Prof. Dr.-Ing. Jochen Schiller, http://www.jochenschiller.de/ MC SS02 4.1

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Prof. Dr.-Ing. Jochen Schiller, http://www.jochenschiller.de/ MC SS02 4.1

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Title: Prof. Dr.-Ing. Jochen Schiller, http://www.jochenschiller.de/ MC SS02 4.1

1
Mobile CommunicationsChapter 4 Wireless
Telecommunication Systems

Market
GSM
Overview
Services
Sub-systems
Components

DECT
TETRA
UMTS/IMT-2000

2
Mobile phone subscribers worldwide
3
Development of mobile telecommunication systems
CT0/1
AMPS
FDMA
CT2
NMT
IMT-FT DECT
IS-136 TDMA D-AMPS
EDGE
IMT-SC IS-136HS UWC-136
TDMA
GSM
GPRS
PDC
IMT-DS UTRA FDD / W-CDMA
IMT-TC UTRA TDD / TD-CDMA
IMT-TC TD-SCDMA
CDMA
IS-95 cdmaOne
IMT-MC cdma2000 1X EV-DO
cdma2000 1X
1X EV-DV (3X)
1G
2G
3G
2.5G
4
GSM Overview

GSM
formerly Groupe Spéciale Mobile (founded 1982)
now Global System for Mobile Communication
Pan-European standard (ETSI, European
Telecommunications Standardisation Institute)
simultaneous introduction of essential services
in three phases (1991, 1994, 1996) by the
European telecommunication administrations
(Germany D1 and D2) ? seamless roaming within
Europe possible
today many providers all over the world use GSM
(more than 184 countries in Asia, Africa, Europe,
Australia, America)
more than 747 million subscribers
more than 70 of all digital mobile phones use
GSM
over 10 billion SMS per month in Germany, gt 360
billion/year worldwide

5
Performance characteristics of GSM (wrt. analog
sys.)

Communication
mobile, wireless communication support for voice
and data services
Total mobility
international access, chip-card enables use of
access points of different providers
Worldwide connectivity
one number, the network handles localization
High capacity
better frequency efficiency, smaller cells, more
customers per cell
High transmission quality
high audio quality and reliability for wireless,
uninterrupted phone calls at higher speeds (e.g.,
from cars, trains)
Security functions
access control, authentication via chip-card and
PIN

6
Disadvantages of GSM

There is no perfect system!!
no end-to-end encryption of user data
no full ISDN bandwidth of 64 kbit/s to the user,
no transparent B-channel
reduced concentration while driving
electromagnetic radiation
abuse of private data possible
roaming profiles accessible
high complexity of the system
several incompatibilities within the GSM
standards

7
GSM Mobile Services

GSM offers
several types of connections
voice connections, data connections, short
message service
multi-service options (combination of basic
services)
Three service domains
Bearer Services (transmission only, connection
oriented, ps or cs)
Telematic Services (application specific)
Supplementary Services (user identification, call
forwarding, groups, )

bearer services
MS
GSM-PLMN
transit network (PSTN, ISDN)
source/ destination network
TE
TE
MT
R, S
(U, S, R)
Um
tele services
8
Bearer Services

Telecommunication services to transfer data
between access points
Specification of services up to the terminal
interface (OSI layers 1-3)
Different data rates for voice and data (original
standard)
data service (circuit switched)
synchronous 2.4, 4.8 or 9.6 kbit/s
asynchronous 300 - 1200 bit/s
data service (packet switched)
synchronous 2.4, 4.8 or 9.6 kbit/s
asynchronous 300 - 9600 bit/s
Today data rates of approx. 50 kbit/s possible
will be covered later!

9
Tele Services I

Telecommunication services that enable voice
communication via mobile phones
All these basic services have to obey cellular
functions, security measurements etc.
Offered services
mobile telephonyprimary goal of GSM was to
enable mobile telephony offering the traditional
bandwidth of 3.1 kHz
Emergency numbercommon number throughout Europe
(112) mandatory for all service providers free
of charge connection with the highest priority
(preemption of other connections possible)
Multinumberingseveral ISDN phone numbers per
user possible

10
Tele Services II

Additional services
Non-Voice-Teleservices
group 3 fax
voice mailbox (implemented in the fixed network
supporting the mobile terminals)
electronic mail (MHS, Message Handling System,
implemented in the fixed network)
...
Short Message Service (SMS)alphanumeric data
transmission to/from the mobile terminal using
the signaling channel, thus allowing simultaneous
use of basic services and SMS

11
Supplementary services

Services in addition to the basic services,
cannot be offered stand-alone
Similar to ISDN services besides lower bandwidth
due to the radio link
May differ between different service providers,
countries and protocol versions
Important services
identification forwarding of caller number
suppression of number forwarding
automatic call-back
conferencing with up to 7 participants
locking of the mobile terminal (incoming or
outgoing calls)
...

