rxotg-90;
RADIO X-CEIVER ADMINISTRATION
ABIS PATH STATUS
MO
RXOTG-90
DEV
DCP APUSAGE
RBLT3-1560 33 UNDEF
RBLT3-1561 34 UNDEF
RBLT3-1562 35 UNDEF
RBLT3-1563 36 UNDEF
RBLT3-1564 37 UNDEF
RBLT3-1565 38 UNDEF
RBLT3-1566 39 UNDEF
RBLT3-1567 40 UNDEF
RBLT3-1568 41 UNDEF
RBLT3-1569 42 UNDEF
RBLT3-1570 43 UNDEF
RBLT3-1571 44 UNDEF
RBLT3-1572 45 UNDEF
RBLT3-1573 46 UNDEF
RBLT3-1574 47 UNDEF
RBLT3-1575 48 UNDEF
RBLT3-1576 49 UNDEF
RBLT3-1577 50 UNDEF
RBLT3-1578 51 UNDEF
RBLT3-1579 52 UNDEF
RBLT3-1580 53 UNDEF
RBLT3-1581 54 UNDEF
RBLT3-1582 55 UNDEF
RBLT3-1583 56 UNDEF
RBLT3-2160
1 UNDEF
RBLT3-2161
2 UNDEF
RBLT3-2162
3 UNDEF
RBLT3-2163
4 UNDEF
APSTATE
IDLE
IDLE
IDLE
IDLE
IDLE
IDLE
IDLE
IDLE
IDLE
IDLE
IDLE
IDLE
IDLE
IDLE
IDLE
IDLE
IDLE
IDLE
IDLE
IDLE
IDLE
IDLE
IDLE
IDLE
IDLE
IDLE
IDLE
IDLE
64K TEI
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
The first command to run when looking for a secondary DIP is the
RXAPP:MO=RXOTG-__; This will show you the range of RBLT3 device numbers
attached to each DIP listed in sequential order.
Look at the result printout and find the range of RBLT or RBLT3 devices listed.
Usually it is easy to tell if there is more than one DIP assigned because the RBLT
range will have a noticeable skip in the numbering. In this case, the devices start
with RBLT3-1560 through 1583 (first DIP). Then jumps to RBLT3-2160 through
2183 (second DIP). Then Jumps again to RBLT3-5496 through 5513 (third DIP).
To find the DIP number form these devise ranges simply divide any number in
the device range by 24 and that will give you your DIP number. 1560/24=65 so
60RB3 is your first DIP. Then
2160/24=90, so 90RB3 is your second DIP.
5496/24=229 so 229RB# will be your third DIP. Now we can status all three DIP’s
to see which one is faulty.
Slide 15
RXAPP Command Cont.
RBLT3-21 67
RBLT3-21 68
RBLT3-21 69
RBLT3-21 70
RBLT3-21 71
RBLT3-21 72
RBLT3-21 73
RBLT3-21 74
RBLT3-21 75
RBLT3-21 76
RBLT3-21 77
RBLT3-21 78
RBLT3-21 79
RBLT3-21 81
RBLT3-21 83
RBLT3-54 96
RBLT3-54 97
RBLT3-54 98
RBLT3-54 99
RBLT3-55 00
RBLT3-55 01
RBLT3-55 02
RBLT3-55 03
RBLT3-55 04
RBLT3-55 05
RBLT3-55 06
RBLT3-55 07
RBLT3-55 08
RBLT3-55 09
RBLT3-55 10
RBLT3-55 11
RBLT3-55 12
RBLT3-55 13
RBLT3-55 14
RBLT3-55 15
RBLT3-55 16
RBLT3-55 17
RBLT3-55 18
RBLT3-55 19
8 UNDEF IDLE
YES
9 UNDEF IDLE
YES
10 UNDEF IDLE
YES
11 UNDEF IDLE
YES
12 UNDEF IDLE
YES
13 UNDEF IDLE
YES
14 UNDEF IDLE
YES
15 UNDEF IDLE
YES
16 UNDEF IDLE
YES
17 UNDEF IDLE
YES
18 UNDEF IDLE
YES
19 UNDEF IDLE
YES
20 UNDEF IDLE
YES
22 UNDEF IDLE
YES
24 UNDEF IDLE
YES
287 UNDEF IDLE
YES
288 UNDEF IDLE
YES
289 UNDEF IDLE
YES
290 UNDEF IDLE
YES
291 UNDEF IDLE
YES
292 UNDEF IDLE
YES
293 UNCONC SPEECH/DATA
YES
294 UNDEF IDLE
YES
295 UNDEF IDLE
YES
296 UNDEF IDLE
YES
297 UNDEF IDLE
YES
298 UNDEF IDLE
YES
299 UNDEF IDLE
YES
300 UNDEF IDLE
YES
301 UNDEF IDLE
YES
302 UNDEF IDLE
YES
303 UNDEF IDLE
YES
304 UNDEF IDLE
YES
305 UNDEF IDLE
YES
306 UNDEF IDLE
YES
307 UNDEF IDLE
YES
308 CONC TRXC SIGNAL
NO 2 3 4 5
309 CONC TRXC SIGNAL
NO 0 1
310 CONC
CF/TRXC SIGNAL NO 62 6 8 9 10
Look at the result printout and find the range of RBLT or RBLT3 devices listed.
Usually it is easy to tell if there is more than one DIP assigned because the RBLT
range will have a noticeable skip in the numbering. In this case, the devices start
with RBLT3-1560 through 1583 (first DIP). Then jumps to RBLT3-2160 through
2183 (second DIP). Then Jumps again to RBLT3-5496 through 5513 (third DIP).
To find the DIP number form these devise ranges simply divide any number in
the device range by 24 and that will give you your DIP number. 1560/24=65 so
60RB3 is your first DIP. Then
2160/24=90, so 90RB3 is your second DIP.
5496/24=229 so 229RB3 will be your third DIP. Now we can status all three DIP’s
to see which one is faulty
Slide 16
Status DIP 65RB3
<dtstp:dip=65rb3;
DIGITAL PATH STATE
DIP
TYPE STATE LOOP TSLOTL DIPEND FAULT
65RB3 IEX WO
END
SECTION
<dtqup:dip=65r b3;
DIGITAL PATH QUALITY
UNACCEPTABLE PERFORMANCE LEVEL
INCOMING DIRECTION
DIP
SECTION T1 N-ES N-SES N-UAS N-UAV SLIP SMI
65RB3
0 0 0 0
0 0 0
OUTGOING DIRECTION
DIP
SECTION T1 F-ES F-SES F-UAS F-UAV SMI
65RB3
0 0 0 0
0 0
DEGRADED PERFORMANCE LEVE L
INCOMING DIRECTION
DIP
SECTION T2 N-ES N-SES N-UAS N-UAV SLIP SMI
65RB3
14 0
0 0 0
0 0
OUTGOING DIRECTION
DIP
SECTION T2 F-ES F-SES F-UAS F-UAV SMI
65RB3
14 0
0 0 0
0
FRAME SLIPS
DIP
SECTION SFV SFTI
65RB3
0 24
END
Looking at both the status and the quality printouts for 65RB3 we can tell that this
DIP is up and clean with the state as WO and the error counters at all zeros.
Since we already know that 90RB3 is clean from the previous troubleshooting
steps, we will now status 229RB3.
Slide 17
Status DIP 229RB3
<dtstp:dip=229rb3;
DIGITAL PATH STATE
DIP TYPE STATE LOOP TSLOTL DIPEND FAULT
229RB 3 IEX ABL
RDI
END
SECTION
<dtqup:dip=229rb3;
DIGITAL PATH QUALITY
UNACCEPTABLE PERFORMANCE LEVEL
INCOMING DIRECTION
DIP SECTION T1 N-ES N-SES N-UAS N-UAV SLIP SMI
229RB 3
2 70 37 0 0 0 0
OUTGOING DIRECTION
DIP SECTION T1 F-ES F-SES F-UAS F-UAV SMI
229RB 3
2 0 0 138 0 0
DEGRADED PERFORMANCE LEVE L
INCOMING DIRECTION
DIP SECTION T2 N-ES N-SES N-UAS N-UAV SLIP SMI
229RB 3
14 2519 1411 0 0 4 1
OUTGOING DIRECTION
DIP SECTION T2 F-ES F-SES F-UAS F-UAV SMI
229RB 3
14 100 100 4907 2 1
FRAME SLIPS
DIP SECTION SFV SFTI
229RB 3
0 24
END
As we can see this DIP is ABL (auto blocked) and the counters are registering
several errors. This will be the DIP that you will put in the ticket and retrieve the
ED path for. From here Create a Ticket in CTS and put the RXASP printout with
this DIP information and the ED path for this DIP and send it to telco.
