zxur 9000 gsm (v6.50.00) product description
TRANSCRIPT
ZXUR 9000 GSMBase Station ControllerProduct Description
Version: 6.50.00
ZTE CORPORATIONNO. 55, Hi-tech Road South, ShenZhen, P.R.ChinaPostcode: 518057Tel: +86-755-26771900Fax: +86-755-26770801URL: http://ensupport.zte.com.cnE-mail: [email protected]
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Users may visit ZTE technical support website http://ensupport.zte.com.cn to inquire related information.
The ultimate right to interpret this product resides in ZTE CORPORATION.
Revision History
Revision No. Revision Date Revision Reason
R1.0 2011–04–25 First edition
Serial Number: SJ-20101019110320-002
Publishing Date: 2011–04–25(R1.0)
ContentsAbout This Manual ......................................................................................... I
Chapter 1 Product Overview ..................................................................... 1-11.1 Product Context ................................................................................................. 1-1
1.2 Whole Cabinet Appearance ................................................................................ 1-2
1.3 Product Features................................................................................................ 1-2
1.3.1 Advanced System Architecture.................................................................. 1-3
1.3.2 A Software Platform of High Scalability ...................................................... 1-4
1.3.3 Higher Capability for Service Processing ................................................... 1-4
1.3.4 The Carrier-Class Reliability...................................................................... 1-4
1.3.5 Environment-Friendly Design .................................................................... 1-4
1.3.6 More Competitive Evolution Potential ........................................................ 1-4
1.3.7 2G/3G Handover Compatibility .................................................................. 1-4
Chapter 2 Service Functions and Technical Specifications................... 2-12.1 Service Functions............................................................................................... 2-1
2.1.1 Basic Services ......................................................................................... 2-1
2.1.2 Mobility Management ............................................................................... 2-7
2.1.3 Channel Management .............................................................................. 2-8
2.1.4 External Interface ..................................................................................... 2-8
2.1.5 Radio Resource Management................................................................... 2-9
2.1.6 Network Management Functionality ......................................................... 2-10
2.2 Technical Specifications.................................................................................... 2-10
2.2.1 Physical Specifications ........................................................................... 2-10
2.2.2 Power Specifications .............................................................................. 2-10
2.2.3 Backup Configuration ..............................................................................2-11
2.2.4 Environment Requirements......................................................................2-11
2.2.5 Security Specifications............................................................................ 2-13
2.2.6 Interface Specifications........................................................................... 2-13
2.2.7 Capacity Specifications........................................................................... 2-14
2.2.8 Clock Specifications ............................................................................... 2-14
2.2.9 Reliability Specifications ......................................................................... 2-14
Chapter 3 Product Structure ..................................................................... 3-13.1 Logic Structure................................................................................................... 3-1
3.1.1 System Logical Structure .......................................................................... 3-1
I
3.1.2 System Logical Units ................................................................................ 3-1
3.2 Hardware........................................................................................................... 3-3
3.2.1 Cabinet Structure ..................................................................................... 3-3
3.2.2 Subrack Structure .................................................................................... 3-4
3.2.3 Front Boards............................................................................................ 3-6
3.2.4 Rear Boards ............................................................................................ 3-7
3.3 Software ............................................................................................................ 3-9
3.3.1 NE Software and the EMS ........................................................................ 3-9
3.3.2 Classification of NE Software .................................................................. 3-10
Chapter 4 Networking ................................................................................ 4-14.1 Networking via the Abis Interface ........................................................................ 4-1
4.1.1 Star Networking ....................................................................................... 4-1
4.1.2 Chain Networking..................................................................................... 4-1
4.1.3 Ring Networking....................................................................................... 4-2
4.1.4 Star-Chain Hybrid Networking .................................................................. 4-2
4.2 Networking via the A/Gb Interface ....................................................................... 4-3
4.2.1 Networking via the Gb Interface ................................................................ 4-3
4.2.2 Networking via the A Interface................................................................... 4-4
Chapter 5 System Configuration............................................................... 5-15.1 Configuration Description.................................................................................... 5-1
5.2 Board Configuration ........................................................................................... 5-2
5.3 Subrack Configuration ........................................................................................ 5-3
5.3.1 Typical Configuration for Single Service Subrack........................................ 5-3
5.3.2 Typical Configuration for Double Service Subracks..................................... 5-3
5.3.3 Typical Configuration for Triple Service Subracks ....................................... 5-4
5.4 Cabling Configuration ......................................................................................... 5-5
5.5 Configuration of Network Management Software .................................................. 5-6
Chapter 6 Signal Processing Flow............................................................ 6-16.1 Circuit-Switched User Plane Data ....................................................................... 6-1
6.2 Packet-Switched User Plane Data ...................................................................... 6-2
6.3 Control Plane Signaling ..................................................................................... 6-2
6.4 BTS Operation and Maintenance Data................................................................. 6-3
Chapter 7 Reliability ................................................................................... 7-17.1 Hardware Reliability Design ................................................................................ 7-1
7.1.1 Types of Board Backup............................................................................. 7-1
7.1.2 Supported Backup Mode for Different Boards............................................. 7-1
7.2 Software Reliability Design ................................................................................. 7-2
II
7.3 Heat Dissipation Design...................................................................................... 7-3
7.3.1 Introduction to Heat Dissipation................................................................. 7-3
7.3.2 Air Duct for Heat Dissipation ..................................................................... 7-3
Figures............................................................................................................. I
Tables ............................................................................................................ III
Glossary .........................................................................................................V
III
IV
About This ManualPurpose
ZXUR 9000 GSM is a new generation radio network controller (that is, BSC) in the ZTE 2Gmulti-mode series products. It performs functions including system access control, securitymode control, mobility management, and radio resource management and control.
ZXUR 9000 GSM provides all the functions defined in the 3GPP R4/R5/R6/R7 protocols,and offers series standard interfaces including A-interface, Abis interface, and Gbinterface, which enable it to connect with CN, BSC, and BTS. ZXUR 9000 GSM isdeveloped on the basis of ZTE all-IP unified hardware platform. It features a distributeddesign, separating control plane and user plane as well as interface and application. Itsupports TDM/IP dual protocol stack, and can smoothly evolve into all-IP GERAN.
What Is in This Manual
Chapter Description
Chapter 1, Product
Overview
Introduces the context of ZXUR 9000 GSM, the cabinet appearance,
and the features provided.
Chapter 2, Service
Functions and Technical
Specifications
Describes the service functions and technical specifications of the
product.
Chapter 3, Product
Structure
Describes the logical structure, the hardware, and the software of the
product.
Chapter 4, Networking Describes different networking modes with illustrations.
Chapter 5, System
Configuration
Presents three typical configuration scenarios with illustrations.
Chapter 6, Signal
Processing Flow
Illustrates the signal processing flow on the user plane, control plane,
and the BTS operation and maintenance data flow.
Chapter 7, Reliability Presents hardware backup modes and the heat dissipation design.
Intended Audience
Communication engineers
I
II
Chapter 1Product OverviewTable of Contents
Product Context .........................................................................................................1-1Whole Cabinet Appearance........................................................................................1-2Product Features........................................................................................................1-2
1.1 Product ContextZXUR 9000 GSM is part of the GSM/EDGERadio Access Network (GERAN). The GERANincludes one or more Base Station Subsystems (BSSs), each of which is made up of oneBSC and one or more BTSs. The BSC and the BTS are connected via the Abis interface,while the GERAN and the CN are connected via the A/Gb interface.
The network location of ZXUR 9000 GSM (BSC) and its relations with other networkelements are shown in Figure 1-1.
Figure 1-1 The Context of BSC
The external system and interfaces are illustrated in Table 1-1.
Table 1-1 The External System and Interfaces
External System Function Related Interface
BTS Establish the radio environment and
transport data under the control of BSC.
Abis
MSC/MGW Connect BSC with MS to establish radio
voice channel for voice switching.
A
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External System Function Related Interface
SGSN Connect BSC with MS to establish PS
radio channel for data switching.
Gb
1.2 Whole Cabinet AppearanceZXUR 9000 GSM adopts the standard 19-inch cabinet. The whole cabinet appearance isshown in Figure 1-2.
