G_TM_iBSC_R1.0Internal User Only
Purpose of this course
You are expected to know the following knowledge after this
course
Functions, features and specifications of iBSC
Hardware structure, shelves and boards of iBSC
Interface design and logic units of iBSC
Control plane and user plane signal flow of iBSC
Internal cable connection of iBSC
*
Signal Flow on iBSC Control Plane and User Plane
iBSC Internal Cable Connection
intelligent
with only two racks
EFR
All IP hardware architecture
Modular design with good scalar
Separation of control streams from media streams
Supporting Flex A and Flex Gb
Coding scheme: FR/HR/EFR/FR-ARM/HR-AMR
Transmission interface: E1/T1/FE/STM-1
ZXG10 iBSC Product Features
Support 2G/3G inter-operating, co-platform of hardware with 3G
equipments to future network convergence and evolution;
High integration, small footprint and low power consumption;
Max. Traffic reaches 15,000 Erl and Max. transceiver number is 3072
TRX;
Support 900M/1800M dual band networking, EGPRS, and eMLPP;
Large capacity to reduce inter-switches among BSCs and assure
network KPI;
Supports concentric circle and dense frequency multiplexing etc. as
to ensure total coverage and capacity;
Using traffic equalization algorithm like dynamic priority of cell
switching and portfolio switching to assure network quality;
Supports AMR-HR/AMR-FR;
Supports TC POOL to save A interface resources;
Supports dynamic distribution of CS and PS resources to make full
use of Abis interface resources;
BSCplus implements local traffic switching.
*
Universal
Internal User Only
Boards
Different software can be used to define different functions for
the same board.
AIU, BIU, PCU and TCU are logical units; All interface units are in
the resource shelf.
Easy Scalability
3 RCBUs/2 racks.
Internal User Only
iBSC supports multiple access modes
E1/T1
STM-1
FE/GE
Evolution
iBSC
iBSC
iBSC
Advantages
Saves 20% space when 2G and 3G modules are integrated into the same
site.
Shares cabinets, spare parts, transmission and OMM.
Saves power consumption
BSC
BSC
RNC
RNC
3072
2,000 * 800 * 600
Power Consumption
All E1: 2,558W/1 rack, 6,368W/2 rack All IP: 2,542W/1 rack,3,808W/2
rack
Power Source Requirements
Operating Temperature
Long-term temperature: 0°C–40°C. Short-term temperature:
-5°C–45°C.
Operating Humidity:
*
Now, I will introduce ZTE BSC dimensioning principle and result.
First please, please focus on BSC capacity, which is showed in this
table.
Internal User Only
The all-IP architecture conforms to the trend towards an IP-based
network
Large capacity and strong processing capabilities
Supports E1, T1, STM-1 and IP interfaces and flexible networking
modes
ZXG10 iBSC Performance Specifications
E1 Gb: 256Mbps IP Gb: 600Mbps
Maximum TRXs supported
*
Signal Flow on iBSC Control Plane and User Plane
iBSC Internal Cable Connection
A – TDM (E1, STM-1), IP
Gb – TDM (E1), IP
Control shelf (BCTC), resource shelf (BGSN), switch shelf
(BPSN)
Boards
*
*
Work Planes: The iBSC adopts the control and bearer separated
structure. Work planes include the control plane and the user
plane.
Major Interfaces: see the previous introductions.
The iBSC contains four levels of shelves (three shelf types). The
control shelf is in Level 2 and the packet switch shelf is in Level
4. The resource shelf is in Level 1 and Level 3.
The iBSC has 16 physical boards. Some physical boards can provide
different logical functions by loading different logical
drives.
Internal User Only
System operation and maintenance
Internal User Only
ZXG10 iBSC Boards
Level 2 switch of control plane signaling
CMP
Control Main Processor
Control and management of CS and PS services, processing of BSSAP
and BSSGP protocols, and resource management of the system
CHUB
OMP
SBCX
BPSN
GLI
PSN
Packet Switch Network
Provides bi-directional user plane data switch with a capacity of
40 Gbps on each direction
BGSN
SPB2
Signaling Processing Board
Signaling processing, interface board (16 E1 lines for A/Gb, eight
E1 lines for Abis)
GUIM
Giga bit User Interface Module
Level 2 switch between the control plane and the user plane,
resource shelf management
GUP2
GSM Universal Processing
Processing of user plane protocols, such as TC, PCU and RTP
DTB
SDTB2
Provides two STM-1 interfaces
Provides four FE interfaces or one GE interfaces for
Abis/A/Gb
EIPI
*
*
This page introduces the 16 physical boards of iBSC. Boards marked
red can provide different logical functions by loading different
logical drivers.
