Huawei Confidential. All Rights Reserved BSC6800 TNL data configuration ISSUE 1.0
Huawei Confidential. All Rights Reserved
BSC6800 TNL data configuration
ISSUE 1.0
2 Internal Use
ObjectivesObjectives
Upon completion of this course, you will be able to:
Master the principles of data configuration or BSC6800;
Master TNL data configuration of BSC6800
3 Internal Use
ReferencesReferences
《 HUAWEI BSC6800 Operation Manual-Data Configuration》
4 Internal Use
Chapter 1 Basic informationChapter 1 Basic information
Chapter 2 Equipment data configuration
Chapter 3 Iub interface data configuration
Chapter 4 Iu-CS interface data configuration
Chapter 5 Iu-PS interface data configuration
5 Internal Use
Configuration Procedure Configuration Procedure
Start
Equipment dataconf iguration
Interf ace dataconf iguration
Global parameterconf iguration
Cell data conf iguration
End
CBS and SMLCconf iguration
6 Internal Use
Configuration Command Configuration Command
You can carry out the MML commands in two modes on a LMT Batch mode. You may organize multiple MML commands in an
MML command script. This mode is applicable for the initial configuration and mass configuration
One-step mode. You may also input one command at a time and carry it out directly. This mode is applicable for routine configuration and maintenance
Action Meaning
ADD Add an object
SET Set an object
LST Query BAM database configuration information
DSP Query FAM object state or BAM running state
MOD Modify an object
RMV Remove an object
ACT Activate an object
DEA Deactivate an object
RST Reset an object
7 Internal Use
Data Configuration Mode Data Configuration Mode
CMC definition To avoid the data conflict, LMTs and M2000 clients cannot configure
the data at the same time. Through the mechanism of Configuration Management Control (CMC), the BSC6800 controls whether LMT or M2000 has the permission to configure the data at a time
Procedures of obtaining CMC in different cases
If … Then …
M2000 communicates with BSC6800 normally Use the REQ CMCTRL command to request the CMC. If M2000 approves, LMT will get
it.
M2000 cannot communicate with BSC6800 or BSC6800 is not equipped with M2000
Use the FOC CMCTRL command to obtain the CMC forcibly.
8 Internal Use
Data Configuration Mode Data Configuration Mode
Use the LST CMCTRL command to query the CMC Obtaining CMC in different cases
Use the LCK CMCTRL command to lock the CMC Use the ULK CMCTRL command to unlock the CMC
If … Then …
M2000 communicates with BSC6800 normally
Use the REQ CMCTRL command to request the CMC. If M2000 approves, LMT will get it.
M2000 cannot communicate with BSC6800 or BSC6800 is not equipped with M2000
Use the FOC CMCTRL command to obtain the CMC forcibly.
9 Internal Use
Configuration State Configuration State
Offline State In offline state, you will configure data in only the BAM database SET AFLUSH is used to set the flag of updating the .dat files. In o
ffline state, the system determines whether to dynamically update .dat files according to your settings. In online state, the system automatically updates the .dat files
.dat files Boards of FAM
BAM
LMT
Configuration MML commands Database
Loading by resetting
Formatting
10 Internal Use
Configuration State Configuration State
Offline commands of BSC6800 Major commands of the BSC6800 system can run in both online and
offline states. However, the commands in the following Table can run in only the offline state
Offline command Function
ADD RNCBASIC Add BSC6800 basic data
MOD RNCBASIC Change BSC6800 basic data
SET SUBNET Set subnet No.
ADD OPC Add source signalling point
RMV OPC Delete source signalling point
11 Internal Use
Configuration State Configuration State
Online State In online state, you will configure data in both BAM and FAM
databases
.dat files
Boards ofFAM
BAM
LMT
Configuration MML commands
Database
Loading directly
Formatting
12 Internal Use
Data Initialization Data Initialization
The BAM database contains initial settings and LMT configurations. RST DATA will remove all LMT configuration data. After the execution of RST DATA the flag of updating .dat files will be restor
ed to ON and after resetting the system or switch to online mode the configuration status will become online
13 Internal Use
Chapter 1 Basic informationChapter 1 Basic information
Chapter 2 Equipment data configuration
Chapter 3 Iub interface data configuration
Chapter 4 Iu-CS interface data configuration
Chapter 5 Iu-PS interface data configuration
14 Internal Use
Equipment Data Configuration Overview Equipment Data Configuration Overview
RNC equipment data configuration procedure
Start
End
Conf igure sy stem
Conf igure time
Conf igure clock
Conf igure subrack
Conf igure board
15 Internal Use
Configure basic system information carry out SET SYS to configure the RNC system information The basic system information is stored in the BAM database. It
is not sent to FAM
Configure RNC subnet carry out SET SUBNET to configure the RNC internal subnet
No. The default subnet No. is 80
Configure WMPU IP address Carry out SET WMPUIP to configure the IP address for the
WMPU board.