Slide 18
RXASP:MOTY=RXOCF; For Large Outages
<rxasp:moty =rxocf;
RADIO X-CEIVER ADMINISTRATION
MANAG ED OBJECT ALARM SI TUATIONS
MO
RXOCF-24
RXOCF-45
RXOCF-66
RXOCF-79
RXOCF-94
RXOCF-109
RXOCF-110
RXOCF-112
RXOCF-133
RXOCF-136
RXOCF-137
RXOCF-138
RXOCF-149
RXOCF-152
RXOCF-179
RXOCF-182
RXOCF-217
RXOCF-218
RXOCF-220
RXOCF-221
RXOCF-249
RSITE
ALARM SITUATI ON
AR2158
OML FAULT
AR2424
OML FAULT
AR2154
OML FAULT
AR2421
OML FAULT
AR2138
OML FAULT
AR2170
OML FAULT
AR2201
OML FAULT
AR2180
OML FAULT
AR2183
OML FAULT
AR2174
OML FAULT
AR2174
OML FAULT
AR2174
OML FAULT
AR2152
OML FAULT
AR2447
OML FAULT
AR2171
OML FAULT
AR2181
OML FAULT
AR2153
OML FAULT
AR2153
OML FAULT
AR2156
OML FAULT
AR2156
OML FAULT
AR2155
OML FAULT
END
During a possible outage situation where you have multiple sites showing OML
fault off the same BSC you can run the RXASP:MOTY=RXOCF; (you can
replace CF with TG, TRX, TS, ect..). This command will give you a printout of all
the CF’s that are in alarm with the site and condition for a quick count of how
many sites are affected.
Slide 19
DTSTP:DIP=ALL,STATE=ABL;
<dtstp:dip=all,state=abl;
DIGITAL PATH ST ATE
DIP TYPE STAT E LOOP TSLOTL DIPEND FAULT
12RB3 IEX ABL
AIS
13RB3 IEX ABL
AIS
24RB3 IEX ABL
AIS
42RB3 IEX ABL
AIS
45RB3 IEX ABL
AIS
46RB3 IEX ABL
AIS
56RB3 IEX ABL
AIS
66RB3 IEX ABL
AIS
67RB3 IEX ABL
AIS
79RB3 IEX ABL
AIS
80RB3 IEX ABL
AIS
81RB3 IEX ABL
AIS
94RB3 IEX ABL
AIS
95RB3 IEX ABL
AIS
110RB3 IEX ABL
AIS
111RB3 IEX ABL
AIS
112RB3 IEX ABL
AIS
133RB3 IEX ABL
AIS
136RB3 IEX ABL
AIS
137RB3 IEX ABL
AIS
138RB3 IEX ABL
AIS
139RB3 IEX ABL
AIS
152RB3 IEX ABL
AIS
153RB3 IEX ABL
AIS
156RB3 IEX ABL
AIS
182RB3 IEX ABL
AIS
183RB3 IEX ABL
AIS
SECTION
Along with the RXASP:MOTY=RXOCF; command you can run the
DTSTP:DIP=ALL,STATE=ABL; command to help correlate the DIP’s that are
down to the sites that are in alarm from the previous command during an outage
situation. This will give you a printout of all the DIP’s to the BSC that that are
blocked. You can also use this information to cross reference you DIP’s in
Granite (ED) for your circuit information. It is important to note that this printout
will give you all the DIPS at the BSC that ore ABL. Some of these may be switch
DIPs or secondary circuits not related to cell sites.
Slide 20
DIGITAL PATH FAULT SUPERVISION
DIGITAL PATH FAULT SUPERVISION
DIP=81RB3; FUALT=AIS
• Indicates A T1 is down or is above the
error threshold.
• Can be either a T1 to a cell site or a
―Switch DIP‖.
• Usually accompanied be an OML Fault
Alarm.
• Comprised of 24 devices, 1 for each DSO.
Slide 21
Recommended Troubleshooting
Steps
1. Log into the appropriate Complex/BSC
and status the DIP using the
DTSTP:DIP=____; (81RB3 in this case)
Command to check and see if the DIP is
down or taking errors.
Slide 22
Status DIP
Connecting to RVCAB08... (Use 'quit' to logoff)
<rxasp:mo=rxotg-81;
NOT ACCEPTED
UNREASONABLE VALUE
(0)MO=RXOTG-81
<dtstp:dip=81rb3;
DIGITAL PATH STATE
DIP
TYPE
81RB3 IEX
END
STATE LOOP TSLOTL DIPEND FAULT
ABL
AIS
As we can see here the DIP is ABL and the State is AIS (alarm indication signal).
When troubleshooting this alarm you can also begin, as I have done here, be
running the RXASP command and use the DIP number as the TG number since
often times the DIP number and the TG number are the same. This may be a
shortcut to correlating a site and TG to your DIP. You can cross reference the
info in the switch (which we will cover next) or in ED to check accuracy. In this
case The DIP is not the TG number so we will have to find the site/devices the
DIP is connected to the long way by checking the devices and SNT (switching
Network Terminal) it is connected to.
Slide 23
2.Find the SNTwith DTDIP
Command
<dtdip:dip=81rb3;
DIGITAL PATH DIP
81RB3
END
SNT
ETM3-2
DIPP DIPNUM SDIP DIPOWNER
54
303
2ETM3 DIPM3
TYPE
IEX
3. Status the SNT for the DIP's
and their Device ranges
The first step to researching the DIP is to find and status the SNT. The fist
command you need to run is the DTSTP:DIP=____; command to find the SNT.
With this we can see that the SNT is ETM3-2. with that in mind we can now
query the SNT to see all the DIP’s connected to it and the devises connected to
them.
Slide 24
3. Status the SNT for the DIP's and their Device ranges
NTCOP:SNT=EMT3-2;
<ntcop:snt=etm3-2;
SWITCHING NETWORK TERMINAL CONNECTION DATA
SNT
ETM3-2
SNTV SNTP
DIP
DEV
SNTINL
1 XM-0-0-6 234RB3 RBLT3-5616&&-5639
0
235RB3 RBLT3-5640&&-5663
1
236RB3 RBLT3-5664&&-5687
2
237RB3 RBLT3-5688&&-5711
3
238RB3 RBLT3-5712&&-5735
4
239RB3 RBLT3-5736&&-5759
5
240RB3 RBLT3-5760&&-5783
6
241RB3 RBLT3-5784&&-5807
7
79RA3 RALT3-1896&&-1919
13
80RA3 RALT3-1920&&-1943
14
81RA3 RALT3-1944&&-1967
15
82RA3 RALT3-1968&&-1991
16
83RA3 RALT3-1992&&-2015
17
84RA3 RALT3-2016&&-2039
18
85RA3 RALT3-2040&&-2063
19
86RA3 RALT3-2064&&-2087
20
87RA3 RALT3-2088&&-2111
21
88RA3 RALT3-2112&&-2135
22
89RA3 RALT3-2136&&-2159
23
90RA3 RALT3-2160&&-2183
24
91RA3 RALT3-2184&&-2207
25
92RA3 RALT3-2208&&-2231
26
93RA3 RALT3-2232&&-2255
27
94RA3 RALT3-2256&&-2279
28
95RA3 RALT3-2280&&-2303
29
96RA3 RALT3-2304&&-2327
30
97RA3 RALT3-2328&&-2351
31
98RA3 RALT3-2352&&-2375
32
99RA3 RALT3-2376&&-2399
33
100RA3 RALT3-2400&&-2423
34
101RA3 RALT3-2424&&-2447
35
102RA3 RALT3-2448&&-2471
36
103RA3 RALT3-2472&&-2495
37
To find all the DIP’s connected to this SNT and their range of devises connected
to them, you will need to run the NTCOP:SNT=EMT3-2; command. Scroll
through the DIP's connected until you find the one you are looking for. In this
case 81RB3.
Note: Some data (DIPS) were removed from this printout for spacing reasons.
Slide 25
3. Status the SNT for the DIP's and their Device ranges
NTCOP:SNT=EMT3-2; Cont.