All boards ending with "2" refer to the second generation. Their
functions are the same as the first generation but the processing
capacity is stronger.
Internal User Only
Physical Board
Logical Board
Functions
GIPI
IPBB
Completes IP access over the Abis interface, and sever the control
plane from the user plane
IPI
Completes IP access over the A interface, and sever the control
plane from the user plane (signaling from service)
IPGB
Completes IP access over the Gb interface, and sever the control
plane from the user plane
GUP2
BIPB2
Search 20 ms TRU frames according to the channels and form IP
packets For IP access over the Abis interface, it also processes
RTP.
AIPB
UPPB2
DRTB2
Completes the transcoding and rate adaptation of TRAU frames, and
provides FR, EFR, AMR and TFO functions
SPB2
LAPD2
GIPB2
Provides Gb interface functions, and processes the FR, NS and
partial BSSGP of GPRS.
*
Internal User Only
Introduction to BCTC
Completes the global operation and maintenance of the system,
provides the global system clock, manages the control plane, and
responsible for the switch between the control plane and the
Ethernet
Each iBSC must be configured with one control shelf, which is
located in Shelf 2 in Rack 1
No.
Internal User Only
BCTC Working Principles
The clock generation board (ICM) distributes clock signals to the
switch shelf and resource shelves through cables.
OMP and SBCX boards are connected to the iOMCR through the hub to
sever intranet segments from Internet segments.
The CHUB acts as the control stream convergence center for the
control streams from the switch shelf, the resource shelf and the
control shelf.
CHUB
CMP
UIMC
OMP
ICM
BCTC
Outside
network
UIMC
BPSN
GUIM
BGSN
8
K
Acts as the Level 2 switch center.
The BGSN is configured in Shelf 1 and Shelf 3 of the main rack.
When a single shelf constitutes an office, it is configured in
Shelf 2.
No.
Internal User Only
BGSN Working Principles
The GUIM board is the convergence and switch center for various
data in the resource shelf. It completes the information exchange
between modules.
The GUIM board interconnects with the GLI board in the packet
switch shelf to carry out level 1 switch between different resource
shelves.
DTBs and SPBs provide E1 interfaces, and SDTBs provide STM-1
access.
GIPI boards provide FE and GE access.
Processes universal services (conversion from TC and TDM to IP
packets, processing of user plane protocols).
Internal User Only
Introduction to BPSN
Interconnects BGSNs and Level 1 switch centers on the user
plane.
Each iBSC should have one BPSN, which is configured in Shelf
4.
If the iBSC has two BGSNs, then the BPSN is not mandatory. However,
this can affect the capacity expansion of the system.
No.
Internal User Only
BPSN Working Principles
The GLI board receives user plane data from the GUIM board.
The PSN provides 40Gbps data switch capacity.
The UIMC receives clock and control signals from the control shelf
and distributes control & management interfaces and clock
signals in the shelf.
Internal User Only
Shelf Configuration (1)
Abis Interface E1
Signal Flow on iBSC Control Plane and User Plane
iBSC Internal Cable Connection
OMP
The OMP board processes the global procedure, performs O&M
related control of the entire system (including O&M proxy), and
connects to the OMM through the 100M Ethernet.
As the processing core of iBSC operation & maintenance, the OMP
board can directly or indirect monitor and manage all boards in the
system. It provides two links (Ethernet interface and RS485) for
configuration management of system boards.
Internal User Only
CPU A is responsible for global operation & maintenance.
CPU B is the Router Processing Unit (RPU).
The HD Disk is a 2G hard disk to store system data, for example,
board software version files, configuration files and logs.
What are the functions of the RPU?
1. Enables intranet addresses within the BSC to communicate with
each other.
2. Provides routes for the operation and maintenance of the
BTS.
RPU 1 BSC 2 iomcrIPAbisomcbOMCB
CMP
The CMP board controls and manages service calls in the PS and CS
fields, and manages the resources of BSSAP, BSSGP and the
system.