Configuring System
16 Internal Use
Configuring ClockConfiguring Clock
Carry out ADD CLKSRC to add a clock source Carry out SET CLKMODE to configure the clock source
handover strategy
17 Internal Use
Configuring Time Configuring Time
You may apply one of the following as the BSC6800 time: The default time of the BAM Server. You need no time
configuration in this case The time of the operation and maintenance center (OMC).
You need establish communication between BSC6800 and OMC in this case. The OMC acts as a Simple Network Time Protocol (SNTP) Server and the BSC6800 as an SNTP Client. You need configure SNTP Client information for the BSC6800
carry out SET SNTPCLTPARA to configure the SNTP Client information
18 Internal Use
Configuring Time Configuring Time
You may apply one of the following as the time of NodeBs : The local default time. You need no time configuration in this ca
se. The time of the BSC6800.
You need establish an IP Over ATM (IPoA) channel between the NodeB and BSC6800 in this case. The BSC6800 acts as an SNTP Server and the NodeBs as SNTP Clients. You need configure SNTP Server information for the BSC6800
carry out SET SNTPSRVPARA to configure the SNTP Server information
19 Internal Use
Configuring Subrack Configuring Subrack
Subrack numbering rule
WRSS
(2)
WRBS
(5)
WRBS
(8)
WRBS
(11)
WRBS
(14)
WRBS
(17)
BAM
(0)
WRBS
(3)
WRBS
(6)
WRBS
(9)
WRBS
(12)
WRBS
(15)
WRBS
(1)
WRBS
(4)
WRBS
(7)
WRBS
(10)
WRBS
(13)
WRBS
(16)
Cabinet 0 Cabinet 1 Cabinet 2 Cabinet 3 Cabinet 4 Cabinet 5
20 Internal Use
Configuring Subrack Configuring Subrack
Configure active/standby ports
Function Command
Add active/standby port ADD REDPORT
List active/standby port configuration LST REDPORT
Modify standby port MOD REDPORT
Remove active/standby port RMV REDPORT
21 Internal Use
Configuring Subrack Configuring Subrack
Whether to back up the WOSE is dependent on the actual transmission network planning. If [WRBS interface board backup type] is set to ONE_TO_ONE, slot 0 and slot 15 of the WRBS will have an active-standby relation. Hereafter, all data can only be configured to slot 0 (slot 15 will synchronize the data automatically)
A WCDMA RNC Signalling Processing board (WSPU) consists of two subsystems. Subsystem 0 works for the WCDMA RNC radio frame processing boards (WFMRs) in odd-numbered slots. Subsystem 1 works for the WFMRs in even-numbered slots. For sharing between subsystems 0 and 1, you shall balance the WFRMs between the odd-numbered and even-numbered slots.
Function Command
Add WRBS ADD SUBRACK
List subrack LST SUBRACK
Remove WRBS RMV SUBRACK
Modify WRBS MOD SUBRACK
Query board state DSP BRD
Notify board Out-of-position CLR BRD
22 Internal Use
Configuring Subrack Configuring Subrack
Configuring RFN Source Subrack The RFN plays an important role in the radio access network. It
works for coding/decoding between the RNC, NodeBs and UEs.
You shall specify a WRBS as the RFN source subrack carry out SET RFNSRC to configure the RNC source subrack
23 Internal Use
Configuring Board Configuring Board
Configuring Active WHPU carry out SET WHPUAS to configure active WHPUs
Configuring WFSM carry out SET FANSPEED to configure the fan speed adjustme
nt mode
24 Internal Use
Configuring OSPConfiguring OSP
carry out ADD OPC to add an OSP ADD OPC can run in only offline state. To make the
configuration effect, you need reset the system.