SNT
ETM3-2
109RA3 RALT3-2616&&-2639
43
78RB3 RBLT3-1872&&-1895
51
79RB3 RBLT3-1896&&-1919
52
80RB3 RBLT3-1920&&-1943
53
81RB3 RBLT3-1944&&-1967
54
82RB3 RBLT3-1968&&-1991
55
83RB3 RBLT3-1992&&-2015
56
84RB3 RBLT3-2016&&-2039
57
85RB3 RBLT3-2040&&-2063
58
86RB3 RBLT3-2064&&-2087
59
87RB3 RBLT3-2088&&-2111
60
88RB3 RBLT3-2112&&-2135
61
89RB3 RBLT3-2136&&-2159
62
90RB3 RBLT3-2160&&-2183
63
91RB3 RBLT3-2184&&-2207
64
92RB3 RBLT3-2208&&-2231
65
93RB3 RBLT3-2232&&-2255
66
94RB3 RBLT3-2256&&-2279
67
95RB3 RBLT3-2280&&-2303
68
96RB3 RBLT3-2304&&-2327
69
97RB3 RBLT3-2328&&-2351
70
98RB3 RBLT3-2352&&-2375
71
99RB3 RBLT3-2376&&-2399
72
6RTG3 RTGLT3-144&&-167
81
7RTG3 RTGLT3-168&&-191
82
8RTG3 RTGLT3-192&&-215
83
EQLEV PROT SDIP SUBSNT DEFPST SNTP
1
2ETM3 0
XM-0-0-6
1
XM-0-0-17
MODE
2176
0
END
Now that we have found our DIP and its device range (located to the right of the
DIP number in the printout) we can status this device range. The devise range
numbers are the numeric value configured in the switch and the site for all 24
devises connected to that DIP.
Note: Some data (DIPS) were removed from this printout for spacing reasons.
Slide 26
4.Status the DIP’s Device Range
STDEP:DEV=RBLT3-1944&&-1967
<stdep:dev=RBLT 3-1944&&-1967;
DEVICE ST ATE DETAILS
DEV
SUBDEV
RBLT3-1944
RBLT3-1945
RBLT3-1946
RBLT3-1947
RBLT3-1948
RBLT3-1949
RBLT3-1950
RBLT3-1951
RBLT3-1952
RBLT3-1953
RBLT3-1954
RBLT3-1955 H'3F
RBLT3-1956 H'FF
RBLT3-1957 H'FF
RBLT3-1958 H'FF
RBLT3-1959 H'FF
RBLT3-1960 H'FF
RBLT3-1961
RBLT3-1962 H'3F
RBLT3-1963
RBLT3-1964
RBLT3-1965
RBLT3-1966
RBLT3-1967
END
STAT E
BLOC
BLOC
BLOC
BLOC
BLOC
BLOC
BLOC
BLOC
BLOC
BLOC
BLOC
BLOC
BLOC
BLOC
BLOC
BLOC
BLOC
BLOC
BLOC
BLOC
BLOC
BLOC
BLOC
BLOC
BLS ADM ABS CONFIG
ABL
H'00 PC
ABL
H'00 PC
ABL
H'00 PC
ABL
H'00 PC
ABL
H'00 PC
ABL
H'00 PC
ABL
H'00 PC
ABL
H'00 PC
ABL
H'00 PC
ABL
H'00 PC
ABL
H'00 PC
ABL
H'00 PC
ABL
H'00 PC
ABL
H'00 PC
ABL
H'00 PC
ABL
H'00 PC
ABL
H'00 PC
ABL
H'00 PC
ABL
H'00 PC
ABL
H'00 PC
ABL
H'00 P
ABL
H'00 P
ABL
H'00 P
ABL
H'00 P
This shows the status of the devise range which we can see is ABL. Also it
shows us that the devises are provisioned for those time slots under the config
column with the PC or P (provisioned Configured and Provisioned) next to them.
If they were not configured it would show NP (Not Provisioned). It is important to
note the Config status as if they were listed as NP then this DIP has not yet been
provisioned in the Switch and the only further action would be to send a Minor TT
to the switch to have them turn this DIP down until provisioned so we don’t keep
getting alarms on it.
From here we can now find the TG and site connected to the DIP.
Slide 27
5. Find the Site and TG.
RXMDP:MOTY=RXOTS,DEV=RBLT3-1952;
<rxmdp:moty=rxots,dev=rblt3-1952;
RADIO X-CEIVER ADMINISTRATION
MANAGED OBJECT DEVICE INFORMATION
MO
DEVS
RXOTS-79-9-4
DEVT
RBLT3-1952
SDEV
1111
END
To find the TG and the site from the previous info, run the
RXMDP:MOTY=RXOTS,DEV=RBLT3-1952; command. This can be ran on any
provisioned device in the range. Also, you can replace the TS (time slot) for TRX.
What this output shows us is that the there is a timeslot allocated to this rblt3
deice and it is RXOTS-79-9-4. 79 is your TG number, 9 is your TRX number and
4 is the timeslot number. With this in mind we can now run the
RXASP:MO=RXOTG-79; command since we know this is on TG 79 from the
printout. This will of course give us the site ID and the alarm situation for that TG.
Slide 28
6. Status the TG to get the site ID
<rxasp:mo=rxotg-79;
RADIO X-CEIVER ADMINISTRATION
MANAGED OBJECT ALARM SITUATIONS
MO
RXOTG-79
RSITE
LA8041
ALARM SITUATION
END
Our status here shows that this TG appears to be alarm free. However we know
this is not the case. With Ericsson, when you have a secondary DIP that goes
down, it may not always show up in the alarm printout for the RXASP command
but that doesn’t mean it’s not in alarm. We can view all the radios and the
timeslots and their status by running the RXMSP:MO=RXOTG-79,SUBORD;
command to verify that this TG does in fact have a bad T1.
Slide 29
7. Verifying the TG has a down T1.
RXMSP:MO=RXOTG-79,SUBORD;
<rxmsp:mo=rxotg-79,subord;
RADIO X-CEIVER ADMINISTRATION
MANAGED OBJECT STATUS
MO
STATE BLSTATE
RXOTG-79
OPER
RXOCF-79
OPER
RXOIS-79
OPER
RXOCON-79 OPER
RXOTRX-79-0 OPER
RXORX-79-0 OPER
RXOTS-79-0-0 OPER
RXOTS-79-0-1 OPER
RXOTS-79-0-2 OPER
RXOTS-79-0-3 OPER
RXOTS-79-0-4 OPER
RXOTS-79-0-5 OPER
RXOTS-79-0-6 OPER
RXOTS-79-0-7 OPER
RXOTX-79-0 OPER
RXOTRX-79-1 OPER
RXORX-79-1 OPER
RXOTS-79-1-0 OPER
RXOTS-79-1-1 OPER
RXOTS-79-1-2 OPER
RXOTS-79-1-3 OPER
RXOTS-79-1-4 OPER
RXOTS-79-1-5 OPER
RXOTS-79-1-6 OPER
RXOTS-79-1-7 OPER
RXOTX-79-1 OPER
RXOTRX-79-4 OPER
RXOTRX-79-5 OPER
BLO BLA LMO BTS
0000 0000
STA
0000 0000
STA
0000 0000
DIS
0000 0000
DIS
0000 0000
STA
0000 0000 0000 ENA
0000 0000 0000 ENA
0000 0000 0000 ENA
0000 0000 0840 DIS
0000 0000 0840 DIS
0000 0000 0840 DIS
0000 0000 0840 DIS
0000 0000 0000 ENA
0000 0000 0000 ENA
0000 0000 0000
ENA
0000 0000
STA
0000 0000 0000
ENA
0000 0000 0840
DIS
0000 0000 0840
DIS
0000 0000 0840
DIS
0000 0000 0840
DIS
0000 0000 0840
DIS
0000 0000 0840
DIS
0000 0000 0000
ENA
0000 0000 0000
ENA
0000 0000 0000
ENA
0000 0000
STA
0000 0000
STA
CONF
CONF
CONF
ENA
ENA
ENA
UNCONF
UNCONF
UNCONF
UNCONF
ENA
ENA
ENA
ENA
UNCONF
UNCONF
UNCONF
UNCONF
UNCONF
UNCONF
ENA
ENA
ENA
From this Printout we can see the TRX’s, subordinate timeslots, and their status.
As we look we can see that in the BTS column there are several timeslots that
are DIS or disabled as well as the CONF column where you can see the same
timeslots listed as UNCONF or unconfigured along with the LMO column with the
HEX code stating an issue. At this point with all the information we have we
would create a CTS ticket to send to Telco with the DTSTP, RXASP, and the
RXMSP along with the correct ED path for the circuit to be tested.
Looking at this we see that not all the timeslots are in order or on the same
radio. This is done to split the rescores from the different T1’s to each sector for
redundancy purposes.