Its physical board is MPx86/2, the same as the OMP, but the memory
capacity is slightly different: 1GB/CPU for the OMP, and 2GB/CPU
for the CMP, and the OMP has a hard disk).
Internal User Only
UIMC
The UIMC is responsible for Ethernet Level 2 switch within the BCTC
and the BPSN and the management of the BCTC.
The UIMC provides the clock drive function inside the BCTC and the
BPSN. It inputs 8K and 16M signals, which are sent to different
slots in the BGSN after phase lockup to provide 16M and 8K clocks
for the boards.
The UIMC provides management interfaces for the BCTC and the BPSN;
it also provides board resetting and resetting signal collection
functions for the BCTC and the BPSN.
Internal User Only
UIMC
The UIMC provides one internal GE interface that is connected to
the CHUB.
Internal User Only
CHUB
The CHUB works together with the UIMC/GUIM to be responsible for
control plane data stream exchange and convergence in the
system.
The control plane data from each shelf is sent to the Ethernet
switching unit of CHUB board through the Ethernet cables on the
control plane.
The data is then sent to UIMC board of the BCTC through GE for
level-2 switch, and then distributed to each CMP board for
processing.
Internal User Only
CHUB
The RCHB1 board has three FE buses, on which FE interfaces are
grouped as FE1–8, FE9–16 and FE17–24.
The RCHB2 board has three FE buses, on which FE interfaces are
grouped as FE25–32, FE33–40 and FE41–46.
Internal User Only
ICM
Responsible for system clock supply and external synchronization.
The board extracts clock reference via the A interface and drives
multiple channels of clock reference signals for use by each
interface unit.
It receives GPS satellite signals and extract 1PPS signals and
related TOD messages. The 1PPS signals are used as reference for
phase lockup in order to create PP2S,19.6608MHz and 8 K clock
references for iBSC.
Supports background or manual selection of clock references,
including BITS, line (8 K), GPS, local (Level 2 or Level 3);
supports software shielding of manual switchover.
Supports four work modes: CATCH, TRACE, HOLD and FREE.
Internal User Only
ICM
8 K reference inputwhen DTB/SDTB2 provides the clock reference, it
connects with the 8KOUT/DEBUG-232 interface of RGIM1.When SPB2
provides the clock reference, it connects with the 8KOUT/CPU1-RS232
interface of RSPB.
One CLKOUT interfaces outputs a one-to-six cable; one shelf has two
UIM/GUIM boards with two clock sockets, so one CLKOUT interface can
connect with three shelves. The RCKG1 board has two CLKOUT
interfaces providing six clock output lines, that is , it can
connect with six shelves.
Internal User Only
SBCX
The SBCX board is the server board. It mounts the server on the
rack.
It provides the keyboard, the mouse and the VGA interface.
Uses Sossaman dual-path dual-core CPU with a frequency of 2G
Hz.
Supports multiple operating systems, including Windows
XP/2000/2003, Linux and Solaris.
Provides three FE interfaces, two GE interfaces and one RS232
serial port.
Provides four universal USB interfaces.
Supports boot from hard disk and boot from USB drive.
Internal User Only
SBCX
OMC1(eth3) is set to an external network address to communicate
with NetNumen M31 server.
OMP1(eth6) is set to an intranet address to communicate with the
OMP.
Internal User Only
Provides 32 E1/T1 links for external connections.
Supports extraction of 8K synchronization clock from the lines,
which is transferred to the CLKG/ICM board through the cable as
clock reference.
Supports 120/75 Ω impedance selection for E1 cables, and supports
coaxial cables and twisted-pair cables.
Supports 100 Ω twisted-pair T1 cables.
Internal User Only
S1~S6 S9 S12
Used to set the resistances that match the impedances of different
E1 paths to 75 Ω or 120 Ω.
75 Ω
S7 S8
Used for indicating the receiving matching impedance of
corresponding E1 chip to the CPU.
75 Ω
S10 S11
Used for reporting the long/short wire status of each E1 chip to
the CPU.
SHORT HAUL
S10 S11 DTBDDF
RDTB Jumpers
On the RDTB, the E1 cable works in the 75 Ω unbalanced coaxial
transmission mode by default.
