Introduction to UMTS ISSUE 1.0
Huawei Confidential. All Rights Reserved
object
Upon completion of this course, you will be able to:
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Understand the communications
history
of
3G
mobile
Understand the UMTS network architecture and 3GPP different releases
Understand the UMTS network services
Understand the basic principles of UTRAN
Internal Use
References
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TS 21.102 3rd Generation Mobile System Release 4 Specifications TS 21.103 3rd Generation Mobile System Release 5 Specifications Huawei’s UMTS RAN protocols and signaling analysis document
Internal Use
Part 1 Introduction to UMTS Part 2 UTRAN basic principles Part 3 ATM basic principles
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Internal Use
Part 1 Introduction to UMTS Section 1 History of 3G Section 2 UMTS network structure Section 3 UMTS network services
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Internal Use
Development of Mobile communication
1st Generation 1980s (analog)
GSM
AMPS TACS NMT OTHERS
2nd Generation 1990s (digital)
Analog to Digital
CDMA IS95 DAMPS PDC
AMPS = Advanced Mobile phone service TACS=Total Access Communications Systems NMT=Nordic Mobile Telephone
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3rd Generation current (digital)
WCDMA FDD
Voice to Broadband
CDMA 2000 WCDMA TDD
GSM=Global system for Mobile Communications D-AMPS=Digital-AMPS PDC=personal digital cellular
Internal Use
History of 3G
At 1985 : ITU started the process of defining the standard for third generation systems, referred to as International Mobile Telecommunications 2000 (IMT2000) Some of the features that IMT-2000 3G network must include 1-Circuit and packet oriented services 2-Simultaneous multiple services 3-Symmetrical and Asymmetrical services 4-Migration path from 2G systems 5-Supporting Multimedia services Car speed environment: 144kbps Walk speed environment: 384kbps Indoor environment: 2048kbps
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1992: 230MHz spectrum was allocated in 2GHz band (WARC92)
Internal Use
History of 3G
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Based on the IMT-200 performance objectives and frequency allocation the ITU-R formally requested a submission of RTT proposals with a closing date at the end of July 1998 . By the closing date , there were a total of 10 RTT proposals were submitted from Europe , United states , Japan , Korea and, China. All these proposal where accepted . Five RTT for IMT2000 • WCDMA FDD • CDMA2000 (1X-EV-DO and 3X modes) • WCDMA-TDD • UWC-136 (based on D-AMPS) • DECT Only three 3G network implemented and currently deployed 1-CDMA 2000 (1X-EV-DO) 2-WCDMA FDD (UMTS FDD) 3-WCDMA TDD (UMTS TDD)
Internal Use
3G standardization organizations
Standardization organizations such as 3GPP, 3GPP2 were established
WCDMA 3GPP
CDMA2000
3G system
3GPP2
FDD/TDD mode
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Internal Use
Frequency allocation for IMT2000 WARC in 1992 230MHz in 2GHZ Band was allocated to IMT2000 IMT-2000 1800
1900
2000
1885
ITU
1980
IMT-2000 1895 1918
Japan
2100
2010 2025
MSS MSS (Reg.2)
1980
2010 2025
PHS IMT-2000 MSS IMT-2000
Europe/ Australia USA
IMT-2000
1880 1900 1920
DECT 185 0
1980 2010 2025
UMTS
MSS UMTS
PCS
Unlicensed
2110
1990
2155 2170
MSS MSS IMT-2000 (Reg.2) 2110
2170
IMT-2000 MSS 2110
2170
UMTS 2110
1910 193 0
2200MHz
2150 2165
2025
MSS
MSS
Reserve
MSS
MSS: Mobile Satellite Service 10
Internal Use
Frequency allocation for IMT2000
Additional (2nd of June, 2000)
WRC2000 Conference has decided to allocate additional bands for IMT-2000, 800MHz, 1.8GHz, and 2.5GHz Band. 2010
800
IMT-2000 GSM (Current) PDC (Current)
1000 960
806
2000 2025
1500 1710
1885 1980
810
960
958
1710
1429
MHz 2690
211 0 880
2500
2170
1990
1513
: Additionally assigned for IMT-2000 11
Internal Use
UMTS FDD and TDD
FDD (Frequency Division Duplex) pL U r o f : f1
ink
Link n w o D f 2: for Mobile Terminal
Base station
TDD (Time Division Duplex) f 1: for
U
Link n w o p&D
TS TS Up Down
Mobile Terminal
Base station
TS: Time slot 12
Internal Use
Summary
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IMT-2000 is the ITU standard for 3G mobile communications three 3G networks are implemented and currently deployed 1-CDMA 2000 (1X-EV-DO) 2-WCDMA FDD (UMTS FDD) 3-WCDMA TDD (UMTS TDD) 3GPP is responsible for producing UMTS network standard specifications 3GPP2 is responsible for producing CDMA2000 network standard specifications
Internal Use
Part 1 Introduction to UMTS Section 1 History of 3G Section 2 UMTS network structure Section 3 UMTS network services
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Internal Use
3GPP R99 network Architecture
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Internal Use
3GPP R99 network Architecture
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Interoperability with GSM CS domain elements are able to handle 2G and 3G subscribers. Changes (upgrades) in MSC/VLR and HLR/AC/EIR. For example SGSN 2G responsible for mobility management (MM) for packet connections 3G MM divided between RNC and SGSN
Internal Use
3GPP R4 network Architecture
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Internal Use
3GPP R4 network Architecture
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The 3GPP R4 introduces separation of the connection, its control, and services for CS domain of CN. Media Gateway (MGW): an element for maintaining the connection and performing switching function when required. MSC server: an element controlling MGW and responsible for signaling Packet switched voice The CS call is changed to the packet switched call in MGW.