Slide 30
7. RXMSP:MO=RXOTG-79,SUBORD; Cont.
RXOTS-79-6-6 OPER
RXOTS-79-6-7 OPER
RXOTX-79-6 OPER
RXOTRX-79-7 OPER
RXORX-79-7 OPER
RXOTS-79-7-0 OPER
RXOTS-79-7-1 OPER
RXOTS-79-7-2 OPER
RXOTS-79-7-3 OPER
RXOTS-79-7-4 OPER
RXOTS-79-7-5 OPER
RXOTS-79-7-6 OPER
RXOTS-79-7-7 OPER
RXOTX-79-7 OPER
RXOTS-79-9-0 OPER
RXOTS-79-9-1 OPER
RXOTS-79-9-2 OPER
RXOTS-79-9-3 OPER
RXOTS-79-9-4 OPER
RXOTS-79-9-5 OPER
RXOTS-79-9-6 OPER
RXOTS-79-9-7 OPER
RXOTX-79-9 OPER
RXOTRX-79-10 OPER
RXORX-79-10 OPER
RXOTS-79-10-0 OPER
RXOTS-79-10-1 OPER
RXOTS-79-10-2 OPER
RXOTS-79-10-3 OPER
RXOTS-79-10-4 OPER
RXOTS-79-10-5 OPER
RXOTS-79-10-6 OPER
RXOTS-79-10-7 OPER
RXOTX-79-10 OPER
END
0000 0000 0840 DIS UNCONF
0000 0000 0840 DIS UNCONF
0000 0000 0000 ENA ENA
0000 0000
STA
0000 0000 0000 ENA ENA
0000 0000 0000 ENA ENA
0000 0000 0000 ENA ENA
0000 0000 0000 ENA ENA
0000 0000 0000 ENA ENA
0000 0000 0000 ENA ENA
0000 0000 0000 ENA ENA
0000 0000 0840 DIS UNCONF
0000 0000 0840 DIS UNCONF
0000 0000 0000 ENA ENA
0000 0000 0000 ENA ENA
0000 0000 0840 DIS UNCONF
0000 0000 0840 DIS UNCONF
0000 0000 0840 DIS UNCONF
0000 0000 0840 DIS UNCONF
0000 0000 0840 DIS UNCONF
0000 0000 0840 DIS UNCONF
0000 0000 0840 DIS UNCONF
0000 0000 0000 ENA ENA
0000 0000
STA
0000 0000 0000 ENA ENA
0000 0000 0840 DIS UNCONF
0000 0000 0840 DIS UNCONF
0000 0000 0840 DIS UNCONF
0000 0000 0840 DIS UNCONF
0000 0000 0840 DIS UNCONF
0000 0000 0840 DIS UNCONF
0000 0000 0840 DIS UNCONF
0000 0000 0840 DIS UNCONF
0000 0000 0000 ENA ENA
Slide 31
MO FLT= BTS INTERNAL
MO FLT= BTS INTERN AL 2 alarms: RXOTX-195-0 RXOTX-195-1
• A fault has occurred in the CF or in one or
more of the MO’s
• Can occur in the CF, TRX, RXOTX, RXORX
• Usually presents in Netcool as a Major
• Can sometimes be restored remotely
Slide 32
Recommended Troubleshooting
Steps
1.
Retrieve alarm printout from parent RXOTG
RADIO X-CE IVER ADMINIS TRA TION
MANAGE D OBJE CT ALARM SITUA TIONS
MO
RXOTG-195
RXOCF-195
RXOTX-195-0
RXOTX-195-1
RSITE
LA0166
LA0166
LA0166
LA0166
ALARM SITUA TION
BTS INT UNAFFECTE D
BTS INT AFFE CTE D
BTS INT AFFE CTE D
END
Determine if the fault is service-affecting or if any other MO’s are in alarm by
looking at the alarm list for the parent RXOTG. If it shows ―BTS INT
UNAFFECTED‖, this will generally not be service-affecting and will not warrant a
critical ticket on the RXOCF itself
If any other MO’s show ―AFFECTED‖ alarm situations, then troubleshoot them
appropriately. The fault codes reflected by the RXOCF will aid in determining the
problems on any subordinate MO’s.
When the RXOTX or RXORX show ―BTS INT AFFECTED‖, it is out of service
(blocked). Usually the RXOCF or the parent RXOTRX will show a ―BTS INT
UNAFFECTED‖ but will not be blocked. However, because the TX and RX are
blocked, from an operational standpoint the TRX is out of service as well since it
has no operating transmit or receive function.
Look the fault code up in the maintenance manual fault list to determine what it
means. The manual may also direct you to pull the fault codes from the parent
MO’s that are showing unaffected faults to help further isolate the problem.
2) Retrieve the fault code(s) for the RXOCF
Slide 33
2. Retrieve the fault code(s) RXMFP:MO=RXOTG195,SUBORD,FAULTY;
<rxmfp:mo=rxotg-195,subord,faulty;
RADIO X-CEIVER ADMINISTRATION
MANAGED OBJ ECT FAULT INFORMATION
MO
RXOCF-195
BTSSWVER
ERA-G04-R08-V01
4 KRY 101 1856/1
R 3C
RU RUREVISION
5 BGM1361001/3
R3A
RUPOSITION
C:0 R:C SH: 1 SL: 37
RU RUREVISION
7 SEB1121095/1
TR41515198
RUSERIALNO
B991781311
RULOGICALID
FC FCU_01 0
R5B
RUPOSITION
C:0 R:C SH: 8 SL:---
RUSERIALNO
TU85160324
RULOGICALID
CABI 2206 0
STATE BLST ATE INTERCNT CONCNT CONERRCNT LASTFLT LFREASON
OPER
00031
FAULT CODES CLASS 2A
8
REPLACEMENT UNITS
2) Retrieve the fault code(s) for the MO
Note: The actual faults are listed at the end of the printout.
Slide 34
2. Retrieve the fault code(s) Cont.
40
MO
RXOTX-195-0
BTSSWVER
ER A-G04-R08-V01
RU RUREVISION
0
RUPOSIT ION
RUSERIALNO
RULOGICALID
STATE BLST ATE INTERCNT CONCNT CONERRCNT LASTFLT LFREASON
NOOP BLO
00000
FAULT CODES CLASS 1B
4
MO
BTSSWVER
RXOTX-195-1
ER A-G04-R08-V01
RU RUREVISION
0
RUPOSIT ION
RUSERIALNO
RULOGICALID
STATE BLST ATE INTERCNT CONCNT CONERRCNT LASTFLT LFREASON
NOOP BLO
00000
FAULT CODES CLASS 1B
4
END
2) Retrieve the fault code(s) for the MO
Note: The actual faults are listed at the end of the printout. From here we can
see that the fault in on RXOTX-195-0 and 195-1. The fault code is 1B4. We can
now reference our documentation to see what the fault is and what actions are
required.
Slide 35
3. Reference the Fault code
Fault No. AO TX I1B:
4
Fault name: TX antenna VSWR limits exceeded
Related fault:
SO CF I2A:8 – VSWR limits exceeded
SO CF RU:40 – Antenna
Description: When VSWR at CDU output exceeds the class 2 limit
defined in IDB with OMT (default value: 1.8), the fault SO CF I2A:8
arises with RU map "Antenna". When VSWR exceeds the class 1
limit (default value: 2.2), the fault AO TX I1B:4 arises on TX.
Possible reas ons:
Faulty IDB
Faulty CDU
TX antenna/feeder faulty or disconnected
Pfwd/ Prefl cables faulty
Measurement receiver in TRU/CU (in some cases) faulty.
Action
Reference the fault code given from our documentation to view the fault and see
what are the next steps to take. From our documentation we can see that this is
a VSWR alarm
Fault Internal 1A 4 ―TX Antenna VSWR Limits Exceeded‖
This fault means that the VSWR (voltage standing wave ratio) on the transmit
antenna or antenna feeder is too high. To keep the reflected power from burning
up the transmitter or power amplifiers, the transmitter is shut down. The RXOCF
will usually also show unaffected fault internal 2A 8 as well.
This fault is NOT remote-repairable. Even if it is a bogus alarm, generally any
blocking/deblocking of TX, TRX, CF, etc will only remove the alarm for a short
period of time, and it will return on the next periodic VSWR measurement.
Cut a ticket to the field with RXASP and RXMFP printout and explanation that TX
has high VSWR. The radio is out of service.
Slide 36
CELL LOGICAL CHANNEL
AVAILABILITY SUPERVISION
CELL LOGICAL CHANNEL AVAILABILITY SUPERVISION CELL=SD0379Y; CHTY PE=TCH
• Generated to inform you that a number of
available channels have fallen below defined
limits.