Figure 1-2 ZXUR 9000 GSM Cabinet
1.3 Product FeaturesZXUR 9000 GSM is a radio network controller developed by ZTE according to 3GPP R7.With all functionalities specified by 3GPP R7, the product provides a series of standardinterfaces and supports connectivity with the CNs from different manufacturers. Theproduct features high capacity, high reliability, with high-scalability. It also supports IPGERAN transmission.
l High Scalability
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Chapter 1 Product Overview
ZXUR 9000 GSM is adaptable to service growth and different traffic volumes,providing high-capacity and high-scalability. The resource-processing capacity onboth the user plane and the control plane can be expanded as required.
l High Capacity
ZXUR 9000 GSM is committed to shortening the investment made by customers inthe entire 2G product lifecycle and providing large-capacity one-stop products.
l High Reliability
ZXUR 9000 GSM has high reliability. Backup is supported for all components, withonline software downloading provided.
l High-efficiency Radio Resource Management
ZXUR 9000 GSM supports automatic optimization of radio parameters. Moreover,radio resource priority allocation and scheduling can be performed intelligentlyaccording to the network load and QoS level.
l Flexible Networking
ZXUR 9000 GSM supports Abis interface-based star network, chain network, treenetwork, and ring network. The product is also compatible with transmissions throughthe Ethernet, E1/T1, and optical fibers.
l Variety of Interfaces
The BSC supports TDM/IP, and such physical interfaces as E1/T1, CSTM-1, EthernetFE/GE. These interfaces make flexible networking possible.
The BSC adopts IP-based switching platform. IP-based architecture makes datatransmission highly effective and flexible. Moreover, high performance packet dataprocessing platform ensures the unblocked data switching capability. Comparedto TDM architecture, IP-based switching has the advantages of convenientmaintenance, easy configuration, flexible expansion, highly efficient transmissionwith flexible transmission mechanism. Therefore, it is more adaptable to rapidlydeveloping mobile data services in the future.
1.3.1 Advanced System ArchitectureThe ZXUR 9000 GSM system is based on the ATCA architecture, providing astandard-platform architecture with features like high reliability and maintainability forcarrier-class applications.
The service control unit adopts standard ATCA architecture.
Themedia access unit adds several rear boards to ATCA.With the capacity of original frontboards, the added rear boards can improve the processing capacity with more interfaces.The rear boards can be fully utilized to meet the requirements of relatively large amountof low-speed interfaces for a BSC.
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1.3.2 A Software Platform of High ScalabilityThe system software adopts the Linuxmulti-process architecture. Themiddleware conceptis introduced for restructuring software design to enable a highly cohesive system withloose coupling.
The multi-process architecture ensures the independence of individual processes,separating the errors occurring within one process from others.
1.3.3 Higher Capability for Service ProcessingZXUR 9000 GSM is a highly integrated system with great processing capability, whichprovides the operator with strong competitiveness in the mobile Internet era.
1.3.4 The Carrier-Class ReliabilityZXUR 9000 GSM adopts a modular design that facilitates installation and maintenanceand makes capacity expansion or adjustment flexible. With good strength and rigidity, thecabinet will hardly become loose, deformed, or damaged during installation/uninstallation,storage and transportation. Besides, the cabinet structure has well-designed cooling andgood electromagnetic compatibility (EMC).
1.3.5 Environment-Friendly DesignThe system is designed by observing relevant environment preserving regulations andstandards. The increasing energy tense and ever deteriorating environment have madeenvironment-friendly design and low power consumption important concerns for telecomoperators, who not only take environment preservation a social responsibility and a meansfor reducing cost, but also promote the formulation of relevant regulations and standards.
1.3.6 More Competitive Evolution PotentialZXUR 9000 GSM has more competitive evolution potential, which can be explained by thefollowing features:
l varieties of external interfaces that are compatible with both full-IP requirements andtraditional E1 and TDM access.
l compatible with IPV6l compatible with future development: the media access system considers the
operator's investment benefit in that it is compatible with multi-mode application andthe evolution to 3G.
1.3.7 2G/3G Handover CompatibilityThe ZXUR 9000 GSM system provides handover between 2G and 3G networks in boththe CS domain and PS domain. This feature can reserve the investment in 2G networkand provide 3G handover capability for 2G operators.
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Chapter 2Service Functions andTechnical SpecificationsTable of Contents
Service Functions.......................................................................................................2-1Technical Specifications ...........................................................................................2-10
2.1 Service Functions
2.1.1 Basic ServicesZXUR 9000 GSM supports the service functions of the BSC specified in GSM Phase II+standards, while compatible with GSM Phase II standards. The major functions are listedas follows:
1. Supports GSM900, GSM850, GSM1800 and GSM1900 network.2. Connects with NetNumen M31 via the OMC interfaces for the management of BSS(s).3. Supports various types of services, including
a. Circuit-Switched Voice Servicesl Full Rate (FR) Speech Servicel Enhanced Full Rate Speech Servicel Half Rate (HR) Speech Servicel AMR Speech Service
Adaptive Multirate (AMR) technique is a kind of speech coding algorithm withvariable rates. It can automatically adjust speech coding rate based on C/Ivalue, thus ensuring the best speech quality for different C/I values.
According to relevant protocols, AMR-FR speech coder has 8 rate modes,which are all supported by ZXUR 9000 GSM. ZXUR 9000 GSM also supportsthe five rates for AMR-HR speech coding7.4 kbit/s, 6.7 kbit/s, 5.9 kbit/s, 5.15kbit/s, 4.75 kbit/s .
b. Circuit Switched Data Service at 9.6 kbit/s
c. Short Message Services (SMS) (supporting messages in Chinese)l MS terminated point-to-point short message servicel MS initiated point-to-point short message servicel Cell broadcast service originated from the SMC or the Operation and
Maintenance System
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d. GPRS Service
Supports point-to-point interactive telecom service, such as database access,session service and tele-action service.
e. EDGE Service
4. Supports frequency hopping.5. Supports discontinuous transmission (DTX) and voice activation detection (VAD).6. Supports various handover modes.
Supports synchronous handover, non-synchronous handover andpseudo-synchronous handover.
Supports handover within frequency bands of 900 MHz, 1800 MHz, and between900 MHz and 1800 MHz; it can process handover measurement; supports handovermeasurement before handover; supports network initiated handover due to service orinterference management; supports handover between channels of different speechcoding rates; supports handover for DTX; supports handover caused by trafficreasons; supports cocentric circle handover based on the carrier-to-interference ratio.
7. Supports 6-level static and 15-level dynamic power control for the MS and the BTS,and supports fast power control based on the receiving quality.
8. Supports overload control and traffic control.
ZXUR 9000 GSM can locate and analyze system overload and report the cause to theOMC. When the traffic is heavy, it can control the traffic through the A interface, theAbis interface and the Gb interface by limiting some services, thus keeping the normalsystem running while ensuring maximum call traffic capacity.
9. Supports call re-establishment upon radio link faults.10. ZXUR 9000 GSM supports call queuing and forced call release in the provisioning and
handover programs.11. Supports Enhanced Multi-level Precedence and Preemption (EMLPP).
The EMLPP classifies mobile subscribers into different priority levels. The subscriberswith higher levels are prioritized over others in obtaining channel resources.
12. Supports Co-BCCH.
Co-BCCH is used in dual-band cells. A dual-band cell is a cell that supports twofrequency bands that share the same BCCH.
Co-BCCH has the following advantages:
l Saves a BCCH timeslot.l For the configuration of 1800M frequency in the 900M cell, it is unnecessary to
modify the existing adjacent cells and re-plan the network. The re-selection andhandover is also not required between dual-band cells that share the same site.
13. Supports dynamic HR channel conversion.
ZXUR 9000 GSM supports dynamic HR channel conversion. The system candynamically and automatically switch between HR and FR channels in real timeaccording to the call traffic.
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14. Supports dynamic radio channel assignment.
ZXUR 9000 GSM supports the dynamic assignment of CS and PS channels.
Dynamic channel assignment means that the logic type of radio channels can bedynamically generated according to the current call type, instead of being configuredat the OMM (OMC client). The dynamic radio channel assignment makes it possibleto make the most of radio resources according to the service type.
