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Glossary (danh sch, cc t chuyn mn)
BSC Base Station ControllerCF Central Functions-nhim v chnh, chc
nng trung tmCON LAPD Concentrator-tp trungDP Digital PathIS
Interface SwitchMO Managed ObjectRX ReceiverTF Timing Function(chc
nng nh thi)TG Transceiver GroupTRXC Transceiver ControllerTS Time
Slot Handler-b iu khin khe thi gianTX Transmitter-my phtpooltraf
The number of transcoder resources currently used in traffic
per pool. DCP=dcp Digital connection point number-s im kt ni
sDCP1=dcp1 Digital Connection Point (DCP) number used for the
signalling path to the TRXCNumeral 0 - 511
DCP2=dcp2 DCP number used for the speech and data connections to
the TRXC
Two DCP2s, for TRXCs using 16 Kbps Abis paths, or eight DCP2s,
for TRXCs using 64 Kbps Abis paths, must be given. The DCP2s given
must be consecutive(lin tc). The DCP2s are sorted into ascending
order. If two DCP2s are given, the lower range DCP2 value is
associated(kt hp) with TSs 0 to 3, and the higher range DCP2 is
associated with TSs 4 to 7. If eight DCP2s are given, the lower
range DCP2 value is associated with TS 0 and the higher range DCP2
value is associated with TS 7.Numeral 0 - 511
SIG=sig Signalling type UNCONC UnconcentratedCONC LAPD
ConcentrationMPLEX16
-
16K MultiplexMPLEX32 32K Multiplex
TEI Terminal Endpoint Identifier(nhn dng)OML Operation and
Maintenance(bo dng) LinkRXD RECEIVER DIVERSITY- nhy thu
BCCH Broadcast Control Channel-knh iu khin qung b
DCHNO=dchno(TCH) Absolute radio frequency channel number(ng,chnh
xc) Maximum 32 Absolute Radio Frequency Channel Number (ARFCNs) per
channel group are allowed. (31 if channel group 0).Numeral 128 -
251 (GSM 800) Numeral 1 - 124 (GSM 900, P-band) Numeral 0, 975 -
1023 (GSM 900, G1-band) Numeral 512 - 810 (GSM 1900) Numeral 512 -
885 (GSM 1800)
HOP=hop Frequency hopping status OFF The hopping status for the
channel group is non-hopping. ON The hopping status for the channel
group is hopping for Traffic Channel (TCH) and Stand-alone
Dedicated Control Channel (SDCCH).
HSN=hsn Hopping sequence numberNumeral 0 - 63
CBCH=cbch Cell broadcast channel This parameter indicates if
Cell Broadcast Channel (CBCH) is included in the Stand Alone
Dedicated Control Channel (SDCCH).YES CBCH will be included in one
of the SDCCH/8 for a cell or a channel groupNO No SDCCH/8 for a
cell or a channel group will include CBCH
CELL=cell Cell designation
-
This is a symbolic name of a defined cell.CHGR=chgr Channel
group number
Numeral 0 - 15 SDCCH=sdcch Required number of SDCCH/8
Numeral 0 - 32 (with combined BCCH 31) TN=tn Timeslot number
Numeral 0 - 7 cgi Cell global identification- nhn dng ton
cu(khu
vc) Expressed as(biu din,trnh by) mcc-mnc-lac-ci where:mcc
Mobile country codemnc Mobile network codelac Location area codeci
Cell identity- nhn dng
BCCHNO=bcchno Absolute radio frequency channel number for
Broadcast Control Channel (BCCH) Absolute Radio Frequency Channel
Number (ARFCN) already defined for a dedicated channel cannot be
given.Numeral 128 - 251 (GSM 800) Numeral 1 - 124 (GSM 900, P-band)
Numeral 975 - 1023, 0 (GSM 900, G1-band) Numeral 512 - 885 (GSM
1800) Numeral 512 - 810 (GSM 1900)
BCCHTYPE=bcchtype BCCH type This parameter indicates the
combinatons of wanted logical channels on the frequency and
timeslot defined for the BCCH in the cell.COMB Combined control
channelIndicates that the cell has a combined BCCH and Stand Alone
Dedicated Control Channel (SDCCH)/4.COMBC Combined control channel
with a Cell Broadcast Channel (CBCH) subchannel
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Indicates that the cell has a combined BCCH and SDCCH/4 with a
CBCH subchannel.NCOMB Non-combined control channelIndicates that
the cell does not have any type of combined BCCH and SDCCH/4.This
parameter applies only to internal cells
RLCRP:CELL= 64k 64kbit/s Mode Supported CS3CS4 The Basic
Physical Channel (BPC) supports General Packet Radio Service (GPRS)
CS-3 or CS-4
EGPRS The BPC supports Enhanced(lm tng, nng cao) General Packet
Radio Service (EGPRS)
NONE The BPC does not support EGPRS or GPRS CS-3 or CS-4
bcch Broadcast Control Channels (BCCHs) This parameter indicates
the number of deblocked BCCHs in the cell.
bpc Basic Physical Channel individual
This individual is also printed in the RADIO X-CEIVER
ADMINISTRATION MANAGED OBJECT CONFIGURATION DATA printout, thus
linking the configured logical channels with the Base Transceiver
Station (BTS) equipment used for them.
cbch Cell Broadcast Channels (CBCHs) This parameter indicates
the number of deblocked CBCHs in the cell.
cell Cell designation This is a symbolic name of a defined
cell.
channel Logical channel identity
This parameter consists of the channel type and an individual
number.
chband Channel band This parameter indicates the frequency band
for the logical channel.The channel band is printed for deblocked
channels.800
GSM 800The BPC holding the channel is configured on one or
several Absolute Radio Frequency Numbers (ARFCN) within the GSM 800
band in the range 128 - 251.
1800 GSM 1800
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The BPC holding the channel is configured on one or several
ARFCNs within the GSM 1800 band in the range 512- 885.
1900 GSM 1900The BPC holding the channel is configured on one or
several ARFCNs within the GSM 1900 band in the range 512- 810.
P900 Primary GSM 900The BPC holding the channel is configured on
one or several ARFCNs exclusively within the primary GSM 900 band
in the range 1 - 124.
E900 Extended GSM 900The BPC holding the channel is configured
on at least one ARFCN in the extended 'G1' GSM 900 band in the
range 0, 975 - 1023.
chgr Channel group numberchrate Channel rate
FR Full rate
HR Half rate
chtype Channel type BCCH
Broadcast Control ChannelCBCH
Cell Broadcast ChannelSDCCH
Stand Alone Dedicated Control ChannelTCH
Traffic Channelicmband Current idle channel interference
band
The interference is measured on an idle channel and the value
range,from negativeto positive infinity (dBm), is divided into 5
intervals which are called idle channel interference bands.
Interference band 1 is the band with the lowest interference.
Interference band 5 is the band with the highest interference. An
idle or busy SDCCH or TCH belongs to one of the idle channel
interference bands.
Numeral 1 - 5noofch Number of deblocked logical channels
A logical channel in state idle, busy or locked is regarded as a
deblocked channel.
nooftch Number of traffic channels This number can have a lower
and an upper limit. This is because there are BPCs configured with
the possibility to be
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allocated either as full rate traffic channels (then counted as
one channel) or half rate traffic channels (then counted as two
channels). These channels are called dual rate channels. In a
channel group or a cell, dual rate channels can be mixed with those
of a fixed channel rate.
sdcch Stand Alone Dedicated Control Channel (SDCCH) This
parameter indicates the number of deblocked SDCCHs in the cell.
spv Speech version If a traffic channel is configured with the
possibility to be allocated for either of several speech versions,
this parameter shows all the possible speech versions (for example
spv = 1,2).
state Logical channel state BLOC
BlockedBUSY
BusyIDLE
IdleLOCK
LockedIf a BPC is configured with the possibility to be
allocated either as a full rate traffic channel or two half rate
traffic channels, the channel state LOCK is applicable. When one
channel rate is allocated to a BPC, the logical channel or channels
of the other rate on the same BPC are locked.
NONE No data existed to be printed.
EOT DURING PRINTOUT The operator has cancelled the printout.
FAULT INTERRUPTfault type
A fault interruption occurred during printing.
Fault type:
FORMAT ERRORThe command was incorrectly specified.
UNREASONABLE VALUE
details A parameter was specified with an unreasonable
value.
FAULT CODE 3CELL NOT DEFINEDdetails
-
The cell is not defined. FAULT CODE 19CELL RESOURCES HAVE
CHANGED
Cell Resources have changed since printout started. FAULT CODE
27CELL DATA CHANGE IN PROGRESS
Modification of cell data by a command is in progress.
FAULT CODE 38COMMAND NOT VALID FOR EXTERNAL CELLSdetails
The command is not valid for external cells. FAULT CODE 120CELL
STATE NOT ACTIVEdetails
The cell has not been activated.
BA-list BCCH Allocation list
1.rxtcp:cell=hni,moty=rxotg; xem TG ca trm Parameters: thng s,
tham s, tham bit, gii hn Associated: kt hp, lin kt dedicated to: c
tnh cht chuyn mn represented by: trnh by bi, biu din bi
2.dtdii:dip=,snt=,dipp=; Initiate: bt u, khi u, xng Sequence:
trnh t, kt ni
3.ntcop:snt=all; xem lung tha hay thiu
SNT=snt Switching network terminal
DIPINF Digital path information related to the Switching Network
Terminal (SNT)
ALL All switching network terminals
SNTP=sntp Switching network terminal connection point
4.rlcrp:cell=hni; lnh kim tra thu bao chim knh - CBCH: Cell
Broadcast Channel-knh qung b- NOOFTCH: Number of traffic
channels
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This number can have a lower and an upper limit. This is because
there are BPCs configured with the possibility to be(c kh nng,c th)
allocated(phn phi,cp pht,nh r v tr) either as(chn 1 trong hai vn )
full rate traffic channels (then counted as one channel) or half
rate traffic channels (then counted as two channels). These
channels are called dual(hai, i) rate channels. In a channel group
or a cell, dual rate channels can be mixed(ln ln,pha trn,hn hp)
withthose of a fixed(ng yn,c nh) channel rate.
icmband Current idle channel interference band The interference
is measured on an idle channel and the value range,from negativeto
positive infinity (dBm), is divided into 5 intervals which are
called idle channel interference bands. Interference band 1 is the
band with the lowest interference. Interference band 5 is the band
with the highest interference. An idle or busy SDCCH or TCH belongs
to one of the idle channel interference bands.
BPC Basic Physical Channel
5.rxcdp:mo=rxotg-tg; xem cu hnh ca trm - arfcn:Absolute Radio
Frequency Channel Number: s knh tn s radio chun-txad:TX logical
address. Numeric value in the range 0 to 31
C0f Carrier zero filling(lm y,ph y) YES
Carrier zero filling is turned on.NO
Carrier zero filling is turned off.