• Usually accompanied or correlated with
additional alarms for the MO’s that have
caused the channel failures.
• Can present as a Critical or Major in Netcool.
• Can also be caused by a down T1.
Slide 37
Recommended Troubleshooting
Steps
1. Right click on the alarm in Netcool and
chose the ―View Alarms At This Location‖
option to see if there are secondary or
correlated faults that may be causing the
Alarm.
1A. If there are no secondary or correlated
alarms, search CTS on the site for
previously opened tickets.
Usually these are accompanied by secondary and/or correlated alarms. These
can come in as Major or Critical alarms. If you do find a secondary alarm, no
matter the severity, troubleshoot that alarm as instructed before moving on to the
next step. If there are no other issues at the site then we will proceed to find the
correct TG for the site in the alarm.
Slide 38
2. Find the correct TG correlated
with the alarm.
CELL LOGICAL CHANNEL AVAILABILITY SUPERVISION CELL=SD0379Y; CHTY PE=TCH
Connecting to SDCAB09... (Use 'quit' to logoff)
<rxtcp:cell=sd0379y,moty=rxotg;
RADIO X-CEIVER ADMINISTRATION
TG TO CHANNEL GROUP CONNECTION DATA
MO
RXOTG-91
CELL
SD0379Y
SD0379Y
CHGR
0
1
END
From looking at the alarm we do not have the TG number to status the alarm
situation. However, we can see the Cell ID in the alarm. From that we can get the
TG number. By looking at the alarm we see in the text that the alarm is on
sd0379 on sector ―Y‖. We can query the cell with the site and sector information.
To find the correct TG to a cell in these alarms you must first run the
RXTCP:CELL=SD0379Y,MOTY=RXOTG; command. This will give you the TG
ID from the cell ID and the sector. We can now see from the printout that the
correct TG to status is 91 and status the TG with the RXASP command.
Slide 39
3. Status the Alarm Situation on the
TG.
<rxasp:mo=rxotg-91;
RADIO X-CE IVER ADMINIS TRA TION
MANAGE D OBJE CT ALARM SITUA TIONS
MO
RXOTG-91
RXOCF-91
RXOTX-91-4
RXOTX-91-5
RSITE
SD0379
SD0379
SD0379
SD0379
ALARM SITUA TION
BTS INT UNAFFE CTED
BTS INT AFFECTE D
BTS INT AFFECTE D
END
We can now see from the RXASP printout that there are internal faults on this TG
in 2 of the radios. They are on RXOTX 91-5 and 91-4. From here we can check
the status of the sectors and get our fault codes for the problem. Basically
working this issue like any other internal fault problem. You will need to run the
RXMFP:MO=RXOTG-91,SUBORD,FAULTY; command to get your fault codes
for these devises. We will run this command next.
Slide 40
4. Run RXMFP command to get
the fault codes.
<rxmfp:mo=rxotg-91,subord,faulty;
RADIO X-CEIVER ADMINISTRATION
MANAGED OBJECT FAULT INFORMATION
MO
RXOCF-91
BTSSWVER
ERA-G04-R08-V01
RU RUREVISION
0 BOE 602 17/1
R1B/A
RUPOSITION
C:0 R:C SH: 6 SL: 10
RU RUREVISION
1 BFL 119 437/1
RULOGICALID
DX DXU_22 0
R1E
RUPOSITION
C:1 R:C SH: 7 SL: 0
RU RUREVISION
2 SEB 112 1147/1
RUSERIALNO
TU86267283
RUSERIALNO
TR42305300
RULOGICALID
CD CDU_L8 0
R2A
RUPOSITION
C:0 R:C SH: 9 SL:---
RUSERIALNO
BK41017805
RULOGICALID
CABI 2250 TRX 0
STATE BLSTATE INTERCNT CONCNT CONERRCNT LASTFLT LFREASON
OPER
00000
FAULT CODES CLASS 2A
9
REPLACEMENT UNITS
59
Slide 41
4. Run RXMFP command to get
the fault codes. Cont.
MO
BTSSWVER
RXOTX-91-4
ERA-G04-R08-V01
RU RUREVISION
0
RUPOSITION
RUSERIALNO
RULOGICALID
STATE BLSTATE INTERCNT CONCNT CONERRCNT LASTFLT LFREASON
NOOP BLO 00000
FAULT CODES CLASS 1B
2
MO
BTSSWVER
RXOTX-91-5
ERA-G04-R08-V01
RU RUREVISION
0
RUPOSITION
RUSERIALNO
RULOGICALID
STATE BLSTATE INTERCNT CONCNT CONERRCNT LASTFLT LFREASON
NOOP BLO 00000
FAULT CODES CLASS 1B
2
END
<
We already know from the RXASP printout that the faults are internal on
RXOTX91-4 and 91-5. From here we can see that the faults codes on RXOTX91-4 and 91-5 are fault code class 1B2. We can now refer to our documentation
to see what this fault is and if it can be cleared remotely or if it will need a ticket
to be dispatched to the field.
Slide 42
5. Reference our documentation to find
the proper fault code procedure.
Fault No. AO TX I1B:
2
Fault name: CDU output power limits exceeded
Related fault:
SO CF I2A:9 – Power limits exceeded
Description: When TX power at CDU output is 7 dB lower than exp ected,
fault SO CF I2A:9 arises. When the difference is 10 dB, fault AO TX I1B:2
arises.
Possible reas ons:
There is probably a fault on the TX path. Other reas on: TX high temperature
or saturation (see AO TX I1B:12 and AO TX I1B:14).
Action: Try the following actions until the fault is corrected:
Check all TX cables, both inside and outside cabinet.
Check the CDU — CDU P fwd/Prefl cables.
Check the RU logs to see which TRU is emitting the fault.
Switch positions bet ween TRUs/CDUs to find out it is the units or the RF
cables that are faulty.
Reinstall the IDB.
From our documentation we can see that this is a CDU power limits exceeded
fault. As the procedure indicates, there is no remote action that can fix this issue.
At this point you would create a ticket in CTS and send it to the field with the
RXASP, and the RXMFP printouts and a statement stating the problem.
It is important to note that the RXASP printout will not always display active
alarms but their could still be resources down in the sector. To check this we
would run the RXMSP command for this TG.
Slide 43
6. If needed, Status the resources
in the sector.
<rxmsp:mo=rxotg-91,subord;
RADIO X-CEIVER ADMINISTRATION
MANAGED OBJECT STATUS
MO
STATE BLSTATE
RXOTG-91
OPER
RXOCF-91
OPER
RXOIS-91
OPER
RXOCON-91
OPER
RXOTRX-91-4 OPER
RXORX-91-4 OPER
RXOTS-91-4-0 OPER
RXOTS-91-4-1 OPER
RXOTS-91-4-2 OPER
RXOTS-91-4-3 OPER
RXOTS-91-4-4 OPER
RXOTS-91-4-5 OPER
RXOTS-91-4-6 OPER
RXOTS-91-4-7 OPER
RXOTX-91-4 NOOP BLO
RXOTRX-91-5 OPER
RXORX-91-5 OPER
RXOTS-91-5-0 OPER
RXOTS-91-5-1 OPER
RXOTS-91-5-2 OPER
RXOTS-91-5-3 OPER
RXOTS-91-5-4 OPER
RXOTS-91-5-5 OPER
RXOTS-91-5-6 OPER
RXOTS-91-5-7 OPER
RXOTX-91-5 NOOP BLO
BLO BLA LMO
0000 0000
0000 0000
0000 0000
0000 0000
0000 0000
0000 0000 0000
0000 0000 0840
0000 0000 0840
0000 0000 0840
0000 0000 0840
0000 0000 0840
0000 0000 0840
0000 0000 0840
0000 0000 0840
0002 0014 0140
0000 0000
0000 0000 0000
0000 0000 0840
0000 0000 0840
0000 0000 0840
0000 0000 0840
0000 0000 0840
0000 0000 0840
0000 0000 0840
0000 0000 0840
0002 0014 0140
BTS CONF
STA
STA
DIS CONF
DIS CONF
STA
ENA ENA
DIS UNCONF
DIS UNCONF
DIS UNCONF
DIS UNCONF
DIS UNCONF
DIS UNCONF
DIS UNCONF
DIS UNCONF
DIS UNCONF
STA
ENA ENA
DIS UNCONF
DIS UNCONF
DIS UNCONF
DIS UNCONF
DIS UNCONF
DIS UNCONF
DIS UNCONF
DIS UNCONF
DIS UNCONF
END
Again if there are no alarms displayed on the RXASP command then we check
the sectors to see if the resources are available. In this case we can see the
sector is OOS and needs attention. Often times if a secondary DIP goes down,
the Cell Logic Availability alarm will present itself with no OML fault or other
alarms in Netcool or in the RXASP printout.