If the E1 line uses 120 Ω balanced transmission mode, the
short-circuit block at X9–X16 on the RDTB needs to be
removed.
The sending end is grounded through the jumper. The receiving end
is connected to a capacitor and then grounded through the jumper.
Jumpers X9–X16 are used to complete such settings.
Internal User Only
Connect E1_TXN-R to the protection ground (Path N)
3-4
Connect E1_RXN-R to the protection ground (Path N)
5-6
Connect E1_TXN+1-R to the protection ground (Path N+1)
7-8
Connect E1_RXN+1-R to the protection ground (Path N+1)
9-10
Connect E1_TXN+2-R to the protection ground (Path N+2)
11-12
Connect E1_RXN+2-R to the protection ground (Path N+2)
13-14
Connect E1_TXN+3-R to the protection ground (Path N+3)
15-16
Connect E1_RXN+3-R to the protection ground (Path N+3)
Internal User Only
SDTB2
The SDTB2 acts as the digital trunk interface board. It provides
two 155M STM-1 standard interfaces.
Supports CAS and CCS, and provides an access processing capacity
equal to 126 E1 lines or 168 T1 lines.
Outputs one path of differential 8 K synchronous clock signals for
the reference of the clock board.
Internal User Only
SPB2
According to its functions, the SPB2 board can be classified into
the LAPD processing board (LAPD2), the signaling processing board
(SPB2) and the Gb interface processing board (GIPB2).
The LAPD2 board processes LAPD signaling. LAPD signaling data from
the BTS are received by the DTB/SPB/SPB2 board, and then switched
to the LAPD2 board through the circuit switching net on the UIM
board in the local resource shelf or the GUIM board in the local
Gigabit resource shelf. The LAPD2 completes the processing of LAPD
signaling data.
The SPB2 board processes MTP2 and X.25 protocols. It supports
extraction of 8 K synchronization clock from the lines, which is
transferred to the CLKG board through the cable as clock
reference.
The GIPB2 board processes the FR, NS and partial BSSGP protocols
for the GPRS, and provides Gb interfaces.
SPB2SPBR8R9
SPB2
Interface unit, which connects with the switching unit and provides
E1 interfaces.
Circuit switch unit, which implements the switching between
interface unit circuits and backplane circuits.
CPU, which implements signaling processing, board management and
internal connection control.
Ethernet Switch Unit, which implements control plane and user plane
data switch and provides FE interfaces.
Clock Unit, which extracts line clock signals and sends them to the
ICM board.
Each SPB2 board contains four CPUs.
Each SPBs board provides 16 E1/T1 interfaces.
SPB24CPUCPU8K16E1
GIPI
The GIPI board provides IP interfaces between iBSC and the BTS, the
SGSN and the MSC/MGW.
Implements Layer 3 protocol interface processing, separates control
plane data from user plane data, and sends the data respectively to
the Ethernet interfaces on the internal control plane and user
plane.
According to functions, GIPI can be classified into four functional
boards:
Abis interface Gigabit IP interface board(IPBB)
A interface Gigabit IP interface board IPAB(Signaling)
A interface Gigabit IP interface board IPI signaling and
service
Gb interface Gigabit IP interface board(IPGB)
TIPB2aTer Interface Process BoardAterTDM/IP20 msTRAUIP
Internal User Only
GIPI
The Interface Unit receives data and sends it to the service
processing unit, which separates user plane data from control plane
data. User plane data is then sent to the GUP2 through the user
plane switch network, and control plane data is sent to the CMP
through the control plane switch network.
The GIPI board can choose RGER (providing one GE interface) or
RMINIC (providing four FE interfaces) as its rear board.
GE2DEBUG1/2-232
Internal User Only
EIPI
The EIPI board provides E1 or T1 based IP connection and works
together with the DTB. It has no external interface and no rear
board. One EIPI works together with two DTBs to provide up to 64 E1
or T1 ports.
TIPB2aTer Interface Process BoardAterTDM/IP20 msTRAUIP
Internal User Only
EIPI
The interface unit receives HW data and sends it to the HPS
daughter card. The data is then processed according to the HDLC
protocol and then sent to the service processing unit. It sends
user plane data through the user plane switch network to the GUP2
for processing, and sends control plane data through the control
plane switch network to the CMP for processing.