6. rxmfp:mo=rxots-TG-TRX-TS 0&&-TS7; xem s cuc gi trn
ts.
conerrcnt Counter for the number of abnormally(khc thng)
terminated connections
concnt Counter for the number of connection setup attempts(c
gng
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lm g)
7. H cu hnh:-dtstp:dip=m trm;(xem trm nm BSC
no)-rxtcp:moty=rxotg,cell=m trm1;(xem TG)
(rxmfp:mo=rxotg-TG;)-rxmsp:mo=rxotg-TG,subord;(xem cu hnh ca trm)
-rxbli:mo=rxotrx-TG-TRX,subord,force;;(lnh blok
TRX)-rxese:mo=rxotrx-TG-TRX,subord;;(lnh xa TRX)
rxmoe:mo=RXOTX-125-6 ; rxmoe:mo=RXOTS-125-6-0 ;
rxmoe:mo=RXOTS-125-6-1 ; rxmoe:mo=RXOTS-125-6-2 ;
rxmoe:mo=RXOTS-125-6-3 ; rxmoe:mo=RXOTS-125-6-4 ;
rxmoe:mo=RXOTS-125-6-5 ; rxmoe:mo=RXOTS-125-6-6 ;
rxmoe:mo=RXOTS-125-6-7 ; rxmoe:mo=RXORX-125-6 ;
rxmoe:mo=RXOTRX-125-6 ;
(rxcdp:mo=rxotg-TG;) +execute: thc hin,thc hin ch dn ca my
tnh,hnh hnh, hnh quyt. -rxmsp:mo=rxotg-TG,subord;(xem cu hnh ca
trm) FORCE Forced blocking indication(s ch dn)SUBORD Subordinate
MOs (di quyn)
All of the MO instances subordinate to the specified MO are
included. Parameter SUBORD may be used for a Transceiver Group (TG)
or Transceiver Controller (TRXC) in Base Transceiver Station (BTS)
logical model G01 and TG, Central Function (CF) or TRXC in the BTS
logical model G12.
8.Tch hp trm:-rlcfp:cell=m trm;(xem SDCCH,nhy tn)-rldep:cell= m
trm;(xem CGI)-dtqup:dip= m trm;(lnh xem h s trt ca
bit)-rxmop:mo=rxotg-tg;(ly version)Khai mi:-ntcop:snt=etm...;
-
-dtdii:dip=m trm,snt=emt...,dipp=...;;-dtbli:dip=m
trm;;-dtble:dip=m trm;;-dtstp:dip=m trm;(xem lung c hay cha)Xe m ta
lung ti BSC: -dtdip:dip=ten tram;
i tn dip (khi khai lung nhng b nhm v khi c dip) -dtpnc:dip=m trm
mi,newdip=...,-dtble:dip=m trm;-dtstp:dip=m trm; Xa
dip:-dtbli:dip=m trm;;-dtdie:dip=m trm;;Khai inner( bn trong, ni b
) cell:
----- Khai bao cell tren MSC-----mgcei:cell=M trm1,CGI=
mcc-mnc-lac-ci1,BSC=BHNI;mgcei:cell=M trm2,CGI=
mcc-mnc-lac-ci2,BSC=BHNI;mgcei:cell=M trm3,CGI=
mcc-mnc-lac-ci3,BSC=BHNI;
a, ParametersBSC=bsc Base Station Controller (BSC) name
The BSC to which the cell is connected.
See Application Information for block MTRAN.CELL=cell Cell
name
See Application Information for block MTRAN.CGI=cgi Cell Global
Identity (CGI)
See Application Information for block MBSSD.
b, Function
This command initiates a new mobile telephony cell in the Mobile
Services Switching Centre and Visitor Location Register (MSC/VLR)
Server. The new cell is connected to a Base Station Controller.When
the first cell is defined in location area, it defines the location
area as well.The order remains after system restart.
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Ch : mgcep:cell=m trm bt k no 1;(lnh in ra)Ch : lnh xa CGI trn
MSC : phi print cc cell ny trn BSC xem cell ny cn tn ti khng sau mi
thc hin cng vic xo:
mgcee:cell=m trm cell1;mgcee:cell=m trm cell2;mgcee:cell=m trm
cell3;
Khai GPRS:rlgsi:cell=m trm...;(khai c 3 cell) Khai outer( bn
ngoi ) cell(nu cdd yu cu gia cc MSC):
mgoci:cell=HTY3156,cgi=452-04-12121-21926,msc=MHN2;
Cc li c th trong CG:Khai bao INTERNAL:+ BSIC: phi l hai ch s(v
d: 8=08)Khai bao TCH cho cell(xem tht
k)+rlcfi:cell=NDH3064,CHGR=1,DCHNO=768&771&774&777&780&783&786&789&792&795&798&801&804&807;+rlcfi:cell=NDH3065,CHGR=1,DCHNO=769&772&775&778&781&784&787&790&793&796&799&802&805&808;+rlcfi:cell=NDH3066,CHGR=1,DCHNO=770&773&776&779&782&785&788&791&794&797&800&803&806&809;
+relation.Thong tin tram moi:Xem version(thay i version):+
RXMOI:MO=RXOTG-tg,TRACO=POOL,COMB=HYB,RSITE=m
trm,SWVER=B4402R011L;Xem m cell:+ RXMOC:MO=RXOTRX-tg-trx0, CELL=m
trm...;(i vi trm 1800 s cell c nh l cell4,cell5,cell6).CH :Khai bao
POWERCONTROL(ch phin bn phn mm)Khai bao Power UL(ch phin bn phn
mm)Khi to dev:
BLODI:DEV=RBLT;
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(Lnh ny c s dng deblock device s chuyn t trng Idle thi thnh trng
thi ABL(Automatic Block))
EXDAE:DEV=RBLT;(Lnh ny c s dng a cc Time Slot (tng ng thut ng
Device) chuyn t trng thi In Service thnh trng thi pre-post
service)
EXDAI:DEV=RBLT;(Lnh ny c s dng a cc Time Slot (tng ng thut ng
Device) chuyn t trng thi pre-post
service thnh trng thi In Service)
BLODE:DEV=RBLT;(Lnh ny c s dng deblock device s chuyn t trng thi
ABL(Automatic Block) thnh trng thi Idle)
Chy lnh v Dng li kim tra:+ Khi to Abis:
RXAPI:MO=RXOTG-tg,DEV=RBLT2-513&&-543,DCP=1&&31;(Lnh
ny c s dng nh ngha mt hoc nhiu Abis paths gia mt BSC v mt BTS. RBLT
l device (TS) kt ni t BSC ti BTS.
DCP l s nhn dng device .) + Lnh active cell.+ a cc MO sang trng
thi In- Service RXESI:MO=RXOTG-28,SUBORD;(ch full cnh bo v)Lnh ny c
s dng a MO (bao gm TG, CF, CON, TF, TRX, TX, RX, TS) vo dch v. C ti
32 MO c th nh ngha trong mt lnh. Nh s dng thng s SUBORD m ta ch dng
1 lnh m c th tc ng n tt c cc MO con ca TG-nh v d trn.+ Deblock cc
MO: RXBLE:MO=RXOTG-28,SUBORD;Lnh ny c s dng deblock MO.RLSTC:
CELL=HNIPDL1,STATE=ACTIVE;RLSTC: CELL=HNIPDL2,STATE=ACTIVE;RLSTC:
CELL=HNIPDL3,STATE=ACTIVE;Lnh ny c s dng thay i trng thi ca Cell
hoc CHGR. C cc trng thi l ACTIVE hoc HALTED.C h : nu TCH HP b hin
tng local mode c th do cc nguyn nhn sau: -khai sai TEI(c th do c
BSC v BTS) -trong lc tch hp mt kt ni hoc do DXU c vn
-
-cha active dch v(EXDAI, BLODE, RXAPI) -do di trm BTS cha chuyn
sang ch remove+ , nu do BSC sai do khai TEI th cch cha li nh sau:
-rxbli:mo=rxotg-tg,subord,force; -rxese:mo=rxotg-tg,subord;
-rxmoc:mo=rxotg-tg,tei=62(thm nu i sang Con hoc Uncon);
-rxesi:mo=rxotg-tg,subord; -rxble:mo=rxotg-tg,subord; 9.T hay i
tham s handover: -RLIHC:CELL=cell,iho=;-RLIHC:CELL=cell,
SSOFFSETULP=gi tr dng, SSOFFSETULN=ga tr m, QOFFSETULP=gi tr dng,
QOFFSETULN=ga tr m, SSOFFSETDLP= ga tr dng, SSOFFSETDLP= ga tr m,
MAXIHO=, TMAXIHO=, TIHO=,-RLLUC:CELL=cell, QLIMUL=;
10.Thay i lac:-RLSTC:CELL=,STATE=HALTED;-rldep:cell=,cgi=
mcc-mnc-lac-ci;-rldec:cell=,cgi=
mcc-mnc-lac-ci;-rlsbc:cell=,t3212=;mcc
Mobile country code Numeral 3 digits
mnc Mobile network code For the number of digits see the
Application Information for block ROEPC.
lac Location area codeNumeral 1 - 65535
ci Cell identityNumeral 0 - 65535
CH :-Xem s lng thu bao(mgsvp;) MSC trc v sau khi thay i LAC(ghi
li gi-s thu bao)-phi gim T3212 theo yu cu ca CDD trc khi thay-Nu
khng c LAI MSC khi thay i LAC th dng lnh khai: MGLAI:LAI=--;-khai
inner cell v outer theo yu cu ca CDD (mgbsp:bsc=all; xem tn
BSC)-(mgnmp:msc=all; xem tn MSC)
-
11. Thay i con-uncon: khi nng cp ri( khng cn thit ) Nu l dng
con:
-rxmop:mo=rxocon-tg;(xem
con)-rxmoc:mo=rxocon-tg,dcp=64&&87;(dng cho
con)-rxesi:mo=rxocon-tg;(xa)-rxble:mo=rxocon-tg;(to li con)
12. Lnh reset trm:-rxbli:mo=rxotg-tg,subord,force;(bloking-ngt
i)-rxble:mo=rxotg-tg,subord;(deblok-to li)
Lnh reset cell:-rxbli:mo=rxotrx-TG-TRX,subord,force;;(lnh blok
TRX)-rxble:mo=rxotrx-TG-TRX,subord;;(deblok-to li TRX)
13. dtbli:dip=m trm;
/ \|dip...|
DTBLI:DIP=+ +;|ALL|\ /
a , Parameters DIP=dip Digital path name Identifier(nhn ra, nhn
dng) 1 - 7 characters
ALL All digital paths
b, Function
The command initiates(bt u) blocking of the specified digital
path.The order(cp, bc, loi, hng) remains after system restart.
14. Lnh deblock dip:
/ \|dip...|
-
DTBLE:DIP=+ +;|ALL |\ /
a, Parameters
DIP=dip Digital Path (DIP) nameIdentifier 1 - 7 characters ALL
All DIPs See the Application Information for block DIPST.
b, FunctionThis command deblocks the specified DIPs.The order
remains after system restart.
15. Lnh kim tra card(hoc
reset):-exemp:rp=all,em=all;-dirrp:rp=all;-blrpi:rp=RP,forced;(block)-blrpe:rp=RP;(deblock)
16. Lnh khng a vo dch v:
a, Command / \ |MO=mo... |RXESE:+ +; |MO=mo[,SUBORD]| \ /
b, ParametersMO=mo Managed Object (MO) instance
See Application Information for block RXCTA for the format and
the value range of this parameter. All MO classes are valid.