ZXUR 9000 GSM performs channel allocation according to integrated analysis ofthe channel rate, carrier priority, interference band, channel allocation on intra-cellhandover, allocation of reserved channels, and sub-cell channel selection.
15. Supports voice version selection.
ZXUR 9000 GSM supports voice version selection, which enables the user to set apreferred voice version for FR and HR channels. The FR voice versions include FR,EFR and AMR. The HR voice versions include HR and AMR.
16. Supports three-digit network IDs.
ZXUR 9000 GSM supports three-digit network IDs. Two-digit or three-digit network IDscan be used according to the current network conditions. Based on the network ID,the MNC in the signaling messages received over the A interface and the Gb interfacecan be interpreted, thus determining the MNC format in the signaling messages to besent. The network ID is also the basis for determining the MNC format in broadcastmessages over the Um interface.
17. Supports handover between 2G and 3G systems.l Supports the 3G-to-2G incoming handover for CS services.l Supports the 2G-to-3G outgoing handover for CS services.
18. Supports full dynamic Abis.
Full dynamic Abis means the relation between radio channels and Abis channels isnot generated in the O&M system, but dynamically configured in the service process.Dynamic Abis provides wider bandwidths for data services when the transmissionbandwidth over Abis is fixed.
19. Supports coding control.
Compared with GPRS, EDGE has significantly improvedmeasurement reports. EDGEmeasurement could be performed by pulses, that is, by the granularity of BURST.
The feature of rapid EGPRSmeasurement enables the network side to respond timelyto changes in radio environment, that is, choosing the most proper coding mode andperforming power control.
In the downlink direction, BSC supports the determination of coding modes bytimeslots and by TBF.
In the uplink direction, BSC determines the uplink TFB coding mode based on theuplink channel measurement parameters reported by the BTS.
20. Supports retransmission.
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In the packet services, retransmission is controlled by negative feedback. The TXside determines which packets are not correctly received by the RX side accordingto the bitmaps sent from the RX side, thus deciding whether the network side shouldretransmit the corresponding packets.
In GPRS, packet data is retransmitted using the same coding mode as the firsttransmission. For example, if the packet data was originally transmitted using CS4coding, it will be retransmitted with CS4 code.
EDGE introduces two new retransmission methods: Segmentation and Assembly(SAR) and incremental redundancy.
21. Optimizes the algorithm for packet channel allocation.
ZXUR 9000 GSM supports the multi-timeslot function of MSs, and assigns GPRS TBFor EDGE TBF to MSs according to their capacity of supporting GPRS or EDGE.
ZXUR 9000 GSM chooses low-load carriers first when assigning PDTCHs to the MSs.After the carrier is selected, it chooses the most suitable PDTCH combination in thecarrier according to MS requirements.
22. Supports QoS.
When the GSM network evolves to GERAN, the high-speed transmission of packetdata brought by EDGE enables operators to provide subscribers with lots of colorfulnew services, such as session service, stream media service, and interaction service.ZXUR 9000 GSM supports different QoS requirements for these services.
23. Supports extended uplink Temporary Block Flow (TBF).
Before extended uplink dynamic allocation is introduced into the GPRS, the number ofuplink channels available for the uplink TBF is always less than or equal to the numberof downlink channels occupied by at the same time. However, ZXUR 9000 GSMsupports extended uplink TBF, which can realize more uplink channels than downlinkchannels, thus better meeting the actual service needs.
24. Supports intelligent power-off.
When the performance data reaches the power-on/power-off threshold, ZXUR 9000GSM notifies the BTS to perform power-on/power-off operations through a message.
ZXUR 9000 GSM can combine multiple scattered timeslots to allocate them to theminimum number of carriers possible, and then shut down the unused carriers toreduce power consumption. The scattered timeslots are preferentially combined ontoBCCH carriers.
ZXUR 9000 GSM supports the customization of intelligent shutdown by period toprevent the intelligent shutdown from influencing the network in busy hours.
25. Supports TFO.
Tandem Free Operation (TFO) is an in-band codec negotiation protocol that makescodec negotiation between two Transcoders (TC) after a call is set up. It eliminatesunnecessary voice code conversion at the sending and receiving ends of calls betweenmobile subscribers, thus increasing voice quality and reducing transmission delay.
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26. Supports transparent channel.
The transparent channel implements transparent transfer of data between a timeslotin the E1 line of an interface at one end and another timeslot in the E1 line of anotherinterface at the other end.
ZXUR 9000 GSM supports transparent channels from the Abis interface to the Ainterface, from the Abis interface to the Abis interface, and from the A interface tothe A interface. When remote TC is implemented, transparent channel from the Abisinterface to the Ater interface is supported.
27. Supports EGPRS and GPRS channel scheduling.
Take GPRS mobile phone as an example. First, GPRS preferential channels areassigned to the phone. When EGPRS channels are free andGPRS channels is heavilyloadded, EGPRS channels can be assigned to the phone. Contrarily, when EGPRSchannels have a heavy load and GPRS channels are free, GPRS phones can switchto GPRS channels.
28. Supports the Dual-Transmission Mode (DTM).
ZXUR 9000 GSM supports DTM. Under A/Gb mode, ZXUR 9000 GSM can processCS and PS services at the same time.
29. Supports subscriber signaling tracing.
ZXUR 9000 GSM implements subscriber signaling tracing based on IMSI, TMSI orTLLI.
30. Supports PS paging coordination.
ZXUR 9000 GSM supports PS paging coordination. In packet transmission mode,ZXUR 9000 GSM enables the MSs to intercept circuit paging messages.
31. Supports FLEX A.
When FLEX A is used, a BSC can connect to multiple MSCs, which constitute an MSCPOOL.
FLEX A provides flexible networking. Compared with the traditional single-MSCstructure, the MSC pool has the following advantages:
l Expands the service area of one MSC, and reduces the frequency and traffic ofinter-MSC handover, location area update, and HLR update.
l Improves the efficiency of network equipment. In one MSC Pool, the homingVLR/MSC can be fixed. In this way, the load of an MSC does not increase whenthe traffic in hot spot goes up in a short time.
l Improves the overall disaster recovery capability of the network. When a MSC inthe MSC Pool is faulty, its traffic can be taken over by another MSC in the MSCPool.
The networking method of FLEX A is transparent to the MS, which means that the MSis not involved when networking changes. This guarantees the compatibility of MS inthe network.
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32. Supports FLEX Gb.
FLEX Gb means one BSC can connect multiple SGSNs that form SGSN pools.
FLEX Gb provides flexible networking modes. Compared with the traditionalsingle-SGSN structure, the SGSN pool provides the following advantages:
l Expands the service area of one SGSN, and reduces the frequency and traffic ofinter-SGSN PS handover, routing area update and HLR update.
l Improves the efficiency of network equipment. In an SGSN POOL, the homingVLR/SGSN can be fixed. In this way, the load of an SGSN does not increasewhen the traffic of a hot spot goes up suddenly.
l Improves the overall disaster recovery capability of the network. When a SGSNin the SGSN Pool is faulty, its traffic can be taken over by another SGSN in theSGSN Pool.
For MS, the networking mode of FLEX Gb is transparent, that is, the MS is not involvedin the modification of networking mode. This guarantees the network compatibility withthe MS.
33. Supports preemption and queuing for packet services.
The preemption of packet services considers all dynamic and static packet channelsin assigning packet radio resources according to subscriber QoS requirements. If thefree radio resources on a channel cannot meet QoS requirements or the maximumnumber of subscribers is reached in the channel, and the current subscriber has theright of preemption, the BSC will attempt to forcibly release the radio resources of oneor more low-priority subscribers for the use of the current subscriber.
When the BSC cannot allocate sufficient packet radio resources according tosubscriber QoS requirements, the queuing of packet services allows the BSC to admitservices as many as possible, and then queue them up to wait for radio resourcesthat meet subscriber QoS requirements.
When the BSC supports both preemption and queuing, the preemption of packetservices precedes queuing in priority. Queuing is activated when preemption fails.
34. Supports re-selection of the external network assisted cell.
re-selection of assisted cell in external network accelerates the access speed of theMSduring re-selection of an external cell, shortens the cell re-selection time during datatransmission, increases data transmission rate, thus providing better user experience.