Slide 44
MO FLT= PERMANENT FAULT
CORRELATED LIKE: MO FLT= PERMANENT FAULT RXOTRX-32-9 RXOTRX-32-8
• Can Present in Netcool as Critical or Major
• Can come in on the CF, TRX, TX, or RX
• Arises on an MO when the MO has
attempted self-recovery from a transient
fault several times and has failed.
• May be related to a faulty T1.
Slide 45
Recommended Troubleshooting
Steps
1.
Log into the appropriate BSC to verify the alarm with the
RXOTG command.
<rxasp:mo=rxotg-32;
RADIO X-CEIVER ADMINISTRATION
MANAGED OBJECT ALARM SITUATIONS
MO
RXOTG-32
RXOTRX-32-8
RXOTRX-32-9
RSITE
TX0060
TX0060
TX0060
ALARM SITUATION
PERMANENT FAULT
PERMANENT FAULT
END
From the RXASP printout we can see that the permanent fault is on RXOTRX32-8 and 32-9. We can status the sector to confirm the ratios status if desired
with the RXMSP command. You can always attempt to restore the radio (or radio
function depending on the MO, TX, RX) by blocking the TRX, testing it, and then
unblocking it. This will give the radio another chance to load and restore. It may
restore for 10 or 15 minutes and then go back into fault. If this happens send
ticket to the field explaining that you have attempted unsuccessfully to restore it.
This is the case more often then not, and this will require either hardware
replacement or a hard reset at the site. We will now go over the procedure to
restore the TRX.
NOTE: If the permanent faults are accompanied by OML faults in this printout,
investigate the issue as a bad T1.
Slide 46
2. Block the TRX and subordinate
devices.
<rxbli:mo=rxotrx-32-8,subord;
RXBLI:MO=RXOTRX-32-8,SUBORD;
<;
RADIO X-CEIVER ADMINISTRATION
MANUAL BLOCKING OF MANAGED OBJECT COMMAND RESULT
MO
STATE RESULT
RXOTX-32-8
COM EXECUTED
RXOTS-32-8-0
COM EXECUTED
RXOTS-32-8-1
COM EXECUTED
RXOTS-32-8-2
COM EXECUTED
RXOTS-32-8-3
COM EXECUTED
RXOTS-32-8-4
COM EXECUTED
RXOTS-32-8-5
COM EXECUTED
RXOTS-32-8-6
COM EXECUTED
RXOTS-32-8-7
COM EXECUTED
RXORX-32-8
COM EXECUTED
RXOTRX-32-8
COM EXECUTED
END
To try and attempt to restore the TRX you must first block it down along with all
its subordinate devices. Use the RXBLI:MO=RXOTRX-32-8,SUBORD: command
to accomplish this. The Subord on the end of the command is to make sure that
all devices within the TRX are down. When you run this command you will notice
that the switch capitalize the command before any other output is given. It is
asking you to confirm your request to block. You will need to enter a ; and then
return to confirm. Then it will give you the printout you see here confirming that
the TRX is blocked. The next step is to test the TRX with the RXTEI command.
Slide 47
3. Test the TRX with the RXTEI
command.
<rxtei:mo=rxotrx-32-8;
RADIO X-CEIVER ADMINISTRATION
TEST OF MANAGED OBJECT COMMAND RESULT
MO
RXOTRX-32-8
RESULT
ORDERED
END
Run the RXTEI command to test the TRX. This will usually take a minute or 2 to
run and then it will give you the results. Either a pass or fail.
Slide 48
3. Test the TRX with the RXTEI
command. Cont.
RADIO X-CEIVER ADMINISTRATION
TEST OF MANAGED OBJECT RESULT
MO
RXOTRX-32-8
RESULT
LOADING FAILED
BTSSWVER
ERA-G04-R08-V01
END
RADIO X-CEIVER ADMINISTRATION
TEST OF MANAGED OBJECT RESULT
MO
RXOTRX-32-8
RESULT
TEST WAS PERFORMED
BTSSWVER
ERA-G04-R08-V01
NO FAULT INDICATIONS
END
When the test is complete it will printout one of these 2 responses. From these
we can see the pass or fail indications. If it returns as failed the next step would
be to create a CTS ticket with the RXASP, and test result printouts and send it to
the field. If it comes back passed then wait a couple of minutes and status the
sector with the RXMSP command and status the TG with the RXASP command
to insure that the sector has restored.
It is important to note at this point that the alarm in Netcool may clear after
blocking and unblocking even though the problem has not gone away. Also, If the
test passes and the sector clears there is a good chance that the alarm and the
alarm condition will return in 15 or 20 minutes. In that case create a ticket and
send it to the field with the printouts and all troubleshooting steps taken.
Slide 49
EXTERNAL ALARMS; see
Additional Info
EXTERNAL ALARMS; see Additional Info RECTIFIER 24V+ MINOR;RECT -48V MINO
• Can present in Netcool as Critical or Major.
• Can cover a wide range of situations many of
which don’t affect performance.
• In general, these faults are not remoterepairable and will just need to be ticketed.
• Alarm fault information will be in the
―Additional Information‖
Typically, these are just ―Rip and Ship‖ alarms. They are usually on equipment
either outside of the cabinet (I.E. Generators, Tower lights and amps, antenna,
ect…) or separate from the BTS equipment (rectifiers, fuse panels, door alarms,
ect..) They can be viewed in a printout with the ALLIP:ACL=EXT; command.
NOTE: Although not considered External faults. Any temperature alarm, High
Temp or Low Temp alarms can be treated much the same way. Since there is
nothing we can do remotely for them, they will just need to be ticketed and sent
straight out to the field. They can also be viewed in the ALLIP printouts.
Slide 50
Recommended Troubleshooting
Steps
Connec ting to SDCAB08... (Use 'quit' to logoff)
<allip:alcat=ext;
ALARM LIST
A2/EXT "SDCAB08_L000403" 323 071212 1412
RADIO X-CEIVER ADMINISTRATION
BTS EXTERNAL F AULT
MO
RXOCF-78
RSIT E
SD 0366
CLASS
2
EXTERNAL ALARM
RECTIFIER 24V+ MINOR
RECT -48V MINOR
A2/EXT "SDCAB08_L000403" 350 071212 1619
RADIO X-CEIVER ADMINISTRATION
BTS EXTERNAL F AULT
MO
RXOCF-68
RSIT E
SD 0339
CLASS
2
EXTERNAL ALARM
RECTIFIER 24V+ MINOR
END
Run the ALLIP:ALCAT=EXT; command to view the all external alarms in the
BSC. You will have to scroll through and find the site for which the Netcool alarm
has been generated for. Since we already know the fault from the additional
information in Netcool we can match it in the alarm printout. Since the these
alarms can not be fixed or restored remotely, you would now need to create a
CTS ticket, paste the allip information in the ticket and send it to the field tech. If
the alarm is not present in the external alarm list, these alarms can also be view
in the A2 or major alarm list by running the ALLIP:ACL=A2; as well. This will just
give you all the major alarms on the BSC and will probably be a much longer list.
Slide 51
PWR COMMERCIAL;RECT 24V
MAINS;BATTERY
CORRELATED LIKE: MO FLT= MAINS FA ILURE 2 alarms: RXOCF-181 RXOCF-180
• Can present as Critical or Major in Netcool
• Can have several different text formats in
Netcool
• May present as Internal or external fault in
Netcool
• Indicates a loss of commercial power to
the site
Slide 52
Recommended Troubleshooting
Steps
1. Run the RXASP:MO=RXOTG-181&-180;
<rxasp:mo=rxotg-181&-180;
RADIO X-CEIVER ADMINISTRATION
MANAGED OBJECT ALARM SITUATIONS
MO
RXOTG-181
RXOCF-181
RXOTG-180
RXOCF-180
RSITE
LA3109
LA3109
LA3109
LA3109
ALARM SITUATION
MAINS FAILURE
MAINS FAILURE
END
With Mains Fail or commercial power alarms there is no remote action to recover
from this. These will require a CTS ticket to be dispatched to the field. Typically,
this is done after waiting about 20 minutes from the alarm presentation time. The
waiting period is to insure that the power does not come back shortly after the
alarm presents itself. This is common in regions that are experiencing extreme
weather events. The alarm printout can be viewed by running the RXASP
command on the affected CF as shown in this slide. Paste this printout in the
CTS ticket to send to the field tech.