SUBORD Subordinate MOs
All of the MO instances subordinate to the specified MO are
included. Parameter SUBORD may be used for a Transceiver
-
Group (TG) or Transceiver Controller (TRXC) in the Base
Transceiver Station (BTS) logical model G01 and TG, Central
Function (CF) or TRXC in the BTS logical model G12.
c, Function
This command orders the removing managed objects from service
into prepost service. The MO must be manually blocked, that is in
state COM. Up to 32 MOs can be specified. The MO instances(trng
hp,v d) from different BTS logical models can not be mixed(hn
hp).
The answer printout RADIO X-CEIVER ADMINISTRATION MANAGED OBJECT
OUT OF SERVICE COMMAND RESULT will be printed giving the result of
the command for all specified MO.
The subsequent result printout RADIO X-CEIVER ADMINISTRATION
MANAGED OBJECT OUT OF SERVICE COMMAND RESULT will be printed giving
the result of the command for all specified MO.
The appearance of answer or result printout depends on exchange
property OSSPRINTVER described in Application Information for block
ROEPC.
If this MO instance was the last removed object from service in
a TG, the observation alarm RADIO X-CEIVER ADMINISTRATION MANAGED
OBJECTS IN TRANSCEIVER GROUP MANUALLY BLOCKED will be ceased.
The order in which the MOs are brought out of service in BTS
logical model G01 is Time Slot (TS) and Receiver (RX) before the
corresponding TRXC; TRXC, Timing Function (TF) and Transmitter (TX)
before the corresponding TG.
The order in which the MOs are brought out of service in BTS
logical model G12 is RX, TX and TS before the corresponding TRXC;
Interface Switch (IS), Concentrator (CON), TRXC, TF, and Digital
Path (DP) before the corresponding CF; CF before the corresponding
TG.
The parameter SUBORD allows the specified MO instance and its
subordinates to be brought out of service.
The order remains after system restart.
-
17. Lnh a vo dch v :
a, Command / \ |MO=mo... |RXESI:+ +; |MO=mo[,SUBORD[,NOPRINT]] |
\ /
b, ParametersMO=mo Managed Object (MO) instance
See Application Information for block RXCTA for format and value
range of this parameter. All MO classes are valid.
NOPRINT No result printout
This parameter suppresses the result printout when parameter
SUBORD has been specified.
SUBORD Subordinate MOs
All of the MO instances subordinate to the specified MO are
included. Parameter SUBORD may be used for a Transceiver Group (TG)
or Transceiver Controller (TRXC) in the Base Transceiver Station
(BTS) logical model G01 and TG, Central Function (CF) or TRXC in
the BTS logical model G12.
c, Function
This command orders bringing Managed Objects into service from
prepost service. Up to 32 MOs can be specified. The MOs must be
defined, that is, in state DEF. The MO instances from different BTS
logical models can not be mixed.
Once an MO has been brought into service it will initially be
manually blocked, that is, in state COM. An attempt is then made to
load the MO.
The answer printout RADIO X-CEIVER ADMINISTRATION MANAGED OBJECT
IN SERVICE COMMAND RESULT will be printed giving the result of the
order for each of the MO instances specified by the MO
parameter.
-
A subsequent result printout RADIO X-CEIVER ADMINISTRATION
MANAGED OBJECT IN SERVICE RESULT will be given when the in-service
order is completed for all MO instances.
If this MO is the first object brought into service in a TG, the
observation alarm RADIO X-CEIVER ADMINISTRATION MANAGED OBJECTS IN
TRANSCEIVER GROUP MANUALLY BLOCKED will be raised.
The order in which the MOs are brought into service in BTS
logical model G01 is TG before the corresponding TRXC, Transmitter
(TX) and Timing Function (TF); TRXC before the corresponding Time
Slot (TS) and Receiver (RX).
The order in which the MOs are brought into service in BTS
logical model G12 is TG before the corresponding CF; CF before the
corresponding Interface Switch (IS), Concentrator (CON), TRXC, TF
and Digital Path (DP); TRXC before the corresponding RX, TX and
TS.
The parameter SUBORD, which may only be used in conjunction with
a single MO instance, will print the status of that MO instance and
all its subordinates. Upto a maximum of one-hundred and
eighty-three MOs can be returned when specifying the SUBORD
parameter.
When using parameter SUBORD, MO instances will only be processed
if their superior MOs are also defined.
The parameter NOPRINT, which may only be used in conjunction
with parameter SUBORD, suppresses the result printout.
The order remains after system restart.
18. Lnh xem lung v xem casce ca trm:
rxapp:mo=rxotg-TG;
19.Ch khi nng cp:
-nhy tn-Thay i gia con v uncon;(c th phi xem cu hnh trc ca trm l
dng con hay uncon bng lnh: rmop:mo=rxotf-
-
tg;). Nu nng ln cu hnh 4/4/4 th phi dng CON cho tt c cc TRX.
RXMOC:MO=RXOCF-TG,TEI=62,SIG=CONC; RXMOI:MO=RXOCON-
TG,DCP=64&&87; RXMOI:MO=RXOTRX- TG TEI,DCP1=..,DCP2..,
SIG=CONC;(Thm cc TRX c lin quan) RXMOI:MO=RXOTRX- TG -TEI,
DCP1=..,DCP2.., SIG=CONC;(Thm cc TRX c lin quan)
RXMOC:MO=RXOTRX-TG-TRX,SIG=CONC;(Thay i cc TRX khng lin
quan)
-Dng lnh halted v active:rlstc:cell=m
trm1,state=halted;rlstc:cell=m trm2 ,state=halted;rlstc:cell=m trm3
,state=halted;
rlstc:cell=m trm1,state=active;rlstc:cell=m
trm2,state=active;
rlstc:cell=m trm3,state=active;Khng dng nhy tn hay nhy
tn:-Change cells (when FHOP=BB and cell C has one CHGR=0)
RLCCC:CELL=m trm1,SDCCH=2,TN=2; RLCFI:CELL=m trm1,DCHNO=;
-when FHOP=SY and cell C has two CHGRs=0,1! RLCCC:CELL= m
trm1,CHGR=1,SDCCH=1,TN=1;
20. Xa cell:rlcrp:cell=cell;rxtcp:cell=
cell,moty=rxotg;rlvle:cell= cell,chtype=tch;(xa gim st)rlvle:cell=
cell,chtype=sdcch;(xa gim st)
rldee:cell= cell(lnh xa)
21. Lnh tng SAE: saaep:sae=502,BLOCK=RTAPH;
-
saaii:sae=502,BLOCK=RTAPH,ni=2048;(s ni ph thuc vo s thay i ca
sae)RXMOI:MO=RXOTRX-67-6, TEI=6, DCP1=146, DCP2=147&148,
SIG=UNCONC;rxmoe:mo=rxotrx-67-6;
22. Thm tn s cho cell:-Them tan so: trm BTS v thay rlccc ging nh
rlcfp theo cr: rlcfi:cell=sla0221,CHGR=0,DCHNO=68;
rlcfi:cell=sla0222,CHGR=0,DCHNO=72;Hin tng Unused hoc Block TRX:
-Trm unused c th do thiu tn s.-C th halted li cell ri active nu l
Unused.(Xem lnh RXMSP)-Dng lnh RLBDC thay i NUMREQBPC(khi khng th
thay i c knh SDCCH) nu l Unused.-Nu khng tng c knh SDCCH do
TN(TN=1, hay TN=1&2)-Khi chuyn trm m mt s trm c hin tng block
mt s TRX th c th do nhm lung.-Do khai sai bng tn GSM900-GSM1800,
cng sut pht 47dbm-45dbm nu Block.-Do gn sai TEI cho cell nn TX b
block.-i vi chgr=2 trm chung TG nu TX unused v MISMATCH=cell th c
th do li khai sai TRX gn cho mt tn cell ca trm khc.
2 3. Dng cho trm chung TG: RXMsc:MO=RXOTF-TG1,TFMODE=M;(tram
chu) RXMsc:MO=RXOTF-TG2,TFMODE=S,TFCOMPNEG= 4580(do ti u-hi ng
cu);
TFCOMPNEG Timing function negative compensation value This is
the distribution delay between the master TG and slave TG,plus own
TG transmitter chain delay, minus the master TG transmitter
chaindelay, given in nanoseconds.
Numeral 1 - 10000 TFCOMPPOS Timing function positive
compensation value
This is the distribution delay between the master TG and slave
TG,
-
plus own TG transmitter chain delay, minus the master TG
transmitter chaindelay, given in nanoseconds.
Numeral 0 - 10000 OMT
TF compensation value configured from OMT within the TG
Synchronization function
TFMODE Timing function synchronization mode This is the mode of
the timing function in the TG.M
Master, synchronized from the synchronization source and
distributed to other TFsThe availability of this parameter value
depends on commercial agreements.
S Slave, synchronized from other TFThe availability of this
parameter value depends on commercial agreements.
SA Standalone, synchronized from synchronization source
24. Xa TCH v thm TCH:
Rlstc:cell=,state=halted;Rlcfe:cell=,chgr=,dchno=;Rlcfi:cell=,chgr=,dchno=;Rlstc:cell=,state=active;
25. Lnh xa chgr v tn
s:Rlstc:cell=,state=halted;RLCHC:CELL=,CHGR=,HOP=on hoc off,HSN=hoc
0,maio=,bccd=;(thay i Yes hoc No)Rxtce:mo=rxotg-tg,cell=,chgr;(ngt
chgr)Rldge:cell=,chgr;(xa chgr)Rlstc:cell=,state=active;
26. Quan h gia cc cell: RLNRC:CELL=cell,CELLR=cellr,+Nu l xa:
RLNRE
-
1, Functiona, Format 1This command changes neighbour relation
data for defined relations.Format 1 is used for the Ericsson1
algorithm. See parameter EVALTYPE in command RLLBC.Issuing a
command of format 1 with all optional parameters included will
result in a too long command line exceeding the maximum input
buffer size of 140 characters. In this case, the command needs to
be given two times with some optional parameters in the first
command and the rest in the second command so that the maximum
input buffer size is not exceeded.For details about the default
values see Application Information for block RQCD.The order remains
after system restart. b, Format 2This command changes neighbour
relation data for defined relations.Format 2 is used for the
Ericsson3 locating algorithm. See parameter EVALTYPE in command
RLLBC.For details about the default values see Application
Information for block RQCD.The order remains after system
restart.
27 . BA list v Relation:
BA list:
1.1 Command:
RLMFC:CELL=cell,MBCCHNO=mbcchno...[,LISTTYPE=listtype]
[,MRNIC];
1.2 Parameters
CELL=cell Cell designation
This is a symbolic name of a defined cell.LISTTYPE=listtype Type
of measurement frequency list.
This parameter indicates in which mode the Mobile Station (MS)
will measure on the frequencies in the list.
ACTIVE Measurement frequency list to be used by active MSs
-
IDLE Measurement frequency list to be used by idle MSs
MBCCHNO=mbcchno Absolute Radio Frequency (RF) channel number for
measurement on Broadcast Control Channel (BCCH)
The number is the absolute RF channel number for the BCCH for
cells to be measured on by a MS in the cell.Numeral 128 - 251 (GSM
800) Numeral 1 - 124 (GSM 900, P-band) Numeral 975 - 1023, 0 (GSM
900, G1-band) Numeral 512 - 885 (GSM 1800) Numeral 512 - 810 (GSM
1900)
MRNIC Measurement results not interpreted correctly
At updating of the measurement frequencies, measurement results
are not interpreted correctly for a period of time.