35. Supports network controlled cell re-selection.
Network controlled cell re-selection is a procedure in which the BSC receives themeasurement report from the MS, and then performs storage and weighted averageprocessing of the measured level values of the service cell and the adjacent cells. Thecalculation result is analyzed together with network service load conditions to makecell re-selection decisions.
By fully utilizing available information and making reasonable decisions, the networkcontrolled cell re-selection optimizes network services. The function also reduces
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MS autonomous re-selection of useless cells, thus increasing TBF data transmissionefficiency and providing the best service quality to end users.
36. Supports uplink incremental redundancy.
Incremental redundancy is a method to control the link quality for EDGE. With thismethod, when the BTS successfully decodes the RLC head but fails to decode adata chunk, the BTS stores this data chunk and informs the MS. The MS then usesanother perforation method to encode and retransmit the data chunk so that the BTScan decode the resent data chunk. If decoding fails, the stored data chunk on BTS canbe used together to perform joint decoding. Data chunks using different perforationmethods have different redundant information. Therefore, joint decoding has a highersuccess rate because more redundancy information can be utilized.
37. Supports Multiple PLMN IDs.
ZXUR 9000 GSM supports the radio network sharing among different operators.Operators can configure their own cells on the same site to provide common accessfor subscribers with different operators.
38. Supports noise suppression (only for E1 A interface) and level control.
Noise suppression can increase the voice SNR, enhance voice quality, and provide amore comfortable communication environment.
Level control helps to optimize signal levels, thus improving communication quality.
TFO is exclusive with noise suppression and level control. If the TFO is established,noise suppression and level control are not necessary.
39. Supports higher-order multiple timeslots for PS services.
ZXUR 9000 GSM supports higher-order multiple timeslots for PS services. Thedownlink can have up to five timeslots at the same time, which increases the downlinkrate to 296 Kbps. The increased transmission rate can significantly improve userexperience for FTP transmission and email services.
40. Supports IP transmission for the A interface.
With the evolution of network technology, it is easier to get IP-based transmissionresources. Compared with the traditional circuit network, IP network has a higherutilization rate and more flexible networking modes.
ZXUR 9000 GSM supports IP-based bearing at the A interface, which helps thenetwork evolve to an all-IP network. With this feature, the GSM can be easilyintegrated with the transmission network in the future.
2.1.2 Mobility ManagementZXUR 9000 GSM provides the following mobility management functions:
l Cell Reselection
Supports inter-BSC and intra-BSC cell reselection.
l Cell Handover
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Supports inter-BSC and intra-BSC cell handover.
2.1.3 Channel ManagementZXUR 9000 GSM supports the following channel management functions:
1. Service channel managementl channel assignmentl link monitoringl channel releasel channel blocking/unblockingl channel conversionl function control
2. Supported Control Channelsl FCCHl SCHl BCCHl PCHl AGCHl RACHl SDCCHl SACCHl FACCHl PACCHl PAGCHl PBCCHl PCCCHl PPCHl PRACHl PTCCH
2.1.4 External InterfaceZXUR 9000 GSM supports the following external interfaces:
l Abis Interface
The interface connects the BSC with the BTS. To connect the BTS for configurationand management, the BSC provides the E1/T1 interface, CSTM-1 interface, EthernetFE(electrical port)/GE(optical or electrical port) interface.
l A Interface
The interface connects the BSC with the CN, that is, MSC/MGW. To connect theCN, the BSC provides the E1/T1 interface, CSTM-1 interface, Ethernet FE(electricalport)/GE(optical or electrical port) interface.
l Gb Interface
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The interface connects the BSC with the SGSN. To connect to the SGSN, the BSCprovides the E1/T1 interface, CSTM-1 interface, Ethernet FE(electrical)/GE(optical orelectric) interface.
l OMC Interface
Operations can be performed on the OMC client to control and maintain the BSC andthe BTS.
2.1.5 Radio Resource ManagementThe BSC provides the following radio resource management functions:l System Access Control
System access of a subscriber is initiated at the subscriber side (e.g., mobile caller) orthe network side (e.g., mobile called party). The access of a subscriber is to acquireGSM services through GERAN. GERAN controls the access according to subscribercapability and resources utilization.
l Access Control
The system decides whether to accept user's access request based on such aspectsas current resource utilization, load level, general interference level of the cell, totaltransmission power, and the bandwidth resource of the Abis interface.
l Load Control
When multiple subscribers access to the system, the BSC monitors the system load,determine whether the system is overloaded and, if yes, the overload level. After that,the BSC takes measures according to preset rules to ensure system stability.
l Power Control
Given that the signal quality is ensured, the transmit power is kept at a low level toimprove system capacity.
In the uplink, open loop and closed loop power control are adopted. When theuplink is not established, the open loop power control regulates the transmit powerin the Physical Random Access Channel (PRACH). Closed loop power control isused after the link is established. Closed loop power control includes outer loop andinner loop power control. Outer loop power control adjusts the bit error rate (BER)or frame error rate (FER), while inner loop power control targets adjusts the targetsignal-to-interference rate (SIR).
In the downlink, only closed loop power control is used.
l System Message Broadcast
This function broadcasts the information of the access layer and non-access layer tothe MS for access to the GSM services.
l Radio Environment Measurement
This function measures the present public channels and dedicated channelsaccording to radio resource management requirements.
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l Dynamic Channel Allocation
Dynamic channel allocation includes low-speed channel allocation and high-speedchannel allocation. High-speed channel allocation conforms to the principles specifiedin access control. Low-speed channel allocation allocates radio resources to differentcells according to their service load.
2.1.6 Network Management Functionalityl Configuration Management
Configuration of BSC physical and logical resource, radio parameter configuration,data import/export.
l Security Management
Network security control and operation log management.
l Fault Management
Displays and saves alarm data that reflects equipment faults and threshold-crossingcases.
l Signaling Tracing
Tracing signaling according to specified BTSs, cells, and MSs for fault analysis.
l Performance Statistics
Performs statistics on services and data transmission.
l Diagnosis Testing
Diagnoses system faults.
2.2 Technical Specifications
2.2.1 Physical Specificationsl Dimensions
à Cabinet size: 2200 mm×600 mm×800 mm (height×width×depth)
à Cabinet color: dark blue
à Cabinet structure: three-layer subracks, with 14 slots on both front panel andbackplane
l Cabinet Weight
Maximum weight of a single cabinet: 430 kg
2.2.2 Power SpecificationsThe power specifications of ZXUR 9000 GSM are shown in Table 2-1.
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Table 2-1 Power Specifications
Parameter Specification
Power supply -48 V DC
Allowed power range -40 V DC to -57 V DC
Maximum power consumption 9000 W
2.2.3 Backup ConfigurationAs a measure to improve reliability, ZXUR 9000 GSM provides backup protection for majorboards.
l 1+1 backup for interface boards.l Load sharing for switch boards.l 1+1 backup for control plane processing boards.l Load sharing for user plane processing boards.l The interface boards using the optical fiber and peer-end connection are protected
by inter-board APS to ensure the reliability of high-speed lines, particularly opticalinterface transmission.
2.2.4 Environment Requirements
2.2.4.1 Grounding RequirementZXUR 9000 GSM includes the -48V ground, work ground and protection ground.
l The -48V and -48 VRTN three-channel power supplies enter the cabinet from the top.The -48 VRTN and GND converges outside the cabinet. The protection earth (PE)connects to the earth.
l The rack provides both top grounding and bottom grounding.l Rack bonding resistance ranges from 0.1 to 0.3 ohms, while the ground resistance
should be less than 1 ohm in the equipment room.
2.2.4.2 Temperature and Humidity Requirementsl Temperature and humidity range for stable operation:
à Temperature range
Long-term operation: 0 ℃ to 45 ℃
Short-term operation: -5 ℃ to 50 ℃
à Humidity range
Long-term operation: 5 % to 85 %
Short-term operation: 5 % to 90 %
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Note:
The short-term operation means that the continuous operating period does not exceed96 hours and the accumulative total period within a year does not exceed 15 days.