Internal User Only
GUIM
The GUIM performs Ethernet Level 2 switching between the control
plane and the user plane in the Gigabit resource shelf, the CS
field timeslot multiplexing slot switching and Gigabit resource
shelf management. It also provides external interfaces for the
Gigabit resource shelf.
It has the capability of 16 K circuit switching, and provides an
internal circuit switching network for the GE resource shelf.
It provides the clock drive in the resource shelf. It inputsPP2S,
8K and 16M signals, which are sent to different slots in the
resource shelf after phase lockup to provide 16M, 8 K and PP2S
clocks for resource modules in this shelf.
The UGIM board performs Gigabit resource shelf management and
provides RS485 management interfaces in the Gigabit resource shelf;
It also provides board resetting and in-slot signal collection
functions.
Internal User Only
GUP2
According to functions, GUP2 boards are classified into five
functional boards: Abis interface processing board BIPB2, A
interface processing board AIPB, user plane processing board UPPB2,
dual rate transfer board DRTB2 and Ater interface processing board
TIPB2.
Over the STM-1 or E1 Abis interface, CS and PS services from the
BTS are switched to the BIPB2 board through the UIM board in the
local resource shelf or the GUIM board in the local Gigabit
resource shelf. The BIPB2 board searches 20ms TRU frames or PCU
frames and form them into IP packets, which are sent to the TCU or
the UPU for processing. Over the IP Abis interface, the BIPB2 board
is also used to process RTP.
The DRTB2 implements code conversion, finishes TRAU frame
conversion and rate adaptation, and provides FR/EFR/HR/AMR/TFO
function.
The AIPB board processes RTP and forms data into IP packets over
the A interface.
The UPPB2 processes user plane protocols such as BSSGP, PDCP and
GTP_U under the A/Gb mode.
The TIPB2 processes user plane data of the Ater interface.
TIPB2aTer Interface Process BoardAterTDM/IP20 msTRAUIP
Internal User Only
a. CPU
FE
b.
GUP2
CPU: responsible for board management, and provides control plane
FE interfaces for external connection.
DSP: processes universal services, including functions of BIPB2,
AIPB, DRTB2, UPPB2 and TIPB2.
Circuit Switch Unit: connects the serial ports of multiple-chip DSP
with the circuit switching network.
Ethernet Switch Unit: implements the Ethernet connections for
multiple-chip DSP and provides the user plane FE interface for
external devices.
Clock Unit: provides necessary clock signals for the units on the
board.
a. CPU
FE
b.
GLI
The GB Line Interface (GLI) board is located at level 1 switching
subsystem of iBSC. It finishes physical layer adaptation, IP
package query, segmentation, forwarding, and flow management
functions, processes bi-directional 2.5Gbps forwarding, and
implements the interfaces to different resource shelves and
external interface functions.
Internal User Only
GLI
Interface Unit: provides GE optical interface and supports physical
backup. SD1–SD2, SD3–SD4, SD5–SD6 and SD7–SD8 are backup
groups.
Processing Unit: implements bi-directional IP packet table look-up,
fragmenting, forwarding and traffic management.
Queue Management Unit: implements bi-directional queue
management.
The GE optical interface receives user plane data from the GUIM and
sends it through the backplane to the PSN board for user plane data
exchange.
Internal User Only
PSN
Provides bi-directional user plane data switch with a capacity of
40 Gbps on each direction
The data from each GLI board is sent to the Matrix Switching Unit
through the high-speed serial links on the backplane. It is
switched and then sent to the destination GLI board.
Internal User Only
Includes the PWRD board and the alarm box
PWRD is responsible for collecting some peripheral and environment
board information within the cabinet, including the power
distributor and fan status as well as some environment alarms like
temperature/humidity, smog, water and infrared alarms. Each cabinet
has one PWRD board.
The Alarm Box (ALB) can report system alarms at different levels
according to system fault grades to facilitate timely interference
and handling by equipment management personnel.
Internal User Only
Board Summary 1
Serdes: parallel-to-serial and serial-to-parallel converter.
The User Plane FE interface of SPB2 is used to transmit user plane
data when the SPB2 serves as the GIPB2 board.
Internal User Only
Board Summary 2
Internal User Only
Active/Standby Board Design
Key boards have 1+1 backup.
Key interface boards such as GIPI and SDTB can have 1+1 backup if
necessary.