25 Internal Use
Chapter 1 Basic informationChapter 1 Basic information
Chapter 2 Equipment data configuration
Chapter 3 Iub interface data configuration
Chapter 4 Iu-CS interface data configuration
Chapter 5 Iu-PS interface data configuration
26 Internal Use
Chapter 3 Iub Interface Data ConfigurationChapter 3 Iub Interface Data Configuration
3.1 Iub Interface Data Configuration
overview
3.2 Iub Interface Data Configuration
MML Commands
3.3 Negotiating data of Iub interface
27 Internal Use
Iub Interface Data Configuration overviewIub Interface Data Configuration overview
28 Internal Use
Iub Interface Data Configuration overviewIub Interface Data Configuration overview
NodeBAAL2Path
RNC
User Plane
NodeBNCP
CCP 1~n RNC
Control Plane ALCAP
Adjnode
29 Internal Use
Iub Physical Connectivity AlternativesIub Physical Connectivity Alternatives
Board Function
WBIE supports ATM over E1/T1 bearer mode. Each board provides 32 E1/T1 ports,
WOSESupporting ATM over E1 over SDH bearer mode. Each (optical) interface board provides 63 E1 ports and 8 E1 electric ports and supports Fractional ATM and CES functions.
WLPUSupporting ATM over SDH bearer mode. Each interface board can support at most 16 STM-1 ports, applicable to high-speed link transmission.
30 Internal Use
Chapter 3 Iub Interface Data ConfigurationChapter 3 Iub Interface Data Configuration
3.1 Iub Interface Data Configuration overvie
w
3.2 Iub Interface Data Configuration
MML Commands
3.3 Negotiating data of Iub interface
31 Internal Use
Iub Interface Data Configuration MML CommandsIub Interface Data Configuration MML Commands
Procedure of Iub configuration Configure Physical Layer Configure ATM Layer Configure SAAL UNI Configure Iub Link Configure Q.AAL2 Configure AAL2 Configure IPoA
32 Internal Use
Configure Physical LayerConfigure Physical Layer
Configure E1/T1 attributes Set E1/T1 link attributes (SET E1T1) Set E1/T1 scramble(SET SCRAMBLE)
Notes: The state of scramble switches between the two ends of
E1/T1 should be set as the same. If several E1/T1s belong to the same IMA group, the state of the switches should be set as the same.
33 Internal Use
Configure Physical LayerConfigure Physical Layer
PHY
PHY
PHY
IMA×éPHY
PHY
PHY
IMA×é
µ¥ATMÐÅÔªÁ÷
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µÍ ËÙÎ ï Àí Á ·
µÍ ËÙÎ ï Àí Á ·
µÍ ËÙÎ ï Àí Á ·
£¨ À ×ÔATM² ã£©Ô ATMÐÅÔªÁ÷£¨ È¥ATM² 㣩
A single ATM cell flow (from the ATM layer)
IMA groupLow-speed physical link
Low-speed physical link
Low-speed physical link
IMA group
The original ATM cell flow (to the ATM layer)
At the Tx end: Cells are allocated to each low-speed physical link in a circular order
At the Rx end: The cells transmitted on each low-speed physical link are reassembled to a single cell group
Inverse multiplexing over ATM (IMA)
34 Internal Use
Configure Physical LayerConfigure Physical Layer
User to Network Interface (UNI)
35 Internal Use
Configure Physical LayerConfigure Physical Layer
The Fractional ATM
36 Internal Use
Configure Physical LayerConfigure Physical Layer
Circuit Emulation Service (CES)
37 Internal Use
Configure Physical LayerConfigure Physical Layer
E1/T1 application configuration when using WBIE/WBIEb
Task Step Operation
Add IMA link1 Use the ADD IMAGRP command to add an IMA group.
2 Use the ADD IMALNK command to add an IMA link to the IMA group. To add more IMA links, repeat this step.
Add UNI link 1 Use the ADD UNILNK command to add a UNI link. To add more UNI links, repeat this step.
Add FRA IMA link
1 Use the ADD IMAGRP command to add an IMA group.
2Use the ADD FRALNK command to add a FRA IMA link to the IMA group. Set the [Board type] to WBIE/WBIEb. Set th
e [Fractional link type] to FRAIMA. To add more FRA IMA links, repeat this step.
3Use the ADD TSCROSS command to add the timeslot cross connection function in the following case: The 2G equipment does not support timeslot cross connection while the FRA IMA link and the E1 link between the 2G
and BSC6800 equipment use different timeslots for transmission.
Add FRA ATM link
1Use the ADD FRALNK command to add a FRA ATM link. Set the [Board type] to WBIE/WBIEb. Set the [Fractional link
type] to FRAATM. To add more FRA ATM links, repeat this step.
2Use the ADD TSCROSS command to add the timeslot cross connection function in the following case: The 2G equipment does not support timeslot cross connection while the FRA ATM link and the E1 link between the 2G
and BSC6800 equipment use different timeslots for transmission.