2.2.4.3 Cleanliness RequirementsThe equipment room must meet the following cleanliness requirements:
l No explosive, conductive, magnetic or corrosive dust.l The thickness of dust particles with larger than 5 um in diameter should be less than
or equal to 3*104 particles/m3.l No corrosive metals or gases that are harmful to insulation.l The equipment room has the capacity to shield some outside electromagnetic
interference.l The rack should be with earthquake-resistance consolidation.l It is permitted that the storage and transportation are with no air-conditioning.
When some of the above requirements cannot be met, the basic requirement is that theequipment room environment resembles the general indoor conditions of different regionsin China.
2.2.4.4 Atmospheric Pressure RequirementsThe atmospheric pressure range for storage: 70 kPa to 106 kPa
The atmospheric pressure range for normal operation: 86 kPa to 106 kPa
2.2.4.5 Electro-Magnetic CompatibilityZXUR 9000 GSM is resistant to electromagnetic interference, conforming torequirements specified in GB/T17618-1998 Information technology equipment–Immunitycharacteristics–Limits and methods of measurement.
ZXUR 9000 GSMThe self-produced electromagnetic interference of the product conformsto requirements of GB9254-1998.
ZXUR 9000 GSMThe EMC specifications of the product conforms to requirementsspecified in EN 300 386 V1.4.1:2008EN 60950–1/A11:2009.
The product has passed the FCC Part 15 certification.
The product has passed the UL certification.
2.2.4.6 Transportation RequirementsThe storage conforms to requirements of GB/T 4798.1. The storage duration should beless than 12 months. Otherwise, the equipment should be tested before operation.
l Temperature requirement for storage: -40 ℃ to +60 ℃
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l Humidity requirement for storage: 10 % to 95 %
With regular packing, the product can endure the shaking and bumping.
2.2.5 Security Specificationsl Optical protection
The optical interface conforms to the requirements of BS EN 60825-2-2000.
l Rack stability
The general symmetry ensures that the rack will not fall down at a tilt table of at least10 degrees. The outer cases of the cabinet and subracks are fixed and can enduregeneral hit.
l Rack security protection
Security protection level should be IP20.
l Electrical leakage
The leak electrical current of this product is less than or equal to 3.5 mA.
l Safety signs
The product has clear enduring safety signs. All indicators, switches, or buttons of theequipment have clear application meanings for different colors.
l Heat resistance and fireproofing
The outer case of the produce is heat-resistant and fireproofing.
l Earthquake resistance
The equipment is safe against 8 magnitude earthquakes.
2.2.6 Interface SpecificationsThe interface boards of ZXUR 9000 GSM are all rear boards. Up to 30 slots are providedfor rear boards. The maximum numbers of supported ports for one slot are listed in Table2-2.
Table 2-2 Maximum Supported Interface Number of One Slot
Interface Type Maximum Number of Ports
CSTM-1 4
E1/T1 32
FE/GE 4
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ZXUR 9000 GSM Product Description
2.2.7 Capacity SpecificationsThe typical single rack configuration involves the following capacity specifications, asshown in Table 2-3.
Table 2-3 Capacity Specifications
Parameter Specification (TDM A interface withbuilt-in TC)
Specification (IP A interface)
Number of racks 1 1
Number of TRX 5600 12250
Number of
Sites/Cells
2800 6125
Erl 33600 73500
BHCA(K) 8400 16800
Maximum Data
Throughput
(Number of
Channels)
19600 MCS9 PDCH 42875 MCS9 PDCH
2.2.8 Clock Specificationsl Clock level: Level 3 Class Al Minimum clock accuracy: ±4.6×10-6l Pull-in range: ±4.6×10-6l Maximum frequency deviation: 2×10 -8 Hz/Dayl Maximum initial frequency deviation: 1×10-8 Hzl Clock working mode: Capture, trace, keep, freel Clock synchronization mode: External clock synchronization, or extracting from the
circuit clockl Clock synchronization interface: 2MBITS(2 MHz, 2 Mbps), GPS, Line Clock
Reference (E1/T1, CSTM-1, Synchronous Ethernet), 1588 V2
2.2.9 Reliability SpecificationsZXUR 9000 GSM has the following reliability specifications shown in Table 2-4.
Table 2-4 Reliability Specifications
Item Specification
MTBF More than 650000 hours
MTTR 30 minutes
Availability 99.99992 %
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Item Specification
System downtime Less than 1 minutes per year for whole system
downtime
Redundancy configuration Board 1+1 backup or load sharing
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Chapter 3Product StructureTable of Contents
Logic Structure ...........................................................................................................3-1Hardware ...................................................................................................................3-3Software.....................................................................................................................3-9
3.1 Logic Structure
3.1.1 System Logical StructureZXUR 9000 GSM has the following logical structure, as shown in Figure 3-1.
Figure 3-1 Logical Structure
• BTS: Base TransceiverStation
• MSC: Mobile SwitchingCenter
• SGSN: Service GPRSSupporting Node
• AU: Access Unit• SU: Switching Unit
• O & M Unit: Operation andMaintenance Unit
• PMU: Peripheral MonitoringUnit
3.1.2 System Logical UnitsZXUR 9000 GSM involves five logical units with different functions. The functions of thefive units and the boards involved are illustrated in Table 3-1.
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Table 3-1 Five Logical Units
Logical Unit Function Boards Involved
Operation and Maintenance
Unit
The unit handles the global
process and the O&M control
at system-level. It also isolates
internal and external network
segments and provides the
global clock.
UMP, ECDM
Access Unit This unit concerns external
interfaces, including Abis, A,
and Gb (E1/T1, CSTM-1, IP). It
implements part of the link layer
processing.
EDTT, ESDTT, ESDTG, ESDTI,
EDTI, EGPB
Processing Unit This unit processes the radio
control-plane and user-plane
protocols and part of the data
bearer protocols related to
transmission.
USP, ETCB
Switching Unit This unit performs intra-shelf
and inter-shelf Layer-2
switching, providing user-plane
and control-plane as switching
planes.
EGBS, EGFS
Peripheral Monitoring Unit This unit belongs to O&M
module and is responsible
for collecting peripheral
information and environment
board information within the
cabinet, including the status
of power distributor and fan,
the environment alarms that
reflect changes in temperature,
humidity, smog, water, and
infrared. The unit raises
system alarms of different
levels according to system
fault grades, thus facilitating
timely handling by equipment
management personnel.
PDUM, PDUB, PDUC, EPCB,
EFMB, NFCM, NFSD, ALB
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3.2 Hardware
3.2.1 Cabinet StructureThe cabinet is made up of the following components:l Cabinet door and rack
à Four doors: Front/rear doors and left-right doors
à Rack: supports the whole cabinet.
l Subracks
à Power Distribution Unit (PDU) (3 U): Located at the top of the cabinet, the PDUprovides power to subracks. The unit can automatically switch between two3-channel outer power sources, with power indicator and environment monitorfunctions.
à ETCA subrack (11 U): The cabinet can admit up to three such subracks.
à Ventilation subrack (5 U): Shared space between subracks. Independent of othersubracks, this subrack changes the air duct from a vertical one to a horizontal one.
l Wind trap component (2 U): traps and converges wind.l Ventilation panel: Dust-proof decoration. One or two such panels for a cabinet.The cabinet structure of ZXUR 9000 GSM is shown in Figure 3-2.
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Figure 3-2 Cabinet Structure
1. Front door2. Side door 13. Rear door4. Side door 25. Rack
6. Power distribution unitPDU7. Ventilation panel1 U8. ETCA subrack11 U9. Wind trap component2 U10. ETCA subrack11 U
11. Ventilation subrack5 U12. ETCA subrack11 U13. Ventilation panel3 U
3.2.2 Subrack StructureThe ETCA subrack includesl Fan unit: Two fan units are located at the front of the cabinet, while one fan unit at the
back.l Service subrack: one subrack component on the front, one on the back of the cabinet,
separated by the backplane.l Power supply unit (Power Distribution Box): two PDUs at the back of the subrack,
supporting four power inputs.l Enhanced Chassis Data Module (ECDA): two modules located on the back of the
subrack, used to manage subrack slots information.
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The ETCA subrack structure is illustrated in Figure 3-3 and Figure 3-4.