2 Function
This command initiates or adds frequencies that MSs will measure
on in the cell. If the type of measurement frequency list is not
specified, then both idle and active lists are changed. The command
is only valid for internal cells, which are, cells belonging to the
current Base Station Controller (BSC).
If MRNIC is specified, or the cell state is halted, then the
updating of the measurement frequencies is performed immediately.
In this case the measurement results are not interpreted correctly
for a period of time. EXECUTED will be printed.
If MRNIC is not specified, the updating of the measurement
frequencies is performed over a period of time and the measurement
results are interpreted correctly. ORDERED will be printed and the
result printout ADDITION OF CELL MEASUREMENT FREQUENCIES COMPLETED
is received.
If the global system type is MIXED, it is possible to add
frequencies in the combination of GSM 800 band, GSM 900 band, and
GSM 1800 or GSM 1900 band.
The frequencies in G1 band can only be defined in a cell if the
feature Extended GSM Frequency Band support is available. The
availability of this feature depends on commercial agreements.
Basically up to 32 measurement frequencies can be defined in a
frequency list.
If the global system type is MIXED, the following restrictions
will apply according to the band in which the BCCH is defined and
the combination of measurement frequency bands. The following
restrictions apply to both IDLE and ACTIVE list types. In a few
cases, when BCCH is in GSM 900 P band or undefined, the
restrictions apply to IDLE list only (See Note 5 below). If the
list type is not specified, it is set to BOTH. When the list type
is set to BOTH, the restrictions are checked for both IDLE and
ACTIVE lists.
Li:
-
EXECUTEDORDEREDNOT ACCEPTEDfault type
Fault type:
FUNCTION BUSY The function is busy.
FORMAT ERRORdetails
The command or a parameter was incorrectly specified.
UNREASONABLE VALUEdetails
The parameter was specified with an unreasonable value.
FAULT CODE 3 CELL NOT DEFINED
The cell is not defined.
FAULT CODE 14 MBCCHNO ALREADY GIVENdetails
The measurement frequency has already been given.
FAULT CODE 21 MAXIMUM NUMBER OF MBCCHNO EXCEEDED
The maximum number of measurement frequencies is exceeded. See
chapter "2 Function" in this document for the maximum number of
measurement frequencies that can be defined in a measurement
frequency list.
FAULT CODE 38 COMMAND NOT VALID FOR EXTERNAL CELLS
The command must not be used for external cells, which are cells
belonging to another BSC.
FAULT CODE 50 ACTIVE BA-LIST RECORDING IS ACTIVE
It is not possible to change neither the active list nor the
idle list when the function Active BA-List Recording is active for
the cell.
FAULT CODE 171 PARAMETER VALUE NOT SUPPORTED BY THIS
EXCHANGEdetails
The possibility to define an MBCCHNO in G1 GSM band depends on
commercial agreements. Contact the sales organization.
Relation:
1.1 Command
RLNRI:CELL=cell,CELLR=cellr[,SINGLE];
-
1.2 Parameters
CELL=cell Cell designation
This is a symbolic name of a defined cell.CELLR=cellr Related
cell designation
This is a symbolic name of a defined related cell.SINGLE Single
direction cell relation
This parameter defines the relation to be a one way relation
between the cell and cellr. It means that handover can only be made
from CELL to CELLR
When SINGLE is not given, the relation will be mutual, which
means that handover in both directions is allowed.
2 Function
This command defines relations between cells. The type of
relation between the cells can be either mutual or one-way. When
relation is mutual, handover in both directions is allowed.
Mutual relation is default. Relation to an external cell, which
is a cell in another Base Station Controller (BSC) or a cell using
another Radio Access Technology (RAT), must be SINGLE.
To change the direction of a relation, the neighbour relation
must be deleted using command RLNRE and a new relation defined.
It is allowed to define up to 64 Global System for Mobile
Communication (GSM) neighbours and 64 UMTS Terrestrial Radio Access
Network (UTRAN) Frequency Division Duplex (FDD) neighbours to a
cell.
The order remains after system restart.
28 . Radio Control Cell, Dynamic HR Allocation Data, Change :
RLDHC:CELL=cell+[,DHA=dha][,DTHAMR=dthamr][,DTHNAMR=dthnamr]+;
29. Thay i nhy tn-BB hoc SY:
In BTS Logical Model G01
/RXMOC:MO=mo...+[,FHOP=fhop][,SWVER=swver][,COMB=comb] \
-
[,RSITE=rsite][,TRACO=traco][,CONFACT=confact] \
[,CONFMD=confmd][,EMG=emg]+; /In BTS Logical Model G12
/RXMOC:MO=mo...+[,FHOP=fhop][,SWVER=swver][,COMB=comb] \
[,RSITE=rsite][,TRACO=traco][,CONFACT=confact]
[,CONFMD=confmd][,SIGDEL=sigdel][,AHOP=ahop] \
[,ABISALLOC=abisalloc]+; /
30. Layer (Tng, lp) :
RLLHC:CELL=HNI5093,LAYER=2,LAYERTHR=80,LAYERHYST=2,PSSTEMP=0,PTIMTEMP=0,FASTMSREG=OFF;
31. Thay i CLS state: rllci:cell=HTY0032;(active hay inactive) /
|/ \/ \RLLCC:CELL=cell+|,CLSLEVEL=clslevel||,CLSACC=clsacc| |\ /\ /
\ / \ |,HOCLSACC=hoclsacc| \ / \ / \/ \|
|,RHYST=rhyst||,CLSRAMP=clsramp|+; \ /\ /| /
32. Thay i tham s HR cho cell: RLDMI:Cell=.;(bt hay tt DMSUPP-
RLDME) /RLDMC:CELL=cell+[,DMQB=dmqb] \[,DMQG=dmqg]
[,DMQBAMR=dmqbamr] [,DMQBNAMR=dmqbnamr] [,DMQGAMR=dmqgamr]
[,DMQGNAMR=dmqgnamr] [,DMTHAMR=dmthamr] \
[,DMTHNAMR=dmthnamr]+;
-
/
33. Xem EM v xem TRX:EXEMP:RP=ALL,EM=ALL;ntcop:snt=all;34. Kim
tra s TRXs:Command to check current number of TRXs:
RXMSP:MOTY=RXOTRX;
Select the appropriate action according to the fault:
LOF or LOS Failure(mt kh nng) in receive direction(s iu khin)
detected(nhn ra,pht hin ra) by local termination equipment. Go to
Step 34.
ALL1 or AIS Alarm indication(du hiu) signal transmitted by
remote(t xa, xa) end termination equipment due to(do , nh c)
failure upstreams. Further action is outside the scope of this
Operational Instruction. Consult the next level of maintenance
support and return to Step 50 in this Operational Instruction.
RDI Remote defect(mt ht) indication. Failure in transmit(truyn
,pht tn hiu) direction detected by remote end termination
equipment. Go to Step 34.
ERATE or CS ES Severe degradation of signal. Go to Step 43. LOMF
or REFM Faults related to multiframe signalling (TS16). Go to Step
38.
AISM Alarm indication signal in TS16 transmitted by remote end
termination equipment due to failure affecting the signalling
upstreams. Further action is outside the scope of this Operational
Instruction. Consult the next level of maintenance support and
return to Step 50 in this Operational Instruction.Other faults
Further action is outside the scope of this Operational
Instruction. Consult the next level of maintenance support and
return to Step 50 in this Operational Instruction.
35. Khi to ng dn cuc gi:RAPTI:LCH=2485;
Tracing(dau vet, lan theo) and printing(in ra) of connections
using logical channel number 2485 is made.36. Xem s TG dang hoat
dong va so TRX dang su dung:
rxmsp:moty=rxotg;rxmsp:moty=rxotrx;
37. Li v LRDEC: FAULT CODE 50 ACTIVE BA-LIST RECORDING( c ghi)
IS ACTIVE
-
When the cell state is ACTIVE and Active BA-List Recording is
active for the cell, it is not possible to change the RF channel
for BCCH.
Sa li 1:
a, Command
/ \ |rid...|RABRP:RID=+ +; |ALL | \ /
b, ParametersRID=rid Active BA-list Recording Identity
Identifier BARID00 - BARID63
ALL All RIDs C,Function
This command is used to print the details of one, severalor all
RIDs. The printout ACTIVE BA-LIST RECORDING DETAILSwill be
given.The order does not remain after system restart.
Sa li 2:
A, CommandRABRE:RID=rid[,MRNIC];
B, ParametersMRNIC Measurement Results Not Interpreted(trnh
din,th hin) Correctly(ng n,ph hp) When re-creating the active
BA-lists, Measurement Results are interpreted incorrectly
during(trong thi gian) a few minutes.
RID=rid Active BA-list Recording Identity Identifier BARID00 -
BARID63
C, FunctionThis command is used to interrupt a recording for
oneRID, before the duration time has elapsed.The command is only
accepted for RIDs that are in stateRECORDING or CONFIGURATION OF
BA-LISTS. The state of theinterrupted RID will then change to
RECORDING COMPLETE.If MRNIC is specified, then the re-creation of
the activeBA-lists is performed immediately. In this case
themeasurement results are interpreted incorrectly duringa few
minutes, e.g. a faulty handover can occur. Otherwise,the
re-creation of the active BA-lists is performed overa period of
time and the measurement results are
-
interpreted correctly.The printout ACTIVE BA-LIST RECORDING
TERMINATION RESULT will be given when the recording is ended. The
printout isrouted both to the ordering IO device and to the IO
deviceindicated by the printout category.The order does not remain
after system restart.
D, Examples
3.1 Example 1
RABRE:RID=BARID00,MRNIC;The active BA-list recording will be
terminatedfor the RID BARID00. When updating the active
BA-lists,measurement result will not be interpreted correctlyfor a
period of time.
38. Lin qua n BA-list(dng khc c th cha dng)
/ \ |,CELL=cell... | | / \| |,CELL=ALL |,CSYSTYPE=csystype||
RABDE:RID=rid + \ /+; | / \ | | |tmbcchno...| | |,TMBCCHNO= + + | |
|ALL | | \ /
a, ParametersCELL=cell Cell designation
Symbolic name, maximum 7 characters
ALL All Internal cells
CSYSTYPE=csystype System Type Identifier GSM800
GSM 800GSM900
GSM 900GSM1800
GSM 1800GSM1900
GSM 1900RID=rid Active BA-list Recording Identity
Identifier BARID00 - BARID63 TMBCCHNO=tmbcchno Absolute Radio
Frequency (RF) channel number for test
measurement on BCCHNumeral 128 - 251 (GSM 800)
-
Numeral 0 - 124 (GSM 900) Numeral 975 - 1023 (GSM 900) Numeral
512 - 885 (GSM 1800) Numeral 512 - 810 (GSM 1900)
The number is the absolute RF channel number for the BCCH for
cells to be measured on by a mobile station in the cell.
ALL All TMBCCHNOs connected to the RID
b,Function
This command removes cells or frequencies from an active
recording. During the recording the frequencies are included in the
active BCCH Allocation (BA) lists, for all cells connected to the
RID.
It is possible to remove one cell, several cells, all cells or
all cells of a specific system type from a RID or remove one
frequency, several frequencies or all frequencies from a RID.
The command is only accepted for RIDs that are in state
ALLOCATED, USED or RECORDING COMPLETE.
If all cells are removed from the RID the state is changed to
ALLOCATED.