Front board and rear board
Rear boards are passive boards that provides cabling from the
backplane (such as E1 and network cables) in order to work together
with corresponding front boards.
Front boards are physical boards that process resources. All system
optical cables are led from the front board panels.
All front boards have four indicators on their panels (RUN, ENUM,
ACT, ALM) to indicate board status.
Internal User Only
ALM
Red
Alarm indicator
Flashing at 5 Hz: version download fails; board self test fails
because of inconsistency between board and configuration
ENUM
Yellow
Board extraction indicator
Solid on: the microswitch is opened; the board is not in position;
or version files are not downloaded.
Flashing at 5 Hz (quickly): the microswitch generates an alarm
because it is opened when the board is still running.
Flashing at 1 Hz (slowly): the board can be extracted. The
microswitch is opened when the board is running, and the board is
in standby mode or release the resource.
Solid off: the microswitch is normal.
ACT
Green
Internal User Only
Signal Flow on iBSC Control Plane and User Plane
iBSC Internal Cable Connection
*
Logical units of iBSC include: Access Unit(BIU GIU AIU), Switch
Unit, CMPU, UPU, TCU, O&MU, PMU
Internal User Only
SDRGIPI,OMCB?
OMCBSDROMMOMMiBSC,SBCXGSMOMCB
MR Measurement ReportMR ServerGIPIMR
Internal User Only
E1 Abis
Internal User Only
BIU - E1 Abis
*
The E1 Abis-interface unit consists of the DTB, the GUP and the
SPB.
1. The DTB completes E1 access.
2. LAPD signaling from the BTS is switched to the SPB through the
GUIM board in the local resource shelf. The SPB processes LAPD
signaling.
3. CS and PS services are switched to the GUP board through the
GUIM board in the local resource shelf. The GUP board finds 20ms
TRU frames or PCU frames according to channel search,and forms
these frames into IP packets that are sent to the TCU or UPU for
processing.
Internal User Only
BIU - IP Abis
*
The IP Abis interface unit is composed of the GGIPI board and the
GUP board.
1. As the interface board, the GIPI board receives IP packets from
the BTS through the external Ethernet interface, and
differentiates
user plane data from control plane data.
UDP data is sent through the user plane switch network to the GUP
for processing.
SCTP data is sent through the control plane switch network to the
CMP for processing.
2. On the uplink direction, the GUP divides the IP packet payload
that are composed based on carriers according to the channel,and
searches the 20ms TRU frames or PCU frames in each channel. It then
forms these frames into IP packets that are sent to the TCU(UPU)
for processing. The downlink direction is just opposite.
Internal User Only
BIU - IPoE Abis
Internal User Only
E1 A
7SPBE1SPBCPU MTP2IP CMPDTB/SDTBUIMTSPB
Internal User Only
AIU - IP A
*
The IP A interface unit is composed of GIPI boards and GUP
boards.
1. The GIPI board completes IP access, and separates user plane
data from control plane data.
UDP data is sent through the user plane switch network to the GUP
for processing.
SCTP data is sent through the control plane switch network to the
CMP for processing.
2. The GUP processes RTP and sends the processing result to the BIU
through the GUIM.
Internal User Only
E1 Gb
The E1 Gb interface unit consists of SPBs.
The SPB completes E1 access, processes FR protocol, and separates
the user plane from the control plane for some data. It sends
user plane data through the user plane switch network to the GUP
for processing, and sends control plane data through the control
plane switch network to the CMP for processing.
Internal User Only
GIU - IP Gb
*
The IP Gb interface unit consists of CIPI boards. The GIPI board
completes IP access, and separates user plane data from control
plane data.
UDP data is sent through the user plane switch network to the GUP
for processing.
For SCTP data, some is sent through the control plane switch
network to the CMP for processing, and some is sent through the
user plane switch network to the GUP for processing.
Internal User Only
O&M Unit
Operation and Maintenance Networking
The networking mode of SBCX is as follows: iBSC OMP board (OMC2
port) and SBCX (omp1 port) form a subnet. The SBCX (omc1 port),
OMM/EMS Client and EMS Server form a subnet. The local OMM usually
consists of the SBCX (OMM Server), the OMM Client (PC).