Figure 3-3 ETCA Subrack - Front View
1. Fan unit 1 2. Fan unit 2 3. Service subrack
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Figure 3-4 ETCA Subrack - Rear View
1. Fan unit2. Service subrack
3. Power supply unit 14. Power supply unit 2
5. ECDM 16. ECDM 2
3.2.3 Front BoardsThe front boards of ZXUR 9000 GSM processes services, as illustrated in Table 3-2.
Table 3-2 Front Board Functions
FunctionBoard
PhysicalBoard
Function
UMP SBCJ OMM: operation and maintenance of NEs. provides the GE interface
for connecting the EMS.
OMP: Processes the global process and controls the operation and
maintenance of the whole system. It connects the OMM through
the internal media plane. As the processing core of operation and
maintenance, the OMP board directly or indirectly monitors and
manages all boards in the system. It provides an Ethernet interface for
the configuration management of boards and other components.
USP SBCJ CMP: Protocol processing on the control plane at the interfaces Abis,
A, and Gb.
RUP: Protocol processing on the user plane.
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FunctionBoard
PhysicalBoard
Function
ETCB ETCB When the A interface adopts TDM, TC processing is implemented.
The interfaces of boards are illustrated in Table 3-3.
Table 3-3 Board Interfaces
FunctionBoard
Interface Remarks
UMP 2×1G, connects 2 EGBS boards on the back plane,
control plane
2×1G, connects 2 EGFS boards on the back plane,
media plane
1+1 backup
USP 2×1G, connects 2 EGBS boards on the back plane,
control plane
2×1G, connects 2 EGFS boards on the back plane,
media plane
CMP: 1+1 backup
RUP: load sharing
ETCB 2×1G, connects 2 EGBS boards on the back plane,
control plane
2×1G, connects 2 EGFS boards on the back plane,
media plane
load sharing
3.2.4 Rear BoardsZXUR 9000 GSM is configured with the boards illustrated in Table 3-4.
Table 3-4 Rear Boards
Board Function Interface Remarks
EDTT TDM Over E1/T1 at the
interfaces A, Abis, and Ater
2×1G, the back plane connects 2
EGBS boards, control plane
4×1G, the back plane connects 2
EGFS boards, media plane
32×E1/T1
No backup or 1+1
backup
EDTI IP Over E1/T1 at the
interface Abis
TDM Over E1/T1 at the
interface Gb
2×1G, the back plane connects 2
EGBS boards, control plane
4×1G, the back plane connects 2
EGFS boards, media plane
32×E1/T1
No backup or 1+1
backup
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Board Function Interface Remarks
EGPB IP processing at the
GE interface (optical or
electrical)
2×1G, the back plane connects 2
EGBS boards, control plane
4×1G, the back plane connects 2
EGFS boards, media plane
4×1G, external single-mode
Load sharing
1+1 backup
ESDTT TDM Over CSTM–1 at the
interface A
2×1G, the back plane connects 2
EGBS boards, control plane
4×1G, the back plane connects 2
EGFS boards, media plane
1+1 backup
ESDTI IP Over CSTM-1 at the
interfaces Abis
TDM Over CSTM-1 at the
interface Gb
2×1G, the back plane connects 2
EGBS boards, control plane
4×1G, the back plane connects 2
EGFS boards, media plane
1+1 backup
ESDTG TDM Over CSTM-1 at the
interfaces Abis and Ater
2×1G, the back plane connects 2
EGBS boards, control plane
4×1G, the back plane connects 2
EGFS boards, media plane
1+1 backup
EGBS Control plane switching of
the service subrack
Management functions of
the system subrack
Switching:
l 26×1G, the back plane
connects 24 service slots
and the EGFS board, control
plane
l 4×1G, inter-subrack
connection at the control
plane
l 2×10G, peer boards stack
l 1×GE, connecting to the
CMM of the peer board
l 1×GE, connecting to the
clock module of the peer
board
CMM:
l 1×FE, connecting to the
CMM of the peer board
l 1×FE, connecting to the peer
board HUB
l 27×I2C, connecting 26
service slots, the power
supply, fan, and the peer
board
1+1 backup
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Board Function Interface Remarks
EGFS Media plane switching
Clock
Media plane switching:
l 34×1G, the back plane
connects 24 service slots,
14 front interfaces, 20 rear
interfaces, media plane
l 2×1G, connecting to the
control plane of EGBS
l 2×10G, inter-subrack
connection at the media
plane
l 2×10G, active-standby
interconnection
Clock
l 1× antenna port, connecting
to the GPS antenna via cable
l 2× clock input, connecting to
the BITS reference via cable
l 3× clock output, connecting
to other subracks
1+1 backup
PDUM Measuring the temperature
and humidity
Testing power supply
1×485, connecting to the UMP
(OMP) via cable
One board per rack
3.3 Software
3.3.1 NE Software and the EMSThe software architecture includes the NE software and operation and maintenancemodule (OMM) client (or OMC).
1. NE Software
The software runs on the cabinet of ZXUR 9000 GSM, responsible for serviceprocessing.
2. OMM Client
This software is the client of the operation and maintenance module. The clientprovides functions to manage the NEs of the BSS, such as fault management,performance management, and configuration management.
The communication between the ZXUR 9000 GSM equipment and the OMM clientconforms to the TCP/IP protocol.
The software architecture of ZXUR 9000 GSM is shown in Figure 3-5.
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Figure 3-5 Software Architecture
3.3.2 Classification of NE SoftwareThe system software can be divided into two categories.
l Version Software
Version software can be managed on the EMS client. It that can be dynamicallyupdated.
l Firmware
Firmware is a software program written on the hardware chips and cannot be updatedon the EMS client.
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Chapter 4NetworkingTable of Contents
Networking via the Abis Interface ...............................................................................4-1Networking via the A/Gb Interface ..............................................................................4-3
4.1 Networking via the Abis InterfaceZXUR 9000 GSM supports several ways of networking.
According to the network topology, ZXUR 9000 GSM supports the star networking,chain networking, ring networking (requires supported transmission network), and hybridnetworking.
The Abis interface supports following transmission modes: CSTM-1, E1/T1, EthernetGE/FE (optical or electrical).
4.1.1 Star NetworkingThe star networking involving ZXUR 9000 GSM is shown in Figure 4-1.
Figure 4-1 Star Networking
In star networking, ZXUR 9000 GSM connects with BTS directly. This networking issimple, and the maintenance and engineering are very convenient too. Since the signalsare transmitted through fewer intermediate links, the reliability of transmission is higher.Generally, this networking is adopted in densely-populated urban areas.
4.1.2 Chain NetworkingThe chain networking involving ZXUR 9000 GSM is shown in Figure 4-2.
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Figure 4-2 Chain Networking
Chain Networking has relatively more intermediate links, so that the reliability is poorer.Chain networking is usually applied in strip-shaped areas with sparse population, and alarge amount of transmission equipment can be saved.
The chain networking can also be applied in the case of one site having multiple BTSs.
In actual engineering networking, the transmission equipment is generally added betweenZXUR 9000 GSM and BTSs, different from the basic networking, because the sites areoften scattered. The common transmission media include: microwave, fiber cable, HDSLcable, and coaxial cable.
4.1.3 Ring NetworkingThe ring networking involving ZXUR 9000 GSM is shown in Figure 4-3.
Figure 4-3 Ring Networking
The ring networking involves two sets of links running in the active/standby relation. Everynode on the ring has two upper-level nodes, thus improving the link reliability. Therefore,if a site is damaged or a link fails, the subordinate nodes can select another link as theactive one.
4.1.4 Star-Chain Hybrid NetworkingThe star-chain hybrid networking involving ZXUR 9000 GSM is shown in Figure 4-4.
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Chapter 4 Networking
Figure 4-4 Star-Chain Hybrid Networking
The advantages of hybrid networking are:
l Easily adaptable to the current transmission mode of the operator. In earlyestablishment of the network, hybrid networking makes the most of the establishedtransmission network, thus saving the network cost and speeding the networkestablishment for the operator.
l Easier networking on complex terrain. Hybrid networking supports multiple topology,thus making network establishment flexible and simple.
l Easy configuration of abundant transmission paths, thus enhancing the networkrobustness.
4.2 Networking via the A/Gb InterfaceThe A interface connects the BSC with the MSC/MGW.
The Gb interface connects the BSC with the SGSN.