Internal Use
Difference between R99 and R4 CS domain evolution SCP
HLR
SCP
HLR
MAP Over TDM
MSC
TUP/ISUP TDM
MAP Over TDM/IP
MSC
MSC Server
ATM/IP/TDM
MSC Server
ATM/IP
MGW
RAN
RAN
RAN
RAN
R99
ATM/IP
RAN
MGW
RAN
R4
Notes: PS domain structure remain unchanged
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Internal Use
3GPP R5 network architecture
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Internal Use
3GPP R5 network architecture
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3GPP R5 introduces the High Speed Downlink Packet Access (HSDPA) The HSDPA scheme proposes to add an additional wideband downlink shared channel that is optimized for very high-speed data transfer In HSDPA the coding and modulation scheme used are changed according to air interface conditions Release 5 employs two modulation schemes, QPSK and 16QAM. Later releases may introduce other schemes, such as 64QAM 3GPP R5 introduces a IP Multimedia subsystem (IMS)
Internal Use
Summary
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3GPP R99 is the first 3GPP specification for UMTS based on GSM NSS as a CN R4 softswitch based CS Core network was introduced in 3GPP R4 HSDPA and IMS are introduced in 3GPP R5
Internal Use
Part 1 Introduction to UMTS Section 1 History of 3G Section 2 UMTS network structure Section 3 UMTS network services
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Internal Use
QoS of Different Services Quality (BER)
conversational
streaming
interactive
background
Time delay
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Internal Use
UMTS services
Conversational Services Speech service: Real time conversational service require the low time delay from end to end , and the uplink and the downlink service bandwidth is symmetrical . Adopt AMR ( adaptive multi rate ) technique (WCDMA).
– 12.2, 10.2, 7.95, 7.40, 6.70, 5.90, 5.15 and 4.75kbps. – The bit rate of AMR voice can be controlled by the RAN according to the payload of air interface and the quality of voice service .
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Video phone (WCDMA) The requirement of time delay is similar to the voice service The CS connection :adopt ITU-T Rec.H.324M (AMR-H.263) The PS connection :adopt IETF SIP or H.323
Internal Use
UMTS services
Streaming Services (eg. Telemetry (monitoring) , Audio and Video streaming )
Interactive Services (eg. Web browsing , and online games ) Background Services (eg. Email , Fax , and SMS )
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Internal Use
Summary
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Internal Use
Part 1 Introduction to UMTS Part 2 UTRAN basic principles Part 3 ATM basic principles
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Internal Use
Multiple Access Techniques CDMA Power Tim
e
e Fr
cy en u q
Traffic channels: different users are assigned unique code and transmitted over the same frequency band, for example, WCDMA and CDMA2000
TDMA Power Tim e
FDMA Power
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Us e U Us ser r Us e r Us e r er
Us er Tim
Fre
e
n ue q e Fr
cy
cy en u q
Traffic channels: different time slots are allocated to different users, for example, DAMPS and GSM
Traffic channels: different frequency bands are allocated to different users,for example, AMPS and TACS Internal Use
Multiple Access Techniques
Advantage FDMA
1. Simple Implementation
AMPS, TACS
Defect Defect 1. Frequency Reuse 2. privacy
1.Privacy
1. Need synchronized of frame
CDMA
1. Reduction the interference
IS95, W-CDMA
2. Diversity Hand-over
1. Sophisticated power control for mobile
TDMA GSM, PDC
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3. Privacy
Internal Use
Multiple Access Techniques
FDMA/TDMA
f 1 f 7
f 5 7 f 6 f 2
f 6 7 f 3 f 4 f 5
f 1 6 f 2 f 1 f 7 f 3
f 4 f 5 f 6 f 2
f 7 f 3 f 4
CDMA
f 2 f 1
f 1 f f 51 f f 6 1 f 1
f 1 f 1 f 1
f 1 f 1
Frequency is different in each sector.