38 Internal Use
Configure Physical LayerConfigure Physical Layer
E1/T1 application configuration when using WOSE/WOSEb optical port
Task Step Operation
Add IMA link
1 Use the ADD IMAGRP command to add an IMA group.
2Use the ADD IMALNK command to add an IMA link to the IMA group. To add more IMA links, repeat this step.
Add UNI link 1 Use the ADD UNILNK command to add a UNI link. To add more UNI links, repeat this step.
39 Internal Use
Configure Physical LayerConfigure Physical Layer
E1/T1 application configuration when using WOSE/WOSEb electrical port
Task Operation
Add FRA ATM linkUse the ADD FRALNK command to add a FRA ATM link. Set the [Board type] to WOSE/WOSEb. To add more FRA ATM links, repeat this step.
Add SDT CES linkUse the ADD SDTCES command to add an SDT CES link. To add more SDT CES links, repeat this step.
Add UDT CES linkUse the ADD UDTCES command to add a UDT CES link. To add more UDT CES links, repeat this step.
40 Internal Use
Configure Physical LayerConfigure Physical Layer
IMA group and link rules:
RUN
ALMACT
CLK2
E1/T 1
E1/T 1
CLK1
E1/T 1
E1/T 1
RUN
ALMACT
E1/T1
CLK2
CLK1
OPT
0~150~41
16~3142~62
0~7
IMA/UNI/FRAATM/FRA IMA
link No.
IMA/UNIlink No.
IMA group No.
FRA ATM/CESlink No.
0~7
8~15
16~23
24~31
0~31
WBIEWBIEb WOSE/WOSEb
IMA group No.
41 Internal Use
Configure ATM Layer (ADD ATMTRF) In the BSC6800 system, the configuration of ATM PVC attributes
mainly refers to the configuration of ATM traffic resources. After ATM traffic resources configuration is completed, the traffic resources can be directly referenced through [Flow index] during the configuration of SAAL, AAL2 PATH, IPoA.
Configure ATM LayerConfigure ATM LayerConfigure ATM LayerConfigure ATM Layer
42 Internal Use
Configure ATM LayerConfigure ATM Layer
ATM service types
Service typeDescription
Full name Abbreviation
Constant Bit Rate CBR No error check, flow control, and other processing.
Real Time Variable Bit Rate
RT-VBRUsed to describe the service with variable data rates and strict real time
requirement, for example, interactive compressed video such as videoconference.
Non-Real Time Variable Bit Rate
NRT-VBRUsed in timing transmission as E-mail transmission. In such a case,
some delays and variations can be accepted by the application.
Unspecified Bit Rate UBR
No commitment or feedback to congestion. It is suitable for sending IP data. In case of congestion, UBR cells will be discarded. However, neither relevant feedback nor the request for slowing down the transmission speed will be returned to the sender.
The BSC6800 also supports UBR+, which ensures the minimum cell rate.
43 Internal Use
Configure ATM LayerConfigure ATM Layer
ATM traffic descriptions
Parameter
Meaning
Full name Abbreviation
Peak cell rate PCR Max. cell transmission rate
Sustainable cell rate SCR Average cell transmission rate during a long term
Minimum cell rate MCR Min. cell transmission rate
Cell delay variation tolerance CDVT Max. tolerable cell jitter (0.1 s)
Cell loss priority CLPIndicating which cells can be discarded (CLP=1), and which cells had better not be discarded (CLP=0) in the case of network congestion
Tag TAGGING Tagging the cells with CLP=0
44 Internal Use
At least 3 to-NodeB SAAL UNI links should be configured, 1 for NCP, 1 for CCP, and 1 for Q.AAL2.
One WSPUb subsystem can control up to 300 SAAL links. The WRSS can provide other devices with up to 13800 PVCs, includi
ng IPoA PVCs, SAAL links and AAL2 paths
Configure SAAL UNIConfigure SAAL UNI Configure SAAL UNIConfigure SAAL UNI
45 Internal Use
Configure NodeB Configure NCP Configure CCP
Configure Iub portConfigure Iub portConfigure Iub portConfigure Iub port
46 Internal Use
Configure NodeB (ADD NODEB ) NodeB and the corresponding SAAL links (including NCP, CCP and
Q.AAL2) should be configured in the same WSPU subsystem. One WSPUb subsystem can support up to 50 NodeBs and 300 SAA
L links ,One WSPUb subsystem can support up to150 cells.
Configure Iub portConfigure Iub portConfigure Iub portConfigure Iub port
47 Internal Use
Configure NCP(ADD NCP) As NodeB control port, NCP is used to transmit NBAP common pro
cedure messages of the Iub interface. There can be only one NCP in a NodeB, i.e. there exists a one-to-one relationship between NCP and the NodeB.