4.2.1 Networking via the Gb InterfaceThe networking via the Gb interface is shown in Figure 4-5.
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Figure 4-5 Networking via the Gb Interface
The Gb interface supports following transmission modes: CSTM-1, E1/T1, and EthernetGE/FE (optical or electrical ports).
4.2.2 Networking via the A InterfaceThe networking with the A interface is shown in Figure 4-6.
Figure 4-6 Networking via the A Interface
The A interface supports following transmission modes: CSTM-1, E1/T1, and EthernetGE/FE (optical or electrical ports).
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Chapter 5System ConfigurationTable of Contents
Configuration Description ...........................................................................................5-1Board Configuration ...................................................................................................5-2Subrack Configuration................................................................................................5-3Cabling Configuration.................................................................................................5-5Configuration of Network Management Software........................................................5-6
5.1 Configuration DescriptionZXUR 9000GSM has three typical application scenarios: single subrack, double subracks,and tri-subrack configuration.
l Single subrack
This configuration means that the BSC is configured with one service subrack.
l Double subracks
The BSC is configured with two service subracks.
l Triple subracks
The BSC is configured with three subracks.
The hardware of this product can be divided into interface resources, system processingresources, and switching resources.
The general system configuration is related to these resources.
Refer to the following list for the configuration:
l Interface board: EGPB, EDTT, ESDTT, ESDTG, EDTI, ESDTIl Control boards: UMP (OMM, OMP)l Processing boards: USP (CMP, RUP), ETCBl Switching boards: EGBS, EGFS
The traffic model contains the following indexes:
l The number of sites/cellsl Traffic volumel Equivalent BHCAl The number of PDCH
The system performance indexes can be calculated from the assuming parameters of thetraffic model and necessary input parameters (for example, the number of cells and thenumber of interfaces). The number of important boards can thus be obtained.
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The number of interface boards is dependent on total traffic of each interface and thenumber of external equipment.
The processing resources on the user plane are the key factor for system configuration.The requirement of processing resources on the user plane can be obtained by collectingtotal system voice traffic and the user-plane board traffic. And then the control-planeprocessing resources can be calculated by data matching based on the user-plane data.
The required amount of system control resources and switch platform resources can becalculated from the amount of the above resources.
5.2 Board ConfigurationThe configuration of front boards is illustrated in Table 5-1.
Table 5-1 Board Configuration List
Board Number of Boards forSingle Subrack
Number of Boards forDouble Subracks
Number of Boards forTriple Subracks
UMP (OMM) 2 2 2
UMP (OMP) 2 2 2
USP (CMP)
USP(RUP)
ETCB
Depending on the
system requirement
and the processing
capacity of the board
Depending on the
system requirement
and the processing
capacity of the board
Depending on the
system requirement
and the processing
capacity of the board
The configuration of rear boards for single-subrack, double-subrack, and triple-subrackscenarios is illustrated in Table 5-2.
Table 5-2 Rear Board Configuration List
Board Number of Boards forSingle Rack
Number of Boards forDouble Racks
Number of Boards forTriple Racks
EGFS 2 4 6
EGBS 2 4 6
Interface board Depending on the
processing capacity of
the interface and the
board, and the backup
configuration
Depending on the
processing capacity of
the interface and the
board, and the backup
configuration
Depending on the
processing capacity of
the interface and the
board, and the backup
configuration
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5.3 Subrack Configuration
5.3.1 Typical Configuration for Single Service SubrackFigure 5-1 lists the typical board configuration for a single-subrack scenario. The type ofthe interface board is decided by the actual networking.
Figure 5-1 Typical Configuration for Single Subrack
5.3.2 Typical Configuration for Double Service SubracksIn the double-subrack scenario, the two subracks are configured as master-subordinatepeers. Figure 5-2 lists the typical board configuration for a double-subrack scenario. Thetype of the interface board is decided by the actual networking.
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Figure 5-2 Typical Configuration for Double Subracks
5.3.3 Typical Configuration for Triple Service SubracksIn the triple-subrack scenario, the three subracks are configured as one master, twosubordinate subracks. Figure 5-3 lists the typical board configuration for a triple-subrackscenario. The type of the interface board is decided by the actual networking.
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Figure 5-3 Typical Configuration for Triple Subracks
5.4 Cabling ConfigurationThe cables inside the rack (single-subrack configuration does not include internal cables)are configured as follows:
l The 10GE optical fiber connects the EGFS board in the master subrack with the sameboard in the subordinate subrack on the media plane.
l The Gigabyte Ethernet (GE) optical fiber connects the EGBS board in the mastersubrack with the same board in the subordinate subrack on the control plane.
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l The clock reference cable connects the clock output on the EFGS board in the mastersubrack to the clock input on the EFGS board in the subordinate subrack.
The cabling outside the rack includes:
l The EGFS board in the master subrack is connected to the BITS clock reference viacable.
l The types of interface boards connect to the external network via the Ethernet cable,optical fiber, or E1 cable.
5.5 Configuration of Network Management SoftwareThe operation and maintenance (O & M) server is installed on the USP (OMM) board,while the client is installed on the PC. The client PC requires the following configurationsillustrated in Table 5-3.
Table 5-3 OMM Client Configuration
Part Suggested Configuration
CPU 2.4Gb, 8-core
Memory 12Gb or more
Hard Disk SAS
CD-ROM Driver Not equipped
Network Port 2*1Gb electrical port
Video adapter Default video adapter
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Chapter 6Signal Processing FlowThe signals in ZXUR 9000 GSM include the clock signal, signaling, the operation andmaintenance signal, and the user plane data. This chapter analyzes the signal processingflows involved. As examples, the Abis interface adopts the IP port, the A interface adoptsthe TDM over CSTM–1, the Gb interface adopts the IP port.
Table of Contents
Circuit-Switched User Plane Data ..............................................................................6-1Packet-Switched User Plane Data .............................................................................6-2Control Plane Signaling .............................................................................................6-2BTS Operation and Maintenance Data .......................................................................6-3
6.1 Circuit-Switched User Plane DataThe CS data flow at the Abis interface starts from the interface board EGPB, and thenflows to the ETCB for transcoding (TC). After that, the data is sent to the A interface boardthrough the IP switching network on the user plane. Through the A interface on the ESDTTboard, the data undergoes the IP-to-TDM conversion, and is sent to the MGW.
The uplink CS data flow on the user plane is illustrated in Figure 6-1 as an example. Thedownlink data flow goes in the opposite direction.
Figure 6-1 CS User Plane Data Flow
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6.2 Packet-Switched User Plane DataThe PS data at the Abis interface starts from the interface on the EGPB, and flows to theRUP board for PS processing according to relevant protocols. After that, the data is sentto the Gb interface on the EGPB before it is sent to the SGSN.
The uplink PS data flow on the user plane is illustrated in Figure 6-2 as an example. Thedownlink data flow goes the opposite way.
Figure 6-2 PS User Plane Data Flow
6.3 Control Plane SignalingControl Plane Signaling at the Abis Interface
The EGPB (Abis interface board) transmits the control plane protocol messages at theAbis interface through the control plane switching network to CMP for protocol processing.
The uplink signaling flow at the Abis interface is illustrated in Figure 6-3 as an example. Thefigure shows the signaling flow between the master subrack and the subordinate subrack.The signaling in the downlink goes in the opposite direction.
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Figure 6-3 Signaling Flow at the Abis Interface
Control Plane Signaling at the A InterfaceThe MTP2 protocol at the A interface is processed on the ESDTT board, while the MTP3and higher protocols are sent to be processed on the CMP via the Ethernet.
The downlink signaling flow at the A interface is illustrated in Figure 6-4 as an example. Thefigure shows the signaling flow between the master subrack and the subordinate subrack.The signaling flow in the uplink goes in the opposite direction.
Figure 6-4 Signaling Flow at the A Interface
6.4 BTS Operation and Maintenance DataThe operation and maintenance data of the BTS is sent from the Abis interface to theinterface board EGPB in the access unit for the physical layer processing. After that, thedata is sent to the EGPB in the master subrack via the switching unit, before it is sent tothe OMM board via the OMM VLAN of the EGPB.
The operation and maintenance data flow of the BTS is illustrated in Figure 6-5.