Frequency is same.
Need for
No need for frequency plan
frequency plan (Frequency Reuse) Reuse 31
f 1 f 1
f f 1 f f f 1 f f 2 1 71 f 1 f f 1 1 f f f 41 f 1 f 71 1 f 1
Internal Use
DS-CDMA
Narrow Band Spreading Signal Code 1 A
(Multiple Signal)
Despreading
(Receiver A)
Code 2 B
A
User-A (Receiver B)
Code 2 B
De-spreading Code
User-B Code 3
Narrow Band Signal
Code 1
C B A
User-A
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Wide Band Signal
User-B (Receiver C)
Code 3
C
C
User-C
User-C Internal Use
Rake Receiver
C B
A
B
A
Rake 33
A
B
C
C
Internal Use
Rake receiver RAKE Receiver Finger Circuit RX
Combiner
Finger Circuit
Combined Signal
Finger Circuit Calculation Calculation
Searcher Electric Power
Electric Power
Output Power
Multiple Signal 1 Multiple Signal 2 Multiple Signal 3 Delay Time
Delay Time
Delay Profile 34
Internal Use
WCDMA handover types
Soft Handover
UE is connected simultaneously to more than one base station (up to 3 sectors) using the same frequency The UE receives the downlink transmissions of two or more base stations. For this purpose it has to employ one of its RAKE receiver fingers for each received signal. in the uplink direction , the code channel of the mobile station is received from both base stations, but the received data is then routed to the RNC for combining The RNC selects the better frame between the two possible candidates based on frame reliability indicator
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Internal Use
WCDMA handover types
Softer Handover
UE is connected simultaneously to two sectors of one base station using the same frequency The UE receives the downlink transmissions the two sectors. For this purpose it has to employ one of its RAKE receiver fingers for each received signal. in the uplink direction , the code channel of the mobile station is received in each sector, then routed to the same baseband Rake receiver and the maximal ratio combined there in the usual way.
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Internal Use
WCDMA handover types
Hard Handover
The UE stops transmission on one frequency before it moves to another frequency and starts transmitting again During Hard Handover the used radio frequency (RF) of the UE changes
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Internal Use
WCDMA handover types
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Inter-system Handover Handover between two different radio access technologies Handover between UMTS FDD and GSM Handover between UMTS FDD and UMTS TDD
Internal Use
Spreading process in WCDMA
Coding & Interleaving
3,840 Kcps Channelization Code
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Σ
Scrambling Code
1st Step: Channelization Variable Rate Spreading ( According to user data rate) 2nd Step: Scrambling Code Fixed Rate Spreading (3,840 Kchips)
Internal Use
Spreading process in WCDMA
Downlink (NodeB to UE ) Scrambling Code: Identifies cell (sector). Channelization Code: Identifies user channels in cell (Sector).
Scrambling Code A Scrambling Code B Channelization Channelization Code 2 Channelization Code 3 Code 1 Channelization Code 1 Channelization Code 1 Channelization Code 2 40
Channelization Code 2
Scrambling Code C Internal Use
Spreading process in WCDMA
Up Link (UE to NodeB ) Scrambling Code: Identifies user terminal. Channelization Code: Identifies channels in user terminal.
Channelization Code 2 Channelization Code 1
Scrambling Code A Channelization Code 1
Scrambling Code B
Channelization Code 1
Scrambling Code C
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Internal Use
Spreading process in WCDMA
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Orthogonal Variable Spreading Factor [OVSF] codes are the channelization codes used for signal spreading in the uplink and downlink
Internal Use
Spreading process in WCDMA
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The code used for scrambling of the uplink Channels may be of either long or short type, There are 224 long and 224 short uplink scrambling codes. Uplink scrambling codes are assigned by higher layers. For downlink physical channels, a total of 218 -1 = 262,143 scrambling codes can be generated. Only scrambling codes k = 0, 1, …, 8191 are used. In the downlink direction 512 of scrambling codes are used to identify the cells in the downlink so downlink planning is required
Internal Use
W-CDMA (IMT-DS) Specification
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Multiple access method
DS-CDMA (DS: Direct Spread)
Duplexing method
FDD/TDD (Frequency Division Duplex/Time Division Duplex)