The order does not remain after system restart.
C, Examples
- Example 1RABDE:RID=BARID15,CELL=KNA11;
Removes the cell KNA11 from the RID BARID15.
- Example 2RABDE:RID=BARID25,CELL=ALL,CSYSTYPE=GSM1900;
Removes all cells of the system type GSM 1900 from the RID
BARID25.
- Example 3RABDE:RID=BARID37,TMBCCHNO=530&&550;
Removes TMBCCHNOs 530 up to 550 from the RIDBARID37.
-
- Example 4RABDE:RID=BARID53,TMBCCHNO=ALL;
Removes all the test BCCH frequencies from the RID BARID53.
39.Lnh print cc ETM:
1.1 Command / \ |SDIP=sdip... |TPSTP:[IO=io,]+ +;
|SDIP=ALL[,STATE=state...]| \ /
1.2 ParametersIO=io Input/Output (IO) device name
Identifier 1 - 7 characters SDIP=sdip Synchronous Digital Path
(SDIP) name
Identifier 1 - 7 characters ALL
All SDIPsSTATE=state State of SDIP
BLOC Blocked
PBLOC Partly blocked
TRAFBLOC Traffic blocked
TRAFLIM Traffic limited
WO Working
2 Function
This command prints the state of specified SDIP on specified or
default IO device.
Printout SYNCHRONOUS DIGITAL PATH STATE is received.
Up to 10 SDIPs can be specified in each command.
The order does not remain after system restart.
3 Examples
3.1 Example 1TPSTP:SDIP=LONDON;
-
The state of SDIP LONDON is printed.
3.2 Example 2TPSTP:IO=AT-4,SDIP=LONDON&OSLO;
The state of the SDIPs LONDON and OSLO is printed on IO device
AT-4.
3.3 Example 3TPSTP:SDIP=ALL;
The state of all SDIPs is printed.
3.4 Example 4TPSTP:IO=AT-4,SDIP=ALL,STATE=WO&BLOC;
All working and all blocked SDIPs are printed on IO device
AT-4.
40. Deblock cc ETM:
1.1 Command / // \\\ | ||,MS=ms...||| |sdip|+,HP +|| |
||,HP=hp...|||TPBLE:SDIP=+ ||,LP=lp...||+; | \\ //| |sdip... | | |
|ALL | \ /
1.2 ParametersHP=hp Higher order Path (HP)
For the value ranges, see the Application Information for SDIP
owning block.
LP=lp Lower order Path (LP)
For the value ranges, see the Application Information for SDIP
owning block.
MS=ms Multiplex Section (MS)
For the value ranges, see the Application Information for SDIP
owning block.
SDIP=sdip Synchronous Digital Path (SDIP) nameIdentifier 1 - 7
characters ALL
All SDIPs
-
2 Function
This command deblocks either the whole SDIP including all
existing lower layers, or only the MS, the HP, or the LP when they
are specified.
Result printout SYNCHRONOUS DIGITAL PATH DEBLOCKING RESULT is
received.
Up to 10 SDIPs can be specified in each command.
The order remains after system restart.
3 Examples
3.1 Example 1TPBLE:SDIP=LONDON;
The whole SDIP LONDON is manually deblocked.
3.2 Example 2TPBLE:SDIP=LONDON,MS=MS-0&-1;
The MS-0 and MS-1 within SDIP LONDON are manually deblocked.
3.3 Example 3TPBLE:SDIP=LONDON,HP;
The HP within SDIP LONDON is manually deblocked.
3.4 Example 4TPBLE:SDIP=LONDON,LP=VC12-0&&-47;
The LPs VC12-0 to VC12-47 within SDIP LONDON are manually
deblocked.
3.5 Example 5TPBLE:SDIP=LONDON&OSLO&NACKA;
The SDIPs LONDON, OSLO, and NACKA are manually deblocked.
3.6 Example 6TPBLE:SDIP=ALL;
All SDIPs are manually deblocked.
3.7 Example 7TPBLE:SDIP=CHICAGO,HP=STS1-0&-1
The HPs STS1-0 and STS1-1 within SDIP CHICAGO are manually
deblocked.
-
41. Dng blocking RP:
1.1 Command
BLRPI:RP=rp[,FORCED];
1.2 Parameters
RP=rp Regional Processor (RP) addressNumeral 0 - 1023
The maximum value is defined by the Size Alteration Event (SAE)
304FORCED Blocks RP regardless of Extension Module (EM) state and
device state.
2 Function
This command is used when blocking an RP, where the logical
state of the RP is set to Manually Blocked (MB). The bus senders
are blocked from sending signals on the RP bus.
In the case of RPs with an EM bus, the control of the connected
equipment, EMs, is transferred automatically, if possible, to the
twin RP through local restarts of the EMs.
If the control of EMs cannot be transferred, all EMs linked to
the RP and all devices connected to the EMs must be manually
blocked before the command can be accepted.
For some RPs without EM bus it is sufficient that all devices
connected to the EMs are manually blocked before the command can be
accepted.
If the parameter FORCED is given, the RP is blocked regardless
of EM state and device state. This parameter shall be used with
care as it can result in traffic disturbance. Special checks
requested by EM owner to ensure that critical IO-channel system
resources are not lost, are still done.
For some RP types without an EM bus, the commands for blocking
and deblocking of EM are not applicable. The operational state for
the EM is then controlled by blocking and deblocking the RP. For
these RPs, some checks normally performed at BLEMI are performed at
BLRPI instead.
The order remains after system restart.
3 Examples
3.1 Example 1
BLRPI:RP=2;
-
An RP with address 2 is blocked (if EM state and device state
are manually blocked).
3.2 Example 2
BLRPI:RP=5,FORCED;
An RP with address 5 is blocked regardless of EM state and
device state.
42. Remove EM(expension module):
1.1 Command
EXEME:RP=rp[,RPT=rpt],EM=em;
1.2 Parameters
EM=em Extension Module (EM) addressNumeral 0 - 63
RP=rp Regional Processor (RP) addressNumeral 0 - 1023
Actual maximum value is defined by Size Alteration Event (SAE)
304.RPT=rpt RP address for twin(sinh i, cp i) RP
Numeral 0 - 1023
Actual maximum value is defined by SAE304.
2 Function
The command is used in order to remove the definition of an EM.
Devices connected to the EM must be manually blocked. Also the EM
must be blocked except(tr ra, loi ra) for the RP-types for which EM
blocking command is not applicable(c th ng dng c). For these
RP-types the RP must be blocked instead(thay vi, thay cho). If the
EM is controlled by an RP pair, both the RP addresses must be
indicated(chi ra).
The order remains after system restart.
3 Examples
3.1 Example 1
EXEME:RP=16,RPT=17,EM=4;
The definition of the EM with address 4, in the RP pair which
consists of RPs 16 and 17, is removed.
-
3.2 Example 2
EXEME:RP=50,EM=5;
The definition of the EM with address 5, in the single RP 50, is
removed.
43. Lnh ny dng xa Regional Software Units (RSU):
1.1 Command
/ \ | / \| | |ALL || / \ |SUNAME=+ +| |RP=rp... | |
|suname||EXRUE:+ +,+ \ /+; |RP=rp,RPT=rpt| | / \ | \ / | |ALL | |
|SUID=+ + | | |suid| | | \ / | \ /
1.2 Parameters
RP=rp Regional Processor (RP) addressNumeral 0 - 1023
The maximum value is defined by Size Alteration Event (SAE)
304.RPT=rpt Regional Processor Twin (RPT) address
Numeral 0 - 1023
The maximum value is defined by SAE=304.SUID=suid Software Unit
(SU) identity
Identifier 1 - 32 characters
If the identifier contains any character, other than letters or
digits then the string must be given within quotation marks.
SUNAME=suname SU nameIdentifier 1 - 8 characters
2 Function
Command EXRUE is used to delete defined Regional Software Units
(RSU) in an RP (RP pair) or in a suite of RPs. The specified suite
of RPs must not consist of more than 128 RPs.
-
The specified RP or RPs must be manually blocked (not blocked
for repair or blocked for function change). Parameter SUID must be
specified if more than one version of the specified SU is
defined.
If a specific SUNAME (SUID) is given, it must be defined in all
the specified RPs.
The RSUs must be deleted at the same time for both RPs in an RP
pair. The two addresses in the pair can be specified in two
different ways as follows:
With parameters RP and RPT With parameter RP for both
addresses
If the command is used to delete definitions of SUs in more than
one RP (RP pair) at a time, all the RP addresses (including the RPT
addresses) must be specified with parameter RP.
An RSU of type Firmware Replacement Package (FRP) shall not be
deleted unless it shall be replaced or it is faulty. This is to
avoid that, at repair of RPs, an RP board is entered and started
with an old FRP RSU. Although an FRP RSU is removed by command
EXRUE the FRP RSU will continue to be working in the RP (if it once
has been loaded to the RP).
The order remains after system restart.
3 Examples
3.1 Example 1
EXRUE:RP=7,RPT=8,SUNAME=RPFDR;
The definition of the RSU with name RPFDR in RP 7 and RPT 8 is
deleted.
3.2 Example 2
EXRUE:RP=7,SUID="5/CAA1053092/1R1A02";
The definition of an RSU with product identity 5/CAA 105 3092/1
R1A02 in RP 7 is deleted.
3.3 Example 3
EXRUE:RP=7&20,SUNAME=RPFDR;
The definition of the RSU with name RPFDR in RP 7 and RP 20 is
deleted.
3.4 Example 4
EXRUE:RP=7&&20,SUNAME=RPFDR;
-
The definition of the RSU with name RPFDR in the RP suite RP 7
through RP 20 is deleted.
3.5 Example 5
EXRUE:RP=7&&20,SUNAME=ALL;
All RSU definitions in the RP suite RP 7 through RP 20 are
deleted.
3.6 Example 6
EXRUE:RP=25,SUID="9000/CXC 152 001 R1A01";
The FRP RSU definition with product identity 9000/CXC 152 001
R1A01 in RP 25 is deleted. If loaded to the RP, the FRP will not be
removed from the RP.
44. Lnh ny dng remove cc RP:
1.1 Command
EXRPE:RP=rp[,RPT=rpt];
1.2 Parameters
RP=rp Regional Processor (RP) addressNumeral 0 - 1023
The maximum value is defined by Size Alteration Event (SAE)
304.RPT=rpt RP twin address
Numeral 0 - 1023
The maximum value is defined by SAE 304.
2 Function
This command is used in order to remove the definition of an RP
or an RP pair.
The command requires that the affected RP is manually blocked
and and that the definition of associated equipment has been
removed.
If the RP is loadable, all Software Unit (SU) definitions must
also be removed (by command EXRUE).
The order remains after system restart.
3 Examples
-
3.1 Example 1
EXRPE:RP=17;
The definition of a single RP, with address 17, is removed.
3.2 Example 2
EXRPE:RP=17,RPT=8;
The definition of an RP pair, with addresses 17 and 8, is
removed.
45. Khi to li RP:
1.1 Command
EXRPI:RP=rp[,RPT=rpt],TYPE=type[,DEFRSU];
1.2 Parameters
DEFRSU Define Regional Software UnitsRP=rp Regional Processor
(RP) address
Numeral 0 - 1023
The maximum value is defined by Size Alteration Event (SAE)
304.RPT=rpt RP twin address
Numeral 0 - 1023
The maximum value is defined by SAE 304.TYPE=type RP type
Text string 1 - 7 characters
2 Function
This command initiates RP equipment for the specified RP-address
(or addresses) and for the specified type of RP.