Slide 53
2. Check the ALLIP Printout
A2/APT "ANCAB11_L000403" 719 071201 1203
RADIO X-CEIVER AD MINISTRATION
MAN AGED OBJECT FAULT
MO
RXOCF-181
RSITE
AL AR M SLOGAN
LA3109
MAINS FAILURE
A2/APT "ANCAB11_L000403" 720 071201 1204
RADIO X-CEIVER AD MINISTRATION
MAN AGED OBJECT FAULT
MO
RXOCF-180
RSITE
AL AR M SLOGAN
LA3109
MAINS FAILURE
END
It is possible that the alarm condition may not present itself in the RXASP
command. This is especially true with alarms that have ― Commercial Power
Failure‖ in the text. In this case you may need to view the ALLIP printout. They
can be in the ALLIP:ALCAT=POWER; or =EXT; or ACL=A1; or A2 depending on
the configuration.
Slide 54
Summary: CORRELATED LIKE:
MO FLT= TS SYNC FAULT
• Single or multiple Timeslots to one or
several TRX’s are OOS
• Often can be a side affect of a down or
faulty T1
• Can be caused by congestion
• Can be restored individually if it is not a T1
issue
Slide 55
Recommended Troubleshooting
Steps
1.
Retrieve alarm printout from parent RXOTG to determine
which RXOTS MO(s) are affected
<rxasp:mo=rxotg-25;
RADIO X-CEIVER ADMINISTRATION
MANAGED OBJECT ALARM SITUATIONS
MO
RXOTG-25
RXOTS-25-3-2
RSITE
LAC312
LAC312
ALARM SITUATION
TS SYNC FAULT
END
RXOTS (Timeslots) can generate TS SYNC FAULT alarms when the span takes
slips, or the path between the transcoder and the TRX is disturbed (ie congestion
in subrate switch). Generally, the RXOTS MO’s will show OPER, but the
corresponding TCH’s will show BLOC. To clear the TS faults, you must block,
loop test, and deblock the affected RXOTS MO(s). It is also helpful to check the
DIP for errors to resolve the origin of the problem.
Here we see that RXOTS-25-3-2 has faulted
If the RXOIS is in alarm PERMANENT FAULT, proceed directly to document
―RXOIS: PERMANENT FAULT‖. A faulty RXOIS can cause RXOTS problems.
In general, if a site only has 2 or 3 TS in fault, you should be able to clear them.
If all the TS under a TRX are down or multiple (more than 7) are down on the
site, additional troubleshooting will be required.
Slide 56
2. Block the affected RXOTS
MO(s
<rxbli:mo=rxots-25-3-2;
RXB LI:MO= RXOTS -25-3-2;
<;
RADIO X-CE IVER ADMINIS TRA TION
MANUA L BLOCKING OF MA NAGE D OBJE CT COMMAND RES ULT
MO
STA TE RESULT
RXOTS-25-3-2
COM
EXECUTE D
You must block the affected timeslots prior to testing them.
Slide 57
3. Test the affected RXOTS MO
<rxtei:mo=rxots-25-3-2;
RADIO X-CEIVER ADMINISTRATION
TEST OF MANAGED OBJECT COMMAND RESULT
MO
RXOTS-25-3-2
RESULT
ORDERED
END
<
COMMAND SESSION SUSPENDED
RADIO X-CEIVER ADMINISTRATION
TEST OF MANAGED OBJECT RESULT
MO
RXOTS-25-3-2
RESULT
TEST WAS PERFORMED
BTSSWVER
ERA-G04-R08-V01
NO FAULT INDICATIONS
END
Test the affected RXOTS MO with the RXTEI command. After a few seconds, a
result printout should appear with ―NO FAULT INDICATIONS‖ as seen here
Slide 58
4. Run a Loop-Test on the affected
RXOTS MO
RECONN E XE CUTED
<rxlti:mo=rxots-25-3-2;
RADIO X-CE IVER ADMINIS TRA TION
TRC-B TS LOOP TES T RESULT
MO
RXOTS-25-3-2
TRADEV
RTTGD-195
RESULT
TEST SUCCESSFUL
TRCA TERDEV
BSCATERDEV
ABISDEV
RBLT3-616
END
Run a Loop-Test on the affected RXOTS MO ). This tests continuity between the
transcoder and the TRX/TS. The Result should be ―TEST SUCCESSFUL‖. Then
unblock the TS and check it for a status. If the result comes back loop test failed,
try the test one more time. Sometimes it will still come back. If it fails out again.
Unblock the TS and then cut a ticket to the field for a possible hardware hard
reset or replacement.
Slide 59
5. Unblock the affected RXOTS
<rxble:mo=rxots-25-3-2;
RXB LE:MO=RXOTS -25-3-2;
<;
RADIO X-CE IVER ADMINIS TRA TION
MANUA L DEBLOCK ING OF MANA GED OB JECT COMMA ND RESULT
MO
STA TE RESULT
RXOTS-25-3-2
PREOP ORDERE D
<rxble:mo=rxots-25-3-2;
RADIO X-CE IVER ADMINIS TRA TION
MANUA L DEBLOCK ING OF MANA GED OB JECT COMMA ND RESULT
MO
RXOTS-25-3-2
STA TE RESULT
PREOP EXECUITE D
Unblock the affect TS. It will show ORDERED, then after a few seconds,
EXECUTED
Slide 60
6. Status the affected RXOTS
<rxmsp:mo=rxots-25-3-2;
RADIO X-CE IVER ADMINIS TRA TION
MANAGE D OBJE CT S TA TUS
MO
RXOTS-25-3-2
STATE BLS TA TE
OPER
BLO BLA LMO BTS CONF
0000 0000 0000 ENA ENA
Wait a few seconds after unblocking so the TS can reset and then status the TS.
It should read operational. If the TS does not come back after a few attemps to
status it and all the DIPs on the CF are clean. Create a TT and send it to the field
with all of your troubleshooting steps and printouts and send it to the field.
Slide 61
CELL LOGICAL CHANNELS SEIZURE
SUPERVISION
CELL LOGICAL CHANNELS SEIZURE SUPERVISION
• BSC threshold alarm for busy or blocked
traffic channels
• Can be due to site outages, congestion,
hardware failure
• Will need to be cleared manually
• Does not require a CTS ticket
A threshold alarm from the BSC triggered when a certain number of traffic
channels are continuously busy or unavailable. These are usually due to
secondary faults or conditions at the equipment or site they are originating from.
T1 failure, radio issues, ect… These are not alarm conditions within the BSC,
rather they are just informational alarms telling a certain number of traffic
channels are down. There is no remote troubleshooting remedy for this condition.
The condition can be cleared manually by clearing the traffic channel alarm data
in the BSC.
Slide 62
Recommended Troubleshooting
Steps
1. Retrieve the traffic channel seizure
information.
<rlvap;
CELL SEIZURE SUPERVISION OF LOGICAL CHANNELS
ALARMED OBJECTS DATA
CONTINUOUSLY BUSY CHANNELS
CHANNEL
CELL
STATE
TCH-58855
SF0323Z BLOC
TCH-58856
SF0323Z BLOC
END
Use the RLVAP; command to view the counter for the traffic channels in alarm.
From the printout we can see which site and sector they belong to. In this case
SF0323Z. Again these are usually from a secondary condition which has most
likely alarmed at the cell site and equipment level. The next step is to clear the
channel data from the counter.
Slide 63
2. Clear the Channel Data
<rlvar:chtype=tch;
RLVAR: CHTYPE= TCH;
<;
E XECUTE D
<rlvap;
CELL SE IZURE SUPE RVIS ION OF LOGICA L CHANNELS ALA RMED
OBJE CTS DA TA
CONTINUOUSLY BUSY CHA NNE LS
CHA NNEL
CELL
STATE
NONE
END
<
To clear the alarm you must clear the counters for the channels. Use the
RLVAP:CHTYPE=TCH; command. You can check you work if you like by running
the RLVAP command again to see if the counters have cleared as shown here.
The alarm should clear from Netcool after a few minutes.
Slide 64
CP AP COMMUNICATION FAULT
CP AP COMMUNIC ATION FAULT
• AP/CP can occur for a wide range of issues
• Can present in Netcool as Critical or Major
• Can sometimes require reporting to Outage
Management for a SIR
• Should always be ticketed after verification
AP/CP faults can come in for a wide range of issues as both critical and major.
The can be verified by running the ALLIP for both A1 and A2. The severity of
these alarms is not always represented well by netcool meaning just because it
presents as a major in netcool it still may be a critical issue. CP issue tend to be
more critical and less common then AP faults.