Notes: The corresponding NodeB should be successfully configured. The SAAL link that accompanies the NCP link should be successfull
y configured and stay in idle status (with the command LST SAALLNK).
The SAAL link should be of UNI type.
Configure Iub portConfigure Iub portConfigure Iub portConfigure Iub port
48 Internal Use
Configure CCP(ADD CCP) As communication control port, CCP is used to transmit NBAP
dedicated procedure messages of the Iub interface. There can be multiple CCPs in a NodeB, i.e. there exists a many-to-one relationship between the CCPs and NodeB.
Notes: To guarantee reliability, you shall configure two or more CCP
links as long as the corresponding SAAL links exist For the same CCP link, its [Port No.] at RNC must be
consistent with that at NodeB, for which the negotiation of RNC with NodeB is needed.
The SAAL link that accompanies the CCP link should be successfully configured and stay in idle status (with the command LST SAALLNK).
The SAAL link should be of UNI type.
Configure Iub portConfigure Iub port
49 Internal Use
Configure Q.AAL2Configure Q.AAL2
Q.AAL2 adjacent node
50 Internal Use
Configure Q.AAL2 adjacent node (ADD AAL2ADJNODE)
Notes: the NodeB corresponding to [NodeB name] must have been configured. It should be noted that NodeBs and adjacent AAL2 nodes of IUB interfac
e are in one-to-one relationship.
Configure Q.AAL2Configure Q.AAL2Configure Q.AAL2Configure Q.AAL2
51 Internal Use
Configure AAL2 PATHConfigure AAL2 PATHConfigure AAL2 PATHConfigure AAL2 PATH
Configure AAL2 PATH Configure AAL2 route
52 Internal Use
The system has the following capability limits for AAL2 path. The BSC6800 can support up to 7360 AAL2 paths. One WSPUb subsystem can control up to 230 AAL2 paths One WBIE/WBIEb can terminate up to 200 AAL2 paths. One WOSE/WOSEb can terminate up to 200 AAL2 paths. One WMUX/WMUXb can terminate up to 60 AAL2 paths. The WRSS can provide other devices with up to 13800 PVCs, including
IPoA PVCs, SAAL links and AAL2 paths
Configure AAL2 PATHConfigure AAL2 PATHConfigure AAL2 PATHConfigure AAL2 PATH
53 Internal Use
Configure AAL2 path ( ADD AAL2PATH ) The adjacent node corresponding to the AAL2 path must have been con
figured (see ADD AAL2ADJNODE). All AAL2 paths of the Iub interface are terminated at WBIE or WOSE . [AAL2 PATH ID] should also be specified to identify the AAL2 path. This
index is to number the AAL2 path of the corresponding adjacent node and should be negotiated with it
Configure AAL2 PATHConfigure AAL2 PATHConfigure AAL2 PATHConfigure AAL2 PATH
54 Internal Use
Configure AAL2 PATHConfigure AAL2 PATH
Configure AAL2 route (ADD AAL2RT) The added AAL2 path can reach the adjacent node, but it might not
reach the destination node . the establishment of an AAL2 route may help it to achieve this object via the other nodes between BSC6800 and the destination node
Even if the destination node is no other than the adjacent node, an AAL2 route is still required
ATM address is used to identify the ATM network node
55 Internal Use
Configure IPoAConfigure IPoAConfigure IPoAConfigure IPoA
56 Internal Use
Configure IPoAConfigure IPoA
Configure IPoA Client (ADD IPOACLIENT)
Configure IPoA PVC(ADD IPOAPVC)
Notes: [IP address] and [Peer IP address] should be in the same subne
t and only one IPoA PVC can exist between them. If [IP address] is for the WMPU, [TX flow index] must be the sa
me as [RX flow index].