When the iBSC needs to manage SDR BTSs, the OMCB server manages all
SDR configurations (physical, transmission and radio
configurations), links, alarms and versions. The OMCB program is
installed on the SBCX and a pair of GIPI boards must be
configured.
Internal User Only
Monitoring Unit - PMU
The PWRD board collects the environment monitoring information of
peripheral devices, including temperature and humidity, smoke,
water and infrared alarms.
Internal User Only
Internal User Only
IP Switch Unit (PSU)
Level 1 switch: GLI and PSN, 40G large-capacity user plane data
switch.
Level 2 switch: UIMU,GUIM, UIMC, and CHUB, responsible for the
switch and convergence of control plane and user plane data in the
system.
Internal User Only
IP Switch Unit (PSU)
If there are only two resource shelves, the Level-1 switch
subsystem is not needed on the user plane. The two resource shelves
can be directly interconnected using Gigabit optical
interfaces.
Internal User Only
Signal Flow on iBSC Control Plane and User Plane
iBSC Internal Cable Connection
User Plane Signal Flow in the CS Domain
The BIU severs user plane data from control plane data, and then
sends user plane data to the TCU, which processes such data and
then sends it to the AIU. Signal flow 1→2.
Internal User Only
User Plane Signal Flow in the PS Domain
The BIU severs CPU frames from all frames and sends them to the
UPU(UPPB2) through the user plane switching network. The UPU then
separates PS field user plane data from CPU frames received for
further processing. After data processing is complete, the data is
sent to the GIU through the user plane switching network.
Internal User Only
Control Plane Signal Flow in the CS Domain
Abis interface signal flow Abis interface unit (BIU) sends
signaling in the LAPD channel to the CMP board as control plane
data. The CMP processes such data and sends some of it directly
back to the BIU (flow direction: 1→1). Some signaling data will be
sent to the AIU in the form of A-interface signaling flow (flow
direction: 1→2).
A-interface signal flow: The AIU processes the MTP2 part of
A-interface signaling, and then sends it to the CMP to complete the
processing of MTP3 and layers above. Some global processes need the
participation of the OMP. The data flow direction is 2→3→3→2 or
2→2.
Internal User Only
Control Plane Signal Flow in the PS Domain
For some control plane signaling in the PS field, the system
requests resources from the CMP board, and then sends the signaling
to the UPPB2 for processing.
When the MS is processing PS services, control plane signaling
should be separated from UPPB2 and then sent to the CMP for
processing.
Internal User Only
Abis interface signaling flow
The Abis interface unit sent (BIU) sent control plane data in the
LAPD channel to the CMP board. The CMP processes such data, such as
the immediate assignment message, and sends it directly back to the
BIU (flow direction: 1→1). Some data, such as the packet assignment
message, are sent to the UPU, which processes then and send them to
the BIU through the user plane switching network (flow direction::
1→3→2).
Data from the Abis interface unit are sent to the UPU through the
user plane switching network. The UPU processes the data and
separates control signaling packets, which are sent to the control
plane processing board (CMP). The data flow direction is:
2→3→3→2
Internal User Only
Gb interface signaling flow
The GIU sends BVC channel data as control plane data to the active
CMP. The CMP processes the data and sends some of it (such as PTP
BVC restart) to other CMPs and some (such as signaling BVC restart)
to the OMP. The CMP or the OMP processes the data and some
signaling generates the Abis signaling traffic, such as paging
messages in the PS or CS field, whose data flow is 5→1 or 5→3→2;
other signaling, such as PTP BVC restart acknowledgement and
signaling BVC restart acknowledgement, is sent to the Gb interface
through the GUI, with the data flow as 5→5 or 6→6.
The GUI routes data from other BVC channels to the user plane
processing unit, which separates control plane data and sends it to
the CMP. The CMP processes the data and some signaling, such as PTP
paging messages, is sent to the Gb interface through the GIU with
the data flow as 4→3→5; some signaling generates the Abis signaling
flow, such as location messages, with the data flow as 4→3→1.
Internal User Only
E1 AbisE1 A
The BIU severs user plane data from control plane data, and then
sends user plane data to the TCU, which processes such data and
then sends it to the AIU.
Internal User Only
E1 AbisE1 A
The Abis interface unit (BIU) sends signaling in the LAPD channel
to the CMP board as control plane data. The CMP processes such data
and sends some of it generates the A interface signaling flow to
the AIU.