Inter-cell synchronization
Asynchronous
Bandwidth
5 MHZ
Chip rate
3.84 Mcps
Carrier spacing
Flexible with 100/200kHz carrier raster
Frame length Unit
10 ms
Data modulation
Downlink: QPSK, Uplink: BPSK
Multi-rate concept
Variable spreading factor and/or multi-code
Maximum data rate
2 Mbps (indoor)/384 kbps (mobile)
Channel coding
Convolutional coding (R=1/3 or 1/2, K=9) Turbo code for High data rate
BPSK: Binary phase shift keying
QPSK: Quadrature phase shift keying
Internal Use
UMTS FDD frequency allocations
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Operating Band
UL Frequencies UE transmit, Node B receive
DL frequencies UE receive, Node B transmit
I
1920 – 1980 MHz
2110 –2170 MHz
II
1850 –1910 MHz
1930 –1990 MHz
III
1710-1785 MHz
1805-1880 MHz
IV
1710-1755 MHz
2110-2155 MHz
V
824 – 849 MHz
869-894 MHz
VI
830-840 MHz
875-885 MHz
Operating Band
TX-RX frequency separation
I
190 MHz
II
80 MHz.
III
95 MHz.
IV
400 MHz
V
45 MHz
VI
45 MHz
Internal Use
Summary
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UMTS is based on DS-CDMA as a multiple access technique Rack receiver is used to combine signals and get benefits from Multipath fading . Also it is used to combine signals in soft and softer handover cases Two types of Power control are used in UMTS , open and closed loop power control Types of handover in UMTS Soft handover Softer handover Hard handover Inter-system handover Spreading process in WCDMA consists of two stages Channelization Scrambling
Internal Use
Part 1 Introduction to UMTS Part 2 UTRAN basic principles Part 3 ATM basic principles
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Internal Use
Why do we need a new technology?
To provide a high-speed, low
delay
multiplexing and switching network to any
type of
user traffic, such as voice support, data,or video applications.
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Internal Use
Traditional Switch Model’s Characteristic
Circuit Switching Data is sent from the same route, so time delay is fixed
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High-speed switching Fixed rate Packet Switching Support multi-rate switching Take full advantage of bandwidth/waste of bandwidth Time delay is not fixed
Internal Use
What is ATM? ATM
for Telecommunications is Asynchronous Transfer Mode, (not Automatic Teller Machine!). In general, ATM means that traffic is carried in small, fixed-length packets called cells. A technology that integrates advantages of circuit switch and packet switch. ATM can support any type of user services, such as voice, data, or video service.
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Internal Use
ATM can provides both CBR and VBR transport
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Internal Use
ATM Overview
5-Bytes Header
48-Bytes Payload
53byte fixed length cell= 5Bytes cell header+48Bytes payload. ATM must set up virtual connection before communication.
Contract
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ATM network will confer with terminal on parameter of QoS before the connection is set up.
Internal Use
ATM Network Model UNI
NNI
NNI
UNI
NNI
NNI NNI
ATM Switch
UNI
ATM End terminal
UNI = User to Network Interface NNI = Network to Network Interface
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Internal Use
ATM Cell
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Internal Use
ATM Cell
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GFC ( Generic Flow Control): It is intended for control of a possible bus system at the user interface and is not used at the moment. VPI ( Virtual Path Identifier): The VPI contains the second part of the addressing instructions and is of higher priority than the VCI. VCI ( Virtual Channel Identifier): VCI in each case indicates a path section between switching centers or between the switching center and the subscriber. PTI ( Payload Type Identifier): Indicates the type of data in the information field. CLP ( Cell Loss Priority): Determines whether a cell can be preferentially deleted or not in the case of a transmission bottleneck. HEC ( Header Error Control): Provided in order to control and, to some extent, correct errors in the header data that may occur. The HEC is used to synchronize the receiver to the start of the cell.
Internal Use
VP and VC
think VPI as a bundle of virtual channels. (256 VPI on one link) the individual virtual channels have unique VCIs. The VCI values may be reused in each virtual path.
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Internal Use
ATM Connections
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Internal Use
ATM Virtual Connection
UNI cell VPI =1 VCI =1
A
1
Port
VPI
VCI
1
1
1
2
26
44 1
3 2
NNI cell VPI =26 VCI =44 3 1
Port
VPI
VCI
1
26
44
2
2
44
UNI cell VPI =20 VCI =30 3
2
NNI cell VPI =2 VCI =44
NNI cell VPI =6 VCI =44 3
B
2
Port
VPI
VCI
2
6
44
3
20
30
2
1
ATM Virtual Connection
Port
VPI
VCI
1
2
44
2
6
44
In order to exchange cells between A and B, several tables must be set up in network node where the cells passed. After these tables have been set up, all the cells will be transferred along this route. This route is called Virtual Connection. 58
Internal Use
ATM Protocol Structure Model
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Internal Use
ATM traffic classes
60
Internal Use
ATM traffic parameters
61
Internal Use
ATM applications in UMTS network
UTRAN
Uu
NodeB
Iub
Iu
Iu-CS
RNC
UE
MSC
NodeB
Iur NodeB
RNC UE
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NodeB
SGSN
Iu-PS
Internal Use
ATM applications in UMTS network
63
Internal Use
64
Internal Use