57 Internal Use
Configure IPoAConfigure IPoA
Configure IP route Configure BAM route (route add) Configure the IP route of the IPoA path from WMUX to NodeB(ADD
IPRT)
58 Internal Use
Chapter 3 Iub Interface Data ConfigurationChapter 3 Iub Interface Data Configuration
3.1 Iub Interface Data Configuration overvie
w
3.2 Iub Interface Data Configuration
MML Commands
3.3 Negotiating data of Iub interface
59 Internal Use
Negotiating Data of Iub InterfaceNegotiating Data of Iub Interface
Sub itemExample
Negotiation Item
Negotiation data related to PVC:
VPI VCIService
typePCR
(cell/s)Traffic
descriptionCommand
Control plane*
NCP 7 60 CBR 1236 NOCLPNOSCR
ADD ATMTRFADD SAALLNKADD NCP
CCP(with port No. of 1)
7 61 CBR 1236 NOCLPNOSCR
ADD ATMTRFADD SAALLNKADD CCP
Q.AAL2 7 62 CBR 1236 NOCLPNOSCR
ADD ATMTRFADD SAALLNKADD AAL2ADJNODE
User planeAAL2 PATH(with PATH to be negotiated)
9 48 CBR 2473
NOCLPNOSCRCDVT(CDVT102400 s)
ADD ATMTRFADD AAL2PATH
Management plane* IPoA PVC 9 49 CBR 1236 NOCLPNOSCR
ADD ATMTRFADD IPOAPVC
60 Internal Use
Negotiating Data of Iub InterfaceNegotiating Data of Iub Interface
Other negotiation data:
Negotiation item ExampleCommand
Other negotiation items IPoA PVC
BSC6800 ATM Address0x4502030405060708090001020304050607080900NodeB ATM Address0x4507070707070707070707070707070707070707
ADD AAL2RT
IP address & mask
BSC6800 IP Address11.13.1.200, Mask255.255.255.0NodeB IP Address11.13.1.1, Mask255.255.255.0
ADD IPOACLIENTADD IPOAPVCADD IPRT
NodeB local ID* Local CellID0ADD LOCELL
61 Internal Use
Chapter 1 Basic informationChapter 1 Basic information
Chapter 2 Equipment data configuration
Chapter 3 Iub interface data configuration
Chapter 4 Iu-CS interface data configuration
Chapter 5 Iu-PS interface data configuration
62 Internal Use
Chapter 4 Iu-CS Interface Data Chapter 4 Iu-CS Interface Data ConfigurationConfiguration
4.1 Iu-CS Interface Data Configuration overview
4.2 Iu-CS Interface Data Configuration
MML Commands
4.3 Negotiating data of Iu-CS interface
63 Internal Use
Iu-CS Interface Data Configuration overviewIu-CS Interface Data Configuration overview
64 Internal Use
Iu-CS Interface Data Configuration overviewIu-CS Interface Data Configuration overview
Iu-CS interface Board
Board Function
WLPUSupporting the ATM over SDH bearer mode and applicable to high-speed link transmission. Each interface board can support at most 16 STM-1 ports or 4 STM-4 ports.
WBIE supports ATM over E1/T1 bearer mode. Each board provides 32 E1/T1 ports.
WOSESupporting the ATM over E1 over SDH bearer mode. Each interface board provides one 155Mbps optical port.
65 Internal Use
Iu-CS Interface Data Configuration overviewIu-CS Interface Data Configuration overview
OSP
MTP3bLinkSet
MTP3bLink
RNC
DSP1
MSCControl plane
OSPAAL2Path
User plane
DSP1
MSC
AdjNode
66 Internal Use
Chapter 4 Iu-CS Interface Data Chapter 4 Iu-CS Interface Data ConfigurationConfiguration
4.1 Iu-CS Interface Data Configuration overview
4.2 Iu-CS Interface Data Configuration
MML Commands
4.3 Negotiating data of Iu-CS interface
67 Internal Use
Iu-CS Interface Data Configuration MML CommandsIu-CS Interface Data Configuration MML Commands
Procedure of Iu-CS configuration Configure Physical Layer Configure ATM Layer Configure SAAL NNI Configure MTP3-b Configure Q.AAL2 Configure AAL2
68 Internal Use
Configure Physical LayerConfigure Physical Layer
Carry out ADD REDPORT to add an active/standby relationship for the WLPU
69 Internal Use
Configure ATM Layer (ADD ATMTRF) In the BSC6800 system, the configuration of ATM PVC attributes
mainly refers to the configuration of ATM traffic resources. After ATM traffic configuration is completed, the traffic resources can be directly referenced through [Flow index] during the configuration of SAAL, AAL2 PATH, IPoA.
Configure ATM LayerConfigure ATM Layer Configure ATM LayerConfigure ATM Layer
70 Internal Use
See Iub, but when specifying [Interface type] of SAAL, please select "NNI".