If parameter DEFRSU is given then default Operating System (OS)
Regional Software Units (RSU), as specified in database table
RPSDEFOSRSUS, are defined for the RP. The effect of parameter
DEFRSU is the same as if these RSUs had been defined by command
EXRUI after command EXRPI.
Possible RP types are described in Application Information for
block RPADM.
All valid types of RPs, with characteristics and properties of
the different types, can be listed by printing the database tables
RPSRPTYPES, RPSTYPESTOPROPS and RPSRPPROPERTIES.Use generic DBS
print command DBTSP.
-
The order remains after system restart.
Note: Also an RSU of type Firmware Replacement Package (FRP) can
be defined for the RPs by use of parameter DEFRSU. FRP RSUs can be
included in the DBS table RPSDEFOSRSUS.
3 Examples
3.1 Example 1
EXRPI:RP=17,TYPE=RPM1A;
An RP of type RPM1A is defined. It has RP address 17.
3.2 Example 2
EXRPI:RP=17,RPT=8,TYPE=RPM6A;
An RP pair of type RPM6A is defined. The pair will control the
same EMs. The pair has RP addresses 17 and 8.
3.3 Example 3
EXRPI:RP=30,RPT=31,TYPE=RPM2B;
An RP pair of type RPM2B is defined. It has RP addresses 30 and
31.
3.4 Example 4
EXRPI:RP=20,type=STC1A;
A Signalling Terminal Central (STC) with RP address 20 is
defined.
3.5 Example 5
EXRPI:RP=40,TYPE=RPI1A,DEFRSU;
An RP of type RPI1A is defined. Default OS RSUs are defined for
the RP. The RP has RP address 40.
46. Khi to cc kt ni SNT:
1.1 Command
/ \ |[SNTP=sntp,]SNT=snt...[,IDLEP=idlep] |
-
| | |SNTP=sntp...,SNT=snt[,IDLEP=idlep] | |
|NTCOI:+SNTP=sntp,SNT=snt,EQLEV=eqlev,PROT=prot[,IDLEP=idlep]
+,SNTV=sntv; | |
|SNTP=sntp,SNT=snt[,MODE=mode][,PROT=prot][,IDLEP=idlep]| | |
|EXTP=extp,SNT=snt[,MG=mg] | \ /
1.2 Parameters
EQLEV=eqlev Equipping level
This parameter is only intended for Switching Network Terminal
(SNT) with Subordinate SNTs and protection.
For value range, see the Application Information for SNT-owning
block. EXTP=extp External Hardware Connection Point
This parameter is only intended for the connection of SNT to
External Hardware Switch.
If the SNT-owning block supports parameter MG then the EXTP
parameter value has to be written within quotation marks.
For string range, see the Application Information for SNT-owning
block. IDLEP=idlep Idle pattern
For value range, see the Application Information for block
SNTH.MG=mg Media Gateway
This parameter is only intended for the connection of SNT to
External Hardware Switch.Text string 1 - 7 characters
MODE=mode Mode
This parameter is only intended for the connection of DL34
SNTs.
For value range, see the Application Information for SNT-owning
block. PROT=prot Protection
This parameter indicates if equipment protection is used.
This parameter is only intended for SNT with Subordinate SNTs
and protection.
For value range, see the Application Information for SNT-owning
block. SNT=snt Switching network terminal
-
Expressed as snt-n where:
snt Switching network terminal typeIdentifier 1 - 13
characters
n Switching network terminal numberNumeral 0 - 65535
The maximum value of the switching network terminal number is
determined by Size Alteration Event (SAE) in the SNT-owning block
(SAE 529).
For alternative expressions, see the Application Information for
block TRAN and the relevant SNT-owning block.
SNTP=sntp Switching network terminal connection point
Expressed as a-b-c where:
a Switch unit nameIdentifier 1 - 7 characters
b Switch unit number
c Switching network terminal point
See Application Information for block TRASAD.
Expressed as a-b-f or a-d-e-f where:
a Switch unit nameIdentifier 1 - 7 characters
b Switch unit number
d Switch unit row number
e Switch unit column number
f Digital link number
See Application Information for block SNTHSNTV=sntv Switching
network terminal variant
For value range, see the Application Information for SNT-owning
block.
2 Function
This command connects a Switching Network Terminal (SNT) to a
Group Switch (GS), a Subscriber Switch (SS), or an External Switch.
For SNTs with subordinate
-
SNTs or SNTs to be connected to an external switch, one SNT can
be connected in one command issue. For SNTs of any other type, the
maximum of 32 SNTs can be connected. For an SNT with several
hardware connections to the GS, the connection is made in
consecutive order according to the designations of these
connections.
For DL3 SNTs with subordinate SNTs the number of the subordinate
SNTs to be connected are indicated by parameter EQLEV. Also the
equipment protection can be specified for this type of SNT with
parameter PROT .
For DL34 SNTs with subordinate SNTs, the number of Multiple
Points (MUPs) to be reserved by the GS is indicated by parameter
MODE.
For SNTs connected to an External Switch, parameter SNTP is not
allowed. Parameter EXTP should be used instead indicating the
connection point (port) of the External Hardware Switch. If this
SNT supports connection to a Media Gateway (MG), parameter MG
should be used indicating the MG name.
Parameter IDLEP may be specified only when this parameter is
supported by the specified SNTs.
Note: Three adaptation blocks exist in the AXE, SNTPCD, SNTET
and SNTMJ. These are used to connect device types which are not SNT
owners. For SNTs connected in adaptation blocks, the SNT type is
defined when the first SNT of that type is connected. This is not
specified in a separate parameter but is implicit in the
command.
The order remains after system restart.
3 Examples
3.1 Example 1
NTCOI:SNT=SNTPCD32-2,SNTP=TSM-1-2,SNTV=5;
The SNT of type SNTPCD 32, variant 5 and individual 2 is
connected to the SNT connection point 2 in Time Switch Module (TSM)
1.
3.2 Example 2
NTCOI:SNT=ET1-0,SNTV=1;
The SNT of type ET1, variant 1 and individual 0 is connected to
the SNT connection.
3.3 Example 3
NTCOI:SNTP=TSM-12-3&&-4,SNT=ASAM-0,SNTV=1;
The SNT of type ASAM, variant 1 and individual 0 is connected to
the SNT connection points 3 and 4 in TSM 12.
-
3.4 Example 4
NTCOI:SNTP=TSM-1-0,SNT=SNTETET8-2&&-4,SNTV=2;
The SNTs of type SNTETET8, variant 2, with individuals 2, 3, and
4 are connected in consecutive order to the SNT connection points
0,1 and 2 in TSM 1.
3.5 Example 5
NTCOI:SNTP=TSM-8-13,SNT=SNTETET8-2&&-6,SNTV=2;
The SNTs of type SNTETET8, variant 2, with individuals 2,3 and 4
are connected in consecutive order to the SNT connection points
13,14 and 15 in TSM 8. Since connection position 15 is the last
position in TSM 8, the sequence continues in TSM 9. Therefore
individuals 5 and 6 are connected to connection points 0 and 1 in
TSM 9.
3.6 Example 6
NTCOI:SNT=ET155-2,SNTP=TSM-1-0,SNTV=1,EQLEV=1,PROT=1;
The SNT ET155, individual 2 of variant 1 is connected to the TSM
1. The EQLEV parameter indicates that one SUBSNT is connected to
the switch. Also that the SNT has equipment protection is
defined.
3.7 Example 7
NTCOI:SNT=ET155-3,SNTP=TSM-1-0,SNTV=1,EQLEV=3,PROT=3;
The SNT ET155, individual 3 of variant 1, is connected in
consecutive order to the TSM 1, 2 and 3. The EQLEV parameter
indicates that three subordinate SNTs are connected to the switch.
Also that the SNT has equipment protection is defined.
3.8 Example 8
NTCOI:SNT=MBTRCS-0,SNTP=TSM-0-0&TSM-1-0,SNTV=1;
The SNT MBTRCS, individual 0 of variant 1, is connected to TSM 0
and TSM 1 at the same connection point of both TSMs (0 in this
example).
3.9 Example 9
NTCOI:SNT=VET-2, EXTP=32-4-8-5, SNTV=0;
The VET SNT, individual 2 of variant 0 is connected to an
external hardware connection point which is positioned in subrack
32 in slot 4 on subport 5 of port 8.
3.10 Example 10
-
NTCOI:SNTP=MUX3-8-4,SNT=SNTETET8-2&&-6,SNTV=2,IDLEP=1;
The SNTs of type SNTETET8, variant 2, with individuals 2 to 6,
are connected in consecutive order to the access points 4,5,6,7 and
8 in MUX3 8.
3.11 Example 11
NTCOI:SNT=ET155-2,SNTP=XM-1-2-8,SNTV=1,MODE=128,PROT=1;
The SNT ET155, individual 2 of variant 1 is connected to the XM
in row 1 and column 2. The number of MUPs to be allocated by the GS
for this SNT is specified in parameter MODE. Also equipment
protection for the SNT is defined.
3.12 Example 12
NTCOI:EXTP="28-2-5-3",SNT=VET-1,MG=AXDWA,SNTV=0;
The VET SNT, individual 1 of variant 0, is connected to an
external hardware connection point of the MG AXDWA which is
positioned in subrack 28 in slot 2 on subport 3 of port 5.
47. Khi to v test cc SNT:
1.1 Command
NTTEI:SNT=snt [,SUBSNT=subsnt];
1.2 Parameters
SNT=snt Switching Network Terminal (SNT)
Expressed as snt-n where:
snt SNT typeIdentifier 1 - 13 characters
n SNT numberNumeral 0 - 65535
The maximum value of the SNT number, is determined by the Size
Alteration Event (SAE) in the SNT owning block (SAE 529).
For alternative expressions, see the Application Information for
block TRAN and the relevant SNT owning block.
SUBSNT=subsnt Subordinate switching network terminal
For value ranges, see the Application Information for the
relevant
-
SNT owning block.
2 Function
This command initiates testing of a manually blocked SNT or a
subordinate SNT. When an SNT with subordinate SNTs is specified in
the command, only the specified subordinate SNTs are tested.
Otherwise, the complete SNT is tested.
Result printout SWITCHING NETWORK TERMINAL TEST RESULT is
received.
The order does not remain after system restart.
3 Examples
3.1 Example 1
NTTEI:SNT=SNTPCD32-9;
SNT 9 of type PCD32 is tested.
3.2 Example 2
NTTEI:SNT=SNTETBT4-2;
SNT 2 controlled by device block BT4 is tested.
3.3 Example 3
NTTEI:SNT=ET155-4,SUBSNT=3;
Subordinate SNT 3 of ET155 SNT 4 is tested.
48. Deblock cc SNT:
1.1 Command
/ \ |snt... |NTBLE:SNT=+ +; |snt [,SUBSNT=subsnt...]| \ /
49. XM bi block:
1.2 Parameters
-
SNT=snt Switching Network Terminal (SNT)
Expressed as snt-n where:
snt Switching network terminal typeIdentifier 1 - 13
characters
n Switching network terminal numberNumeral 0 - 65535
The maximum value of the switching network terminal number, is
determined by the Size Alteration Event (SAE) in the SNT owning
block (SAE 529).