Internal User Only
IP AbisIP A
The BIU severs user plane data from control plane data, and then
sends user plane data to the TCU, which processes such data and
then sends it to the AIU.
Internal User Only
IP AbisIP A
The Abis interface unit (BIU) sends signaling in the LAPD channel
to the CMP board as control plane data. The CMP processes such data
and sends some of it generates the A interface signaling flow to
the AIU.
Internal User Only
E1 AbisE1 Gb
The BIU severs CPU frames from all frames and sends them to the
UPU(UPPB) through the user plane switching network. The UPU then
separates PS field user plane data from CPU frames received for
further processing. After data processing is complete, the data is
sent to the GUI through the user plane switching network.
Internal User Only
E1 AbisE1 Gb
The Abis interface unit (BIU) sends control plane data in the LAPD
channel to the CMP board. The CMP processes such data and sends
some of it to the UPU (such as packet assignment message). The UPU
processes such data and then sends it to the BIU through the user
plane switch network.
Internal User Only
E1 AbisE1 Gb
The GIU sends BVC channel data as control plane data to the main
CMP. The CMP processes the data and some signaling generates the
Abis signaling flow, such as paging messages in the CS field
Internal User Only
IP Abis IP Gb
The BIU severs PCU frames from all frames and sends them to the
UPU(UPPBs) through the user plane switching network. The UPU then
separates PS field user plane data from CPU frames received for
further processing. After data processing is complete, the data is
sent to the GUI through the user plane switching network.
Internal User Only
IP Abis IP Gb
The Abis interface unit (BIU) sends control plane data in the LAPD
channel to the CMP board. The CMP processes such data and sends
some of it to the UPU (such as packet assignment message). The UPU
processes such data and then sends it to the BIU through the user
plane switch network.
Internal User Only
IP Abis IP Gb
The GIU sends BVC channel data as control plane data to the main
CMP. The CMP processes the data and some signaling generates the
Abis signaling flow, such as paging messages in the PS or CS
field
Internal User Only
Signal Flow on iBSC Control Plane and User Plane
iBSC Internal Cable Connection
Internal User Only
System Interconnection Modes
Most boards are managed by the OMP via the internal control
plane.
The CLKG/ICM board are connected to the UIMC via the RS485 bus, and
then managed by the OMP.
*
BPSN
System Clock Capture and Distribution Principles
The CLK board is responsible for supplying clock signals and
external synchronization functions.
Clock level: Level 3 clock
The board extracts clock reference via A Iu interface and drives
multiple channels of timing reference signals for use by each
interface shelf after intra-board synchronization.
Level 2 forwarding of the UIM board
DTB, SDTB2 and SPB2 can be used to extract line reference
The BPSN does not need a clock reference
8K2M
Control plane and Ethernet interconnection cables;
User plane optical cable connection;
Monitoring cable.
8K2M
Clock Extraction and Distribution Cables
The clock extraction cable connects the 8KOUT interface on the DTB
rear board to the 8KIN interface on the ICM.
The ICM can also extract GPS signals as the clock reference.
The clock distribution cables connect the CLKOUT interface on the
ICM rear board to the CLKIN interfaces on UIM boards in each
shelf.
To use the clock reference of the A interface, please extract it
from the 1st E1 of the A interface.
Internal User Only
Control Plane and Ethernet Interconnection Cables
The FE interfaces of the CHUB rear boards connect to the FE
interfaces of the UIM boards in each shelf.
Internal GE connection is used inside the BCTC.
Internal User Only
User Plane Optical Cable Connection
The optical interface on the GUIM front panel in the BGSN connects
to the optical interface on the PLI front panel.
Supports physical backup.
Internal User Only
Monitoring Cables
The cables between fans to PWRD boards are usually 120 ohm
twisted-pair cables that are connected to the FANBOX interfaces to
monitor fan running status.
The environment monitoring sensor is connected to the SENSORS
interface on the PWRD board to collect environment alarms.
The door access sensor is connected to the DOOR interface on the
PWRD board to monitor door access status.
The PWRD board reports monitoring information to the OMP board via
RS485 cables.
Internal User Only
Oscillastor
RS232
GPS
2Mbps/2MHz
PP2S/16CHIP
RS232
CP FE 1~6