Configure SAAL NNIConfigure SAAL NNIConfigure SAAL NNIConfigure SAAL NNI
71 Internal Use
Configure MTP3-bConfigure MTP3-bConfigure MTP3-bConfigure MTP3-b
Adding MTP3B data includes the following: Adding DSP Adding signalling link set Adding signalling link Adding route data
72 Internal Use
Configure MTP3-bConfigure MTP3-bConfigure MTP3-bConfigure MTP3-b
The system has the following limits for MTP3B. The BSC6800 can support up to 608 MTP3B links. One WSPUb subsystem can support up to 50 MTP3B links. The BSC6800 can support up to 76 MTP3B routes
73 Internal Use
Configure MTP3-bConfigure MTP3-bConfigure MTP3-bConfigure MTP3-b
Configure DSP (ADD N7DPC ) The BSC6800 supports six types of DSPs , up to 38 DSPs can be c
onfigured
DSP type Description
IUCSMSC in R99. It has the functions of the control planes of both the radio network layer and
transport network layer on the Iu-CS interface.
IUCS_ALCAPMedia Gateway in R4. It has the functions of the control plane of the transport network lay
er on the Iu-CS interface.
IUCS_RANAPMSC Server in R4. It has the functions of the control plane of the radio network layer on th
e Iu-CS interface.
IUPS Signalling point in the control plane of the Iu-PS interface.
IUR Neighboring RNC
STP Signalling transfer point. The BSC6800 supports up to 2 STP DSPs.
74 Internal Use
Configure MTP3-bConfigure MTP3-bConfigure MTP3-bConfigure MTP3-b
Use the ADD MTP3BLKS command to add an MTP3B signalling link set to the DSP.
Use the ADD MTP3BLNK command to add a signalling link in an MTP3B signalling link set.
Use the ADD MTP3BRT command to add a route to the DSP
[Signalling link selection mask] is used for load sharing of links in a linkset. The result of this value AND the value of [signalling route selection mask] in ADD N7DPC should be 0
Up to 16 signalling links can be added to a signalling linkset
75 Internal Use
See Iub
Configure Q.AAL2Configure Q.AAL2Configure Q.AAL2Configure Q.AAL2
76 Internal Use
Configure AAL2 PathConfigure AAL2 PathConfigure AAL2 PathConfigure AAL2 Path
MSC BSC6800
WSPU subsystem
AAL2 connection 1
AAL2 connection 2
AAL2 connections 3
AAL2 PATH
Configure AAL2 PATH Configure AAL2 route
77 Internal Use
Configure AAL2 PATH See Iub
Configure AAL2 PathConfigure AAL2 PathConfigure AAL2 PathConfigure AAL2 Path
78 Internal Use
Configure AAL2 route see Iub
Configure AAL2 PathConfigure AAL2 PathConfigure AAL2 PathConfigure AAL2 Path
79 Internal Use
Chapter 4 Iu-CS Interface Data Chapter 4 Iu-CS Interface Data ConfigurationConfiguration
4.1 Iu-CS Interface Data Configuration overview
4.2 Iu-CS Interface Data Configuration
MML Commands
4.3 Negotiating data of Iu-CS interface
80 Internal Use
Negotiating data of Iu-CS interfaceNegotiating data of Iu-CS interface Negotiating data of Iu-CS interfaceNegotiating data of Iu-CS interface
项
Sub Item
Negotiation Item
Example
Negotiation data related to PVC
SLC VPI VCIService
typePCR
(cell/s)Traffic
descriptionCommand
Control plane
MTP3-b link 0 10 54 CBR 3708 NOCLPNOSCRADD ATMTRFADD SAALLNKADD MTP3BLNKMTP3-b link 1 10 55 CBR 3708 NOCLPNOSCR
User plane
AAL2 PATH (AAL2 PATH ID is to be negotiated)
None 7 51 CBR 7434
NOCLPNOSCRCDVT(CDVT102400 s)
ADD ATMTRFADD AAL2PATH
81 Internal Use
Negotiating data of Iu-CS interfaceNegotiating data of Iu-CS interface Negotiating data of Iu-CS interfaceNegotiating data of Iu-CS interface
Other negotiation data
Negotiation itemExample
Command
Other negotiation items
ATM address
BSC6800 ATM Address0x4502030405060708090001020304050607080900 MSC ATM Address0x4507070707070707070707070707070707070707
ADD AAL2RT
Signalling point code
BSC6800 SPC0x900 MSC DPC0xaa
ADD N7DPC
82 Internal Use
Chapter 1 Basic informationChapter 1 Basic information