For alternative expressions, see the Application Information for
block TRAN and the relevant SNT owning block.
SUBSNT=subsnt Subordinate switching network terminal
For value ranges, see the Application Information for the
relevant SNT owning block.
2 Function
This command deblocks an SNT or a subordinate SNT. When an SNT
with subordinate SNTs is specified in the command, only the
specified subordinate SNTs are deblocked. Otherwise, the complete
SNT is deblocked.
A maximum of 128 SNTs or 1 SNT with SUBSNTs or specified
SUBSNTs, can be specified in one command issue.
The supervision is activated for the entire deblocked SNT, or
for the deblocked subordinate SNT.
Result printout SWITCHING NETWORK TERMINAL DEBLOCKING RESULT is
received.
The order remains after system restart.
3 Examples
3.1 Example 1
NTBLE:SNT=SNTETBT3-18&&-21;
SNT of type SNTETBT3 with individuals 18, 19, 20, and 21 are
manually deblocked.
3.2 Example 2
NTBLE:SNT=ET6-27&&-29;
-
SNT of type ET6 with individuals 27, 28, and 29 are manually
deblocked.
3.3 Example 3
NTBLE:SNT=ET155-0,SUBSNT=0&&3;
Subordinate SNT 0, 1, 2, and 3 of ET155 SNT 0 are manually
deblocked.
3.4 Example 4
NTBLE:SNT=ET155-0&&-2;
SNT of type ET155 with individuals 0, 1, and 2 are manually
deblocked.
3.5 Example 5
NTBLE:SNT=ET155-10,SUBSNT=1&5;
Subordinate SNT 1 and 5 of ET155 SNT 10 are manually
deblocked.
1.1 Command / / / \ \ \ | |UNIT=unit...|,DETAIL| | |GDSTP|:+ \ /
+ |; | |TYPE=type | | \ \ / /
1.2 ParametersDETAIL Detailed printoutTYPE=type Type of
Distributed Group Switch unit to be printedUNIT=unit Distributed
Group Switch unit identifier
Expressed as clm-n, mux-p-n, or xm-p-r-c where:
c Individual column number
clm Clock module name
mux Multiplexer unit name
n Unit number
p Plane identifier
r Individual row number
xm Switch matrix unit name
A Plane A
B
-
Plane B
Note: See Application Information for block GIOH and each unit
specific AI.
2 Function
This command prints the state of Distributed Group Switch
units.
The command accepts the specification of a single unit, multiple
units of varying types, all units of a particular type, or all
units in the Distributed Group Switch.
If parameter TYPE is specified, the state of all the Distributed
Group Switch units of the type specified in the command are
printed.
Repetition is allowed for all unit types.
For switch matrix units, repetition is only allowed on the
column identifier.
When a range of units is specified and if no units are connected
to the Distributed Group Switch in the given range then NONE is
printed. Otherwise, only the state of the units that are connected
are printed.
If parameter DETAIL is specified, the states of the whole chain
of downstream Distributed Group Switch units connected to the units
specified in the command are printed. It is not allowed to specify
a Clock unit together with parameter DETAIL.
The answer printout DISTRIBUTED GROUP SWITCH STATE is
received.
The order does not remain after system restart.
1.1 CommandGDBLI:UNIT=unit;
1.2 ParametersUNIT=unit Distributed Group Switch unit
Expressed as clm-n, mux-p-n, or xm-p-r-c where:
c Individual column number
clm Clock Module (CLM) name
mux Multiplexer unit name
n Unit number
p Plane identifier
A Plane A
-
B Plane B
r Individual row number
xm Switch Matrix (XM) unit name
See Application Information for block GIOH and each unit
specific AI (CLM, MUX3, MUX34, MUXSP , MUXTS, XM).
1.3 Dialogue ParametersNO; Manual blocking of the specified CLM
is not to take place.YES; Manual blocking of the specified CLM unit
is to take place.
2 Function
This command initiates blocking of a unit in the Distributed
Group Switch, provided the blocking will not result in traffic
restrictions.
Result printout DISTRIBUTED GROUP SWITCH UNIT BLOCKING RESULT is
received.
Manual blocking of automatically blocked units is always
permitted, but not in units which are not connected.
Manual blocking of a CLM means considerable risk for the
exchange as there are only two CLMs in the Distributed Group
Switch. For this reason unnecessary blocking must be avoided. In
the case of an unnecessary blocking attempt on a CLM, the dialogue
procedure starts and answer printout WARNING, ACCEPTANCE MEANS
CONSIDERABLE RISK FOR THE WHOLE EXCHANGE, ANSWER WITH YES IF YOU
WANT TO CONTINUE will be received. Indicate with YES if the
blocking is to be executed. Indicate with NO if the blocking is not
to be executed, and the printout BLOCKING ORDER CANCELLED will be
received.
An observation alarm DISTRIBUTED GROUP SWITCH UNIT MANUALLY
BLOCKED indicating that the unit is now blocked is added in the
alarm list.
If the alarm DISTRIBUTED GROUP SWITCH FAULT is present for the
unit being manually blocked, then the fault alarm is ceased.
This command cannot be given immediately after an initial start
or if the switch type is not initiated.
The order remains after system restart.
1.1 CommandGDBLE:UNIT=unit;
1.2 ParametersUNIT=unit Distributed Group Switch unit
identifier
-
Expressed as clm-n, mux-p-n or xm-p-r-c where:
c Individual column number
clm Clock Module (CLM) name
mux Multiplexer unit name
n Unit number
p Plane identifier
A Plane A
B Plane B
r Individual row number
xm Switch Matrix (XM) unit name
See Application Information for block GIOH and each unit
specific AI (CLM, MUX3, MUX34, MUXSP , MUXTS, XM).
2 Function
This command ends the blocking of a unit in the Distributed
Group Switch.
Result printout DISTRIBUTED GROUP SWITCH UNIT DEBLOCKING RESULT
is received.
An observation alarm DISTRIBUTED GROUP SWITCH UNIT MANUALLY
BLOCKED indicating that the unit was blocked is no longer in the
alarm list.
This command cannot be given immediately after an initial start
or if the switch type is not initiated.
The order remains after system restart.
3 Examples
3.1 Example 1GDBLE:UNIT=CLM-1;
This command ends the blocking of CLM unit 1.
3.2 Example 2GDBLE:UNIT=MUX3-B-2;
-
This command ends the blocking of the Digital Link version 3
Multiplexer (MUX3) in plane B, unit 2.
3.3 Example 3GDBLE:UNIT=MUX34-A-3;
This command ends the blocking of the Digital Link adaptable
from version 3 to 4 Multiplexer (MUX34) in plane A, unit 3.
3.4 Example 4GDBLE:UNIT=MUXSP-B-1;
This command ends the blocking of the Multiplexer based on Space
Switch Module (MUXSP) in plane B, unit 1.
3.5 Example 5GDBLE:UNIT=MUXTS-A-2;
This command ends the blocking of the Multiplexer based on Time
Switch Module (MUXTS) in plane A, unit 2.
3.6 Example 6GDBLE:UNIT=XM-B-1-4;
This command ends the blocking of XM in plane B, row 1, column
4.
50. Xem RP/EM:
1.1 Command / \ |DEV=dev... | | | | / \ |RADRP:+ |dety...| +;
|DETY=+ +[,PPS]| | |ALL | | | \ / | \ /
1.2 ParametersDETY=dety Device type ALL All device typesDEV=dev
DevicePPS Pre-Post Service If this parameter is given, then data is
printed only for devices in Pre-Post Service State. If the
parameter is omitted, then data is printed only for devices not in
Pre-Post Service State.
-
2 FunctionThe command orders a printout of device RP/EM data.The
printout DEVICE RP/EM DATA IN BSC is received forspecified devices,
all devices of a device type, or alldevices.If the parameter PPS is
specified in the command, thenonly devices which are in Pre-Post
Service State will beincluded on the printout.If the parameter PPS
is omitted, when only devices whichare not in Pre-Post Service
State will be included onthe printout.Up to sixteen (16) such
commands may be given simultaneously.All DEVICE RP/EM DATA IN BSC
printouts are interruptedand terminated on commencement of an
EXCHANGE DATA command,to prevent the possibility of out-of-date
printouts beingobtained.The order does not remain after system
restart.
50. Lnh pint v tng sae:
1.1 Command
/ \ / / \\|sae| | |block||
SAAEP:SAE=+ + |,BLOCK= + +|;|ALL| | |ALL ||\ / \ \ //
1.2 Parameters
BLOCK=block Block name Identifier 1 - 7 characters
ALL All loaded blocksSAE=sae Size Alteration Event Numeral 0 -
8192 The maximum value is defined in the Operating System Area as
highest usable SAE number.
ALL All defined SAEs
2 FunctionThis command is used to print file size information of
Size Alteration Events (SAEs) defined in the system.The parameter
SAE specifies the Size Alteration Eventnumber. The SAE type can be
local or global. The tableindicates the number range for local and
global SAEs:
-
Table 1 SAE Type SAE number rangeGLOBAL 0 - 499LOCAL 500 -
899GLOBAL 900 - highest usable SAE number defined in the Operating
System
AreaIf the SAE number specified in parameter SAE is oftype
LOCAL, the parameter BLOCK must also be specified.If value ALL is
specified for parameter BLOCK then file size information of the
specified LOCAL SAE inall participating blocks are printed.If the
SAE number specified in parameter SAE is oftype GLOBAL, the
parameter BLOCK must not be specified.If parameter value ALL is
specified for parameter SAEthen file size information of all SAEs
defined in thesystem are printed. If a block name is specified
togetherwith ALL for parameter SAE, then all SAEs defined in
thespecified block are printed.The function uses the SAE database
tables where all SAEs that are defined in the system are stored. If
theSAE database tables are not complete, the function allowsfile
size information of one SAE to be printed.The order does not remain
after system restart.
3 Examples
3.1 Example 1
SAAEP:SAE=4;This command prints file size information ofof
Global SAE 4.
3.2 Example 2
SAAEP:BLOCK=RE,SAE=513;This command prints file size information
ofLocal SAE 513 participated by block RE.
3.3 Example 3
SAAEP:BLOCK=RE,SAE=ALL;This command prints file size information
ofall SAEs participated by block RE.
3.4 Example 4
SAAEP:SAE=500,BLOCK=ALL;This command prints file size
information ofLocal SAE 500 in all participating blocks.
-
3.5 Example 5
SAAEP:SAE=ALL;
3 Examples
3.1 Example 1RADRP:DEV=RXTRA-1;Printout device RP/EM data for
device RXTRA-1.
3.2 Example 2RADRP:DEV=RXTRA-33&&-47;Printout device
RP/EM data for devices RXTRA-33 toRXTRA-47 inclusive.
3.3 Example 3RADRP:DETY=RXTRA,PPS;Printout device RP/EM data for
all RXTRA-devices inPre-Post Service State.