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Figure 6-5 Flow of the BTS Operation and Maintenance Data
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Chapter 7ReliabilityTable of Contents
Hardware Reliability Design........................................................................................7-1Software Reliability Design.........................................................................................7-2Heat Dissipation Design .............................................................................................7-3
7.1 Hardware Reliability DesignThe rack and service subracks all adopt dual power supplies, so that at leastdouble-channel cables are used inside the rack. The control plane boards adopt theactive/standby working mode, while the user plane boards adopt the load sharing workingmode. The interface boards adopt either the active/standby or the load sharing workingmode. Therefore, the faults of any individual hardware do not affect the normal operationof the system.
7.1.1 Types of Board BackupThe boards in ZXUR 9000 GSM adopt one of the three backup modes: No backup, 1+1backup, and load sharing.
l No Backup
The board has no backup configuration.
l 1+1 Backup
1+1 backup is also called the active/standby backup. Of the two boards asactive-standby peers, only the active board is in operation at a certain time.
If any fault occurs to the active board, the system switches the standby/active relation.The standby board is switched as active, while the active board is switched as standby.
l Load Sharing
Load sharing backs up the service data on the board.
When a service is running, related services are distributed on multiple boards. If anindividual board fails, the service on the failed board can be shared by other boardsto ensure the full operation of the service.
7.1.2 Supported Backup Mode for Different BoardsAt present, the boards equipped with ZXUR 9000 GSM have different backup modes, aslisted in Table 7-1.
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Table 7-1 Board Backup Mode Details
Function Board Supported Backup Mode Description
UMP(OMP/OMM) 1+1 backup The OMP must adopt the 1+1
backup, because this board
performs centralized control
over the whole system.
ETCB Load Sharing -
EDTT No backup, 1+1 backup -
EDTI No backup, 1+1 backup -
ESDTT 1+1 backup -
ESDTI 1+1 backup -
ESDTG 1+1 backup -
EGPB Load sharing, 1+1 backup -
EGBS Load Sharing Provides load sharing upon
occurrence of a fault
EGFS Load Sharing Provides load sharing upon
occurrence of a fault
USP (CMP) 1+1 backup -
USP(RUP) Load Sharing -
Note:
The two boards as active-standby peers may not use two neighboring slots. The slotdistribution is decided by the cabling on the back plane.
7.2 Software Reliability DesignThe system software adopts reliable design. All the system, except the external operationandmaintenance interfaces, has an internal communication network completely separatedfrom the outer network. Besides, the system is equipped with a built-in firewall to protectthe external O & M interfaces against attacks. At the same time, the O & M subsystemsupports high-security authentication design, which enables the authorization of differentlevels of operations to users.
The product has powerful fault tolerance, which can be illustrated by the following aspects:
l Automatic testing for user-defined configurations. Illegal or improper configuration willbe rejected, and the user will be prompted to make proper settings.
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l Supports the backup of the key version or major data as the basis for rollback in thecase of failed loading of a version or relevant data.
l The Watchdog function can restart a board to resume operation when an error occursduring the software operation. Meanwhile, the black box records the runtime errorsfor further analysis.
l During the backup of hardware, the software can automatically test the faults occurringat ports, links, and other faults. If any fault is tested, the software automatically startor activate the standby unit to ensure proper system operation.
7.3 Heat Dissipation Design
7.3.1 Introduction to Heat DissipationThe upper and lower air duct for heat dissipation is formed with the combination of therack with other subracks, including the fan subrack, ventilation subrack, wind trap subrack,and ventilation pannel. The fan-drived ventilation can meet the ventilation and coolingrequirement inside the subracks. The air inlet can be installed with the dustproof screen.
7.3.2 Air Duct for Heat DissipationThe air duct for heat dissipation of ZXUR 9000 GSM is shown in Figure 7-1.
Figure 7-1 Ventilation Subrack Air Flow
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The figure above illustrates the air outlet at the top of the cabinet. The air enters the cabinetfrom under the service subrack horizontally, and turns vertical after flowing through theventilation subrack, bringing heats from inside the cabinet to the outlet above the servicesubrack. This is an efficient way of heat dissipation.
With full configuration, the cabinet has the following air flow for heat dissipation, as shownin Figure 7-2. The air flow of each subrack is explained as follows:
l Power supply unit: bottom-upl Upper service subrack: bottom-upl Middle service subrack: bottom-upl Bottom service subrack: front-to-back
Figure 7-2 Air Flow in the Whole Cabinet
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FiguresFigure 1-1 The Context of BSC................................................................................. 1-1
Figure 1-2 ZXUR 9000 GSM Cabinet........................................................................ 1-2
Figure 3-1 Logical Structure...................................................................................... 3-1
Figure 3-2 Cabinet Structure..................................................................................... 3-4
Figure 3-3 ETCA Subrack - Front View ..................................................................... 3-5
Figure 3-4 ETCA Subrack - Rear View...................................................................... 3-6
Figure 3-5 Software Architecture............................................................................. 3-10
Figure 4-1 Star Networking ....................................................................................... 4-1
Figure 4-2 Chain Networking .................................................................................... 4-2
Figure 4-3 Ring Networking ...................................................................................... 4-2
Figure 4-4 Star-Chain Hybrid Networking.................................................................. 4-3
Figure 4-5 Networking via the Gb Interface ............................................................... 4-4
Figure 4-6 Networking via the A Interface ................................................................. 4-4
Figure 5-1 Typical Configuration for Single Subrack.................................................. 5-3
Figure 5-2 Typical Configuration for Double Subracks............................................... 5-4
Figure 5-3 Typical Configuration for Triple Subracks ................................................. 5-5
Figure 6-1 CS User Plane Data Flow ........................................................................ 6-1
Figure 6-2 PS User Plane Data Flow ........................................................................ 6-2
Figure 6-3 Signaling Flow at the Abis Interface ......................................................... 6-3
Figure 6-4 Signaling Flow at the A Interface.............................................................. 6-3
Figure 6-5 Flow of the BTS Operation and Maintenance Data................................... 6-4
Figure 7-1 Ventilation Subrack Air Flow .................................................................... 7-3
Figure 7-2 Air Flow in the Whole Cabinet .................................................................. 7-4
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Figures
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TablesTable 1-1 The External System and Interfaces .......................................................... 1-1
Table 2-1 Power Specifications ............................................................................... 2-11
Table 2-2 Maximum Supported Interface Number of One Slot................................. 2-13
Table 2-3 Capacity Specifications ........................................................................... 2-14
Table 2-4 Reliability Specifications .......................................................................... 2-14
Table 3-1 Five Logical Units ...................................................................................... 3-2
Table 3-2 Front Board Functions ............................................................................... 3-6
Table 3-3 Board Interfaces ........................................................................................ 3-7
Table 3-4 Rear Boards .............................................................................................. 3-7
Table 5-1 Board Configuration List ............................................................................ 5-2
Table 5-2 Rear Board Configuration List ................................................................... 5-2
Table 5-3 OMM Client Configuration ......................................................................... 5-6
Table 7-1 Board Backup Mode Details ...................................................................... 7-2
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Tables
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Glossary3GPP- 3rd Generation Partnership Project
AMR- Adaptive Multiple Rate
APS- Automatic Protection Switching
ATCA- Advanced Telecommunications Computing Architecture
Abis- Abis Interface between BSC and BTS
BSC- Base Station Controller
BSS- Base Station Subsystem
BTS- Base Transceiver Station
CN- Core Network
CS- Circuit Switched
EDGE- Enhanced Data rates for GSM Evolution
EFR- Enhanced Full Rate
EMC- Electromagnetic Compatibility
FE- Fast Ethernet
FR- Full Rate
GE- Gigabit Ethernet
GERAN- GSM/EDGE Radio Access Network
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ZXUR 9000 GSM Product Description
GSM- Global System for Mobile Communication
HR- Half Rate
IMSI- International Mobile Subscriber Identity
IP- Internet Protocol
MGW- Media GateWay
MS- Mobile Station
MSC- Mobile Switching Center
PS- Packet Switched
QoS- Quality of Service
SGSN- Service GPRS Supporting Node
TBF- Temporary Block Flow
TDM- Time Division Multiplexing
TFO- Tandem Free Operation
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