Chapter 2 Equipment data configuration
Chapter 3 Iub interface data configuration
Chapter 4 Iu-CS interface data configuration
Chapter 5 Iu-PS interface data configuration
83 Internal Use
Chapter 5 Iu-PS Interface Data ConfigurationChapter 5 Iu-PS Interface Data Configuration
5.1 Iu-PS Interface Data Configuration
overview
5.2 Iu-PS Interface Data Configuration
MML Commands
5.3 Negotiating data of Iu-PS interface
84 Internal Use
Iu-PS Interface Data Configuration overviewIu-PS Interface Data Configuration overview
85 Internal Use
Chapter 5 Iu-PS Interface Data ConfigurationChapter 5 Iu-PS Interface Data Configuration
5.1 Iu-PS Interface Data Configuration
overview
5.2 Iu-PS Interface Data Configuration
MML Commands
5.3 Negotiating data of Iu-PS interface
86 Internal Use
Iu-PS Interface Data Configuration MML CommandsIu-PS Interface Data Configuration MML Commands
Procedure of Iu-PS configuration Configure Physical Layer Configure ATM Layer Configure SAAL NNI Configure MTP3-b Configure IPoA
87 Internal Use
See Iu-CS
Configure Physical LayerConfigure Physical LayerConfigure Physical LayerConfigure Physical Layer
88 Internal Use
See Iub
Configure ATM LayerConfigure ATM LayerConfigure ATM LayerConfigure ATM Layer
89 Internal Use
See Iu-CS
Configure SAAL NNIConfigure SAAL NNIConfigure SAAL NNIConfigure SAAL NNI
90 Internal Use
See Iu-CS
Configure MTP3-bConfigure MTP3-bConfigure MTP3-bConfigure MTP3-b
91 Internal Use
Configure IPoAConfigure IPoAConfigure IPoAConfigure IPoA
PVC1
Bind PVC to IPoA client
BSC6800
SGSN gateway
IPoA client
WRSSWHPU
WLPU
SGSN gateway IP Destination IP
SGSN
Configure IPoA Client Bind IPoA PVC Configure IP route
92 Internal Use
Configure IPoAConfigure IPoAConfigure IPoAConfigure IPoA
Configure IPoA Client (ADD IPOACLIENT) Each WHPU has two subsystems, numbered 1 and 2. Each sub
system can hold up to 5 IPoA clients. The WHPUs work by sharing the resource pool.
93 Internal Use
Configure IPoAConfigure IPoAConfigure IPoAConfigure IPoA
configureIPoA PVC(ADD IPOAPVC) Each IPoA Client need be configured with 1 IPoA PVC. The Tx traffic index and Rx traffic index of an IPoA PVC must be
the same.
94 Internal Use
Configure IPoAConfigure IPoAConfigure IPoAConfigure IPoA
Configure IP route (ADD IPRT) Each WHPU subsystem need must be configured with IP route
to SGSN.
95 Internal Use
Chapter 5 Iu-PS Interface Data ConfigurationChapter 5 Iu-PS Interface Data Configuration
5.1 Iu-PS Interface Data Configuration overview
5.2 Iu-PS Interface Data Configuration
MML Commands
5.3 Negotiating data of Iu-PS interface
96 Internal Use
Iu-PS Interface ConfigurationIu-PS Interface Configuration Iu-PS Interface ConfigurationIu-PS Interface Configuration
Sub Item
项Example
Negotiation Item商 项
Negotiation data related to PVC
SLC VPI VCIService
typePCR
(cell/.s)Traffic description Command
Control plane MTP3-b link 0 12 50 CBR 3708 NOCLPNOSCR
ADD ATMTRFADD SAALLNKADD MTP3BLNK
User plane
IPoA PVC None 13 60 UBR 351415
NOCLPNOSCRCDVT(CDVT102400 s)
ADD ATMTRFADD IPOAPVC
IPoA PVC None 13 61 UBR 351415
NOCLPNOSCRCDVT(CDVT102400 s)
ADD ATMTRFADD IPOAPVC
97 Internal Use
Iu-PS Interface ConfigurationIu-PS Interface Configuration Iu-PS Interface ConfigurationIu-PS Interface Configuration
Other negotiation data
Negotiation item ExampleCommand
Other negotiation items
IP address and mask
BSC6800 IP Address172.23.10.68, Mask255.255.255.0BSC6800 IP Address172.23.10.69, Mask255.255.255.0SGSN IP Address172.23.5.217, Mask255.255.255.0SGSN Gateway IP Address172.23.10.80, Mask255.255.255.0
ADD IPOACLIENTADD IPOAPVCADD IPRT
Signalling point code
BSC6800 SPC0x900SGSN SPC0x1500 ADD N7DPC
Network mode of operation* NMOMode1 ADD
CNDOMAIN
98 Internal Use