3.4 Example 4RADRP:DETY=ALL;Printout device RP/EM data for all
devices not inPre-Post Service State.L i: FAULT CODE 6INVALID
DEVICE TYPE SPECIFIEDdetails Command not permitted for this device
type.FAULT CODE 7DEVICE TYPE DOES NOT HAVE PPS FUNCTIONdetails
Device type does not have the Pre-Post Service state function
associated with it.FAULT CODE 18NO DEVICE DATA AVAILABLE FOR
OUTPUTdetails No device data available for output.FAULT CODE 29DATA
CHANGE IN PROGRESS Command not allowed, data change command in
progress.51. Tng SAE t ng:
1.1 Command
-
SAALI;
1.2 Parameters
-
2 FunctionCommand SAALI orders the execution of the Size
AlterationEvents in the Size Alteration Action List.The command is
terminated if the Automatic Size AlterationState is set Passive.The
order remains after system restart.
3 Examples
3.1 Example 1
SAALI;The Size Alteration Events in the Size Alteration
ActionList are executed.52. Khai BPCs:
1.1 Command /RLBDC:CELL=cell[,CHGR=chgr]+[,NUMREQBPC=numreqbpc]
\ [,NUMREQEGPRSBPC=numreqegprsbpc]
[,NUMREQCS3CS4BPC=numreqcs3cs4bpc] \ [,TN7BCCH=tn7bcch]+; /
1.2 ParametersCELL=cell Cell designation
This is a symbolic name of a defined cell.CHGR=chgr Channel
group number
Numeral 0 - 15 NUMREQBPC=numreqbpc Number of required BPCs
This parameter indicates the number of required Basic Physical
Channels (BPCs) in a channel group. The parameter value must be
specified as a multiple of 8.
-
Numeral 8 - 128
SYSDEF System defined limitNumber of BPCs is defined by the
number of frequencies in the channel group.
NUMREQCS3CS4BPC=numreqcs3cs4bpc Number of required GPRS CS-3 or
CS-4 BPCs
This parameter indicates the number of required BPCs in a
channel group that can support General Packet Radio Service (GPRS)
CS-3 or CS-4.Numeral 0 - 128
NUMREQEGPRSBPC=numreqegprsbpc Number of required EGPRS BPCs
This parameter indicates the number of required BPCs in a
channel group that can support Enhanced General Packet Radio
Service (EGPRS).Numeral 0 - 128
TN7BCCH=tn7bcch TN7 on BCCH frequency
This parameter indicates if Timeslot Number (TN) 7 on the
Broadcast Control Channel (BCCH) frequency can be configured with
Traffic Channels (TCHs) supporting EGPRS or GPRS only.
EGPRS TN7 on the BCCH frequency can be configured with TCHs
supporting EGPRS.
GPRS TN7 on the BCCH frequency can be configured with TCHs
supporting GPRS only.
2 Function
This command defines the number of required BPCs, and how many
of the required BPCs that can support EGPRS or GPRS CS-3 or CS-4.
It also defines if TN7 on the BCCH frequency can be configured with
TCHs supporting EGPRS or GPRS only.
The number of TCHs for a channel group can be calculated by
subtracting the BPCs used for control channels from the number of
required BPCs. If the number of required BPCs is set to system
defined, the number of required BPCs is equivalent to the number of
defined frequencies times eight. An extended range cell only
configures half of the BPCs.
There must be at least one frequency defined per eight number of
required BPCs.
-
It is not allowed to set the number of required BPCs so that the
Stand-alone Dedicated Control Channels (SDCCH/8s) set in command
RLCCC cannot be configured.
The number of SDCCH/8s and the number of required BPCs that can
support EGPRS or GPRS CS-3 or CS-4 cannot exceed the number of
required BPCs in the channel group.
The parameter TN7BCCH is only valid for channel group 0.
If channel groups have been defined for the cell using command
RLDGI, then the CHGR parameter is mandatory.
The command is not valid for external cells, that is, cells
belonging to another Base Station Controller (BSC).
The order remains after system restart.
3 Examples
3.1 Example 1RLBDC:CELL=HLM1,NUMREQBPC=8;
The required number of BPCs for the cell HLM1 is set to 8.
3.2 Example 2RLBDC:CELL=HLM1,CHGR=1,NUMREQBPC=16;
The required number of BPCs in channel group 1 in cell HLM1 is
set to 16.
3.3 Example 3RLBDC:CELL=HLM1,CHGR=1,NUMREQBPC=SYSDEF;
The required number of BPCs in channel group 1 in cell HLM1 is
set to the number of BPCs defined by the number of frequencies in
the channel group.
3.4 Example
4RLBDC:CELL=HLM1,CHGR=1,NUMREQBPC=16,NUMREQCS3CS4BPC=4;
The required number of BPCs in channel group 1 in cell HLM1 is
set to 16. The required number of BPCs that support GPRS CS-3 or
CS-4 in channel group 1 in cell HLM1 is set to 4.
3.5 Example
5RLBDC:CELL=HLM1,CHGR=0,NUMREQBPC=16,NUMREQEGPRSBPC=4,TN7BCCH=EGPRS;
The required number of BPCs in channel group 0 in cell HLM1 is
set to 16. The required number of BPCs that support EGPRS in
channel group 0 in cell HLM1 is set to 4. TN7 on the BCCH frequency
can be configured with TCHs supporting EGPRS.
-
53. L nh dng Tng BPCs:
RLBDC:CELL=cell[,CHGR=chgr]+[,NUMREQBPC=numreqbpc] \
[,NUMREQEGPRSBPC=numreqegprsbpc] [,NUMREQCS3CS4BPC=numreqcs3cs4bpc]
\ [,TN7BCCH=tn7bcch]+; /
1.2 ParametersCELL=cell Cell designation
This is a symbolic name of a defined cell.CHGR=chgr Channel
group number
Numeral 0 - 15 NUMREQBPC=numreqbpc Number of required BPCs
This parameter indicates the number of required Basic Physical
Channels (BPCs) in a channel group. The parameter value must be
specified as a multiple of 8.Numeral 8 - 128
SYSDEF System defined limitNumber of BPCs is defined by the
number of frequencies in the channel group.
NUMREQCS3CS4BPC=numreqcs3cs4bpc Number of required GPRS CS-3 or
CS-4 BPCs
This parameter indicates the number of required BPCs in a
channel group that can support General Packet Radio Service (GPRS)
CS-3 or CS-4.Numeral 0 - 128
NUMREQEGPRSBPC=numreqegprsbpc Number of required EGPRS BPCs
This parameter indicates the number of required BPCs in a
channel group that can support Enhanced General Packet Radio
Service (EGPRS).Numeral 0 - 128
TN7BCCH=tn7bcch TN7 on BCCH frequency
This parameter indicates if Timeslot Number (TN) 7 on the
Broadcast Control Channel (BCCH) frequency can be configured with
Traffic Channels (TCHs) supporting EGPRS or
-
GPRS only.
EGPRS TN7 on the BCCH frequency can be configured with TCHs
supporting EGPRS.
GPRS TN7 on the BCCH frequency can be configured with TCHs
supporting GPRS only.
2 Function
This command defines the number of required BPCs, and how many
of the required BPCs that can support EGPRS or GPRS CS-3 or CS-4.
It also defines if TN7 on the BCCH frequency can be configured with
TCHs supporting EGPRS or GPRS only.
The number of TCHs for a channel group can be calculated by
subtracting the BPCs used for control channels from the number of
required BPCs. If the number of required BPCs is set to system
defined, the number of required BPCs is equivalent to the number of
defined frequencies times eight. An extended range cell only
configures half of the BPCs.There must be at least one frequency
defined per eight number of required BPCs.It is not allowed to set
the number of required BPCs so that the Stand-alone Dedicated
Control Channels (SDCCH/8s) set in command RLCCC cannot be
configured.The number of SDCCH/8s and the number of required BPCs
that can support EGPRS or GPRS CS-3 or CS-4 cannot exceed the
number of required BPCs in the channel group.
The parameter TN7BCCH is only valid for channel group 0.
If channel groups have been defined for the cell using command
RLDGI, then the CHGR parameter is mandatory.
The command is not valid for external cells, that is, cells
belonging to another Base Station Controller (BSC).
The order remains after system restart.
3 Examples
3.1 Example 1RLBDC:CELL=HLM1,NUMREQBPC=8;
The required number of BPCs for the cell HLM1 is set to 8.
3.2 Example 2RLBDC:CELL=HLM1,CHGR=1,NUMREQBPC=16;
The required number of BPCs in channel group 1 in cell HLM1 is
set to 16.
-
3.3 Example 3RLBDC:CELL=HLM1,CHGR=1,NUMREQBPC=SYSDEF;
The required number of BPCs in channel group 1 in cell HLM1 is
set to the number of BPCs defined by the number of frequencies in
the channel group.
3.4 Example
4RLBDC:CELL=HLM1,CHGR=1,NUMREQBPC=16,NUMREQCS3CS4BPC=4;
The required number of BPCs in channel group 1 in cell HLM1 is
set to 16. The required number of BPCs that support GPRS CS-3 or
CS-4 in channel group 1 in cell HLM1 is set to 4.
3.5 Example
5RLBDC:CELL=HLM1,CHGR=0,NUMREQBPC=16,NUMREQEGPRSBPC=4,TN7BCCH=EGPRS;
The required number of BPCs in channel group 0 in cell HLM1 is
set to 16. The required number of BPCs that support EGPRS in
channel group 0 in cell HLM1 is set to 4. TN7 on the BCCH frequency
can be configured with TCHs supporting EGPRS.
54. Li ABIS PATH UNAVAIL: 117. Note:
In this result an ABIS PATH UNAVAIL(khong san co, khong co gia
tri) fault may be received, this fault is also covered(che boi) by
this OPI
Alarm ceasing printout:RADIO X-CEIVER ADMINISTRATION MANAGED
OBJECTS IN TRANSCEIVER GROUP MANUALLY BLOCKED
1.1 CommandRXAPI:MO=mo,DEV=dev...,DCP=dcp...[,RES64K];
1.2 ParametersDCP=dcp Digital connection point number used as
termination point in the Base
Transceiver Station (BTS) for the Abis pathNumeral 0 - 511
DEV=dev Transmission device used for the Abis path
See Application Information for block TRAN for the format and
value range of this parameter.
MO=mo Managed object instance
See Application Information for block RXCTA for the format and
value range of this parameter.
The Managed Object (MO) must be of class Transceiver Group
(TG).RES64K A 64 kbit/s Abis path will be reserved for use by a
suitably configured Time
Slot (TS) only.
-
2 Function
This command is used to define one or more Abis paths between
the Base Station Controller (BSC) and the Base Transceiver Station
(BTS).
Up to 124 Abis paths may be defined per TG. All Abis paths
within a TG must be connected to devices of the same transmission
type. See Application Information for block RBLT for valid
transmission types.
Warning!
The setup of the transmission type must be considered when
defining Abis paths as they may already be used by the transmission
system for control purposes.
The first specified DEV argument is connected to the first
specified DCP argument and the second specified DEV argument is
connected to the second specified DCP argument, etc.
The answer printout RADIO X-CEIVER ADMINISTRATION ABIS PATH
RESULT will show the results of the Abis path definition
request.
The order remains after system restart.
3 Examples
3.1 Example 1RXAPI:MO=RXOTG-1,DEV=RBLT-1,DCP=1;
An Abis path is defined in BTS logical model G12 between the
transmission device RBLT 1 and DCP 1 within TG 1.
3.2 Example
2RXAPI:MO=RXOTG-3,DEV=RBLT-2&&-4,DCP=4&&6;
Abis paths are defined in BTS logical m