Slide 65
Recommended Troubleshooting
Steps
1. Verify the alarm using ALLIP on A1 and A2
<allip:ac l=a1;
ALARM LIST
A1/APZ "DNCOB08_L000403" 395 071211 1215
AP PROCESS STOPPED
AP APNAME
1 DNCOB08
NODE
B
NODENAME
DNCOB08APGB
RESOURCE GROUP
PROCESS
LBB
clusSvc
CAUSE
DATE TIME
Process death
20071211 102325
A1/APZ "DNCOB08_L000403" 396 071211 1215
AP SYSTEM ANALYSIS
AP APNAME
1 DNCOB08
NODE
B
OBJECT
COUNTER
Logic alDisk % Free Space
NODENAME
DNCOB08APGB
INSTANCE
C:
LIMIT
<6
VALUE
2.45
A1/APZ "DNCOB08_L000403" 397 071211 1218
AP PROCESS STOPPED
AP APNAME
1 DNCOB08
NODE NODENAME
B
DNCOB08APGB
RESOURCE GROUP
PROCESS
LBB
ACS_PRC_ClusterControl
CAUSE
DATE TIME
Process death
20071211 121850
END
From the ALLIP A1 we can see that the AP process has stopped. This will
require an immediate ticket to the Switch and a call as well. Also, report to the
Outage management team. If the AP or CP have gone single sided, as in this
case, they will need to send a SIR notification for lack of redundancy. Also, check
the ALLIP A2 printout as some of the alarms will only present as majors even
though they are critical.
Slide 66
2. Check ALLIP A2
A2/APZ "DNCOB08_L000403" 859 071213 1105
CP AP COMMUNICATION FAULT
FAULT
NETWORK FAULT
DEV
DEVIP
NETWORKIP
REMOTEIP
OCITS-1 192.168.170.128 192.168.170.0 192.168.170.2
RP
0
EM
0
RPTYPE
TYPE
A2/APZ "DNCOB08_L000403" 860 071213 1105
CP AP COMMUNICATION FAULT
FAULT
NETWORK FAULT
DEV
DEVIP
NETWORKIP
REMOTEIP
OCITS-0 192.168.169.128 192.168.169.0 192.168.169.2
RP
0
EM
0
RPTYPE
TYPE
A2/APZ "DNCOB08_L000403" 878 071213 1114
AP NOT REDUNDANT
AP APNAME
1 DNCOB08
NODE
A
NODENAME
DNCOB08APGA
NODE NOT AVAILABLE
DNCOB08APGB
CAUSE
DATE TIME
Node is down
20071213 111438
END
From here we can see that CP AP communications are down, the AP is not
redundant and is down. Paste these in the ticket along with the A1 printout to
send to the switch.
It is important to note that not all AP alarms are not this serious. Most are majors
with process errors or faults that can just be sent to the switch without callout.
However, anytime you lose redundancy with either the AP or CP, a callout will
need to be made and the Outage Management team advised.
Slide 67
MO FLT= LOOP TEST FAILED
MO FLT= LOOP TEST FAILED
• Occurs when a manual or automatic loop
test has been performed while the DIP
takes errors, or the path between the
transcoder and the TRX is disturbed
• Presents in Netcool as a Major
• Can sometimes be restored If it is not a
DIP issue
Slide 68
Recommended Troubleshooting
Steps
1. Retrieve alarm printout from parent RXOTG
<RXASP:MO= RXOTG-63;
RADIO X-CE IVER ADMINIS TRA TION
MANAGE D OBJE CT ALARM SITUA TIONS
MO
RXOTG-63
RXOTS-63-0-0
RSITE
DLLS TXE 049
DLLS TXE049
ALARM SITUA TION
LOOP TES T FAILED
END
As we can see from the printout RXOST-63-0-0 is affected. If the RXOIS is in
alarm PERMANENT FAULT, proceed directly to document ―RXOIS:
PERMANENT FAULT‖. A faulty RXOIS can cause RXOTS problems. Also,
always check the DIP for errors since this is likely caused by a faulty DIP. If the
DIP shows errors create a ticket and treat this like a regular DIP issue.
If the DIPs are clean you can try to block the affected TS, run the TEI test, loop
test, and then unblock the TS like we did with the TSSYNC faults earlier,
Slide 69
2. Block the TS and test
RXBLI:MO=R XOT S-63-0-0;
RADIO X-CEIVER ADM INISTRAT ION
MANUAL BL OCKING OF M ANAG ED OBJECT COM MAND RESULT
MO
ST AT E RESULT
RXOTS-63-0-0 COM EXECUTED
END
<RXTEI:MO=RXOTS-63-0-0;
RADIO X-CEIVER ADM INISTRAT ION
TEST O F MAN AGED OBJ ECT CO MM AND RESULT
MO
RESULT
RXOTS-63-0-0 ORDER ED
END
<
RADIO X-CEIVER ADM INISTRAT ION
TEST O F MAN AGED OBJ ECT R ESULT
MO
RESULT
BTSSWVER
RXOTS-63-0-0 T EST WAS PERFORM ED
ER A-G03-R01-V01
NO FAULT IND ICAT IONS
END
<RXLTI:MO=R XOT S-63-0-0;
RADIO X-CEIVER ADM INISTRAT ION
TRC-BTS LOO P T EST R ESULT
MO
RESULT
RXOTS-63-0-0 T EST SUCC ESSFUL
TRADEV
TRC AT ERDEV
RTTF1D2-3341
END
BSCATERD EV ABISDEV
RBLT24-1519
Block the affected RXOTS MO(s). Test the affected RXOTS MO(s) (NOT
REQUIRED, BUT RECOMMENDED) After a few seconds, a result printout
should appear with ―NO FAULT INDICATIONS. Run a Loop-Test on the affected
RXOTS MO(s). This tests continuity between the transcoder and the TRX/TS.
The result should be ―TEST SUCCESSFUL‖. If RESULT = ―ABIS PATH
UNAVAILABLE‖, you may have a faulty DIP or the DIP resources have not been
assigned correctly. If RESULT = ―TEST PASSED‖, the fault may have just been
transient. Proceed with unblocking
Slide 70
3. Unblock the TS
RXBLE:MO=R XOTS-63-0-0;
RADIO X-CEIVER AD MINISTRATION
MANUAL DEBLOCKING OF MAN AGED OBJECT COMMAND RESULT
MO
RXOTS-63-0-0
STATE RESULT
PREOP ORDERED
END
< RADIO X-CEIVER ADMINISTR ATION
MANUAL DEBLOCKING OF MAN AGED OBJECT RESULT
MO
RXOTS-63-0-0
STATE RESULT
OPER EXECUTED
END
Unblock the affected RXOTS MO(s). It will show ORDERED, then after a few
seconds, EXECUTED if you are successful. Otherwise it will just return a NOOP
result. At that point you would have to create a ticket and send it to the field.
Slide 71
LOCAL MODE & OPERATOR CONDITION
CORRELATED LIKE: MO FLT= LOC AL MODE 1 alarms: RXOCF-2
CORRELATED LIKE: MO FLT= OPERATOR CONDITION 1 alarms: RXOCF-54
A2/APT "BDE C02E _D000100" 157 020805 0036
RADIO X-CE IVER ADMINIS TRA TION
MANAGE D OBJE CT FAULT
MO
RXOTRX-2-8
RSITE
DNVRCO1250
ALARM SLOGAN
LOCAL MODE
A2/APT "BSC02_E 000O0056" 827 020318 1232
RADIO X-CE IVER ADMINIS TRA TION
MANAGE D OBJE CT FAULT
MO
RXOCF-63
RSITE
DLLS TXL009
ALARM SLOGAN
OPERATOR CONDITION
The RXOCF is currently in a maintenance mode, normally set locally by a tech in
the site.
1) If a tech has reported for maintenance on the site or there is a ticket cut
against this device or other devices in the site, notate the alarm as LOCAL
MODE.
2) If no tech has called in and no relevant ticket exists against site, cut ticket and
note this information. There are times that devices go into local mode due to
problems.
). The RXOCF is currently reporting that the cabinet door is open, hopefully by a
tech at the site.
1) If a tech has reported for maintenance on the site or there is a ticket cut
against this device or other devices in the site, notate the alarm as OPERATOR
CONDITION.
2) If no tech has called in and no relevant ticket exists against site, cut a minor
ticket and note this information. There are times that the door alarm contacts fail,
or the weather may be affecting the door seal.
Note, the RXMFP printout on the RXOCF will show an External Fault 2B 9
(operator condition).
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