12
Architecture of the GSM system

GSM is a PLMN (Public Land Mobile Network)
several providers setup mobile networks following
the GSM standard within each country
components
MS (mobile station)
BS (base station)
MSC (mobile switching center)
LR (location register)
subsystems
RSS (radio subsystem) covers all radio aspects
NSS (network and switching subsystem) call
forwarding, handover, switching
OSS (operation subsystem) management of the
network

13
GSM overview
OMC, EIR, AUC
fixed network
HLR
GMSC
NSS with OSS
VLR
MSC
MSC
VLR
BSC
BTS
BSC
BTS
BTS
BSS
RSS
BTS
BTS
MS
14
GSM elements and interfaces
radio cell
BSS
MS
MS
Um
radio cell
BSS Base Station subsystem BTS Base transfer
station BSC Base Station Controller MS Mobile
Station MSC Mobile Switching Center VLRVisitor
Location Register HLR Home location
Register GMSC Gateway MSC IWF InterWorking
Function AUC Authentication Center EIR
Equipment Identity Register OMC Operation and
Maintenance Center PDN Public Data Network PSTN
Public Switched Telephone Network ISDN
Integrated Service Digital Network
MS
RSS
BTS
BTS
Abis
BSC
BSC
A
MSC
MSC
NSS
VLR
VLR
signallng
HLR
ISDN, PSTN
GMSC
PDN
IWF
O
EIR
OSS
OMC
AUC
15
GSM system architecture
radiosubsystem
network and switching subsystem
fixedpartner networks
MS
MS
ISDNPSTN
Um
MSC
Abis
BTS
BSC
EIR
BTS
SS7
HLR
VLR
BTS
BSC
ISDNPSTN
BTS
MSC
A
IWF
BSS
PSPDNCSPDN
16
System architecture radio subsystem
radiosubsystem
network and switchingsubsystem
MS
MS

Components
MS (Mobile Station)
BSS (Base Station Subsystem)consisting of
BTS (Base Transceiver Station)sender and
receiver
BSC (Base Station Controller)controlling
several transceivers
Interfaces
Um radio interface
Abis standardized, open interface with 16
kbit/s user channels
A standardized, open interface with 64 kbit/s
user channels

Um
Abis
BTS
MSC
BSC
BTS
A
BTS
MSC
BSC
BTS
BSS
17
System architecture network and switching
subsystem
networksubsystem
fixed partnernetworks

Components
MSC (Mobile Services Switching Center)
IWF (Interworking Functions)
ISDN (Integrated Services Digital Network)
PSTN (Public Switched Telephone Network)
PSPDN (Packet Switched Public Data Net.)
CSPDN (Circuit Switched Public Data Net.)
Databases
HLR (Home Location Register)
VLR (Visitor Location Register)
EIR (Equipment Identity Register)

ISDNPSTN
MSC
EIR
SS7
HLR
VLR
ISDNPSTN
MSC
IWF
PSPDNCSPDN
18
Radio subsystem

The Radio Subsystem (RSS) comprises the cellular
mobile network up to the switching centers
Components
Base Station Subsystem (BSS)
Base Transceiver Station (BTS) radio components
including sender, receiver, antenna - if directed
antennas are used one BTS can cover several cells
Base Station Controller (BSC) switching between
BTSs, controlling BTSs, managing of network
resources, mapping of radio channels (Um) onto
terrestrial channels (A interface)
BSS BSC sum(BTS) interconnection
Mobile Stations (MS)

19
GSM cellular network
segmentation of the area into cells
possible radio coverage of the cell
idealized shape of the cell

use of several carrier frequencies
not the same frequency in adjoining cells
cell sizes vary from some 100 m up to 35 km
depending on user density, geography, transceiver
power etc.
hexagonal shape of cells is idealized (cells
overlap, shapes depend on geography)
if a mobile user changes cells ? handover of the
connection to the neighbor cell

20
Example coverage of GSM networks
(www.gsmworld.com)
Vodafone (GSM-900/1800)
T-Mobile (GSM-900/1800) Berlin
e-plus (GSM-1800)
O2 (GSM-1800)
21
Base Transceiver Station and Base Station
Controller

Tasks of a BSS are distributed over BSC and BTS
BTS comprises radio specific functions
BSC is the switching center for radio channels

22
Mobile station

Terminal for the use of GSM services
A mobile station (MS) comprises several
functional groups
MT (Mobile Terminal)
offers common functions used by all services the
MS offers
corresponds to the network termination (NT) of an
ISDN access
end-point of the radio interface (Um)
TA (Terminal Adapter)
terminal adaptation, hides radio specific
characteristics
TE (Terminal Equipment)
peripheral device of the MS, offers services to a
user
does not contain GSM specific functions
SIM (Subscriber Identity Module)
personalization of the mobile terminal, stores
user parameters

23
Network and switching subsystem

NSS is the main component of the public mobile
network GSM
switching, mobility management, interconnection
to other networks, system control
Components
Mobile Services Switching Center (MSC)controls
all connections via a separated network to/from a
mobile terminal within the domain of the MSC -
several BSC can belong to a MSC
Databases (important scalability, high capacity,
low delay)
Home Location Register (HLR)central master
database containing user data, permanent and
semi-permanent data of all subscribers assigned
to the HLR (one provider can have several HLRs)
Visitor Location Register (VLR)local database
for a subset of user data, including data about
all user currently in the domain of the VLR

24
Mobile Services Switching Center

The MSC (mobile switching center) plays a central
role in GSM
switching functions
additional functions for mobility support
management of network resources
interworking functions via Gateway MSC (GMSC)
integration of several databases
Functions of a MSC
specific functions for paging and call forwarding
termination of SS7 (signaling system no. 7)
mobility specific signaling
location registration and forwarding of location
information
provision of new services (fax, data calls)
support of short message service (SMS)
generation and forwarding of accounting and
billing information

25
Operation SubSystem

The OSS (Operation Subsystem) enables centralized
operation, management, and maintenance of all GSM
subsystems
Components
Authentication Center (AUC)
generates user specific authentication parameters
on request of a VLR
authentication parameters used for authentication
of mobile terminals and encryption of user data
on the air interface within the GSM system
Equipment Identity Register (EIR)
registers GSM mobile stations and user rights
stolen or malfunctioning mobile stations can be
locked and sometimes even localized (IMEI)
Operation and Maintenance Center (OMC)
different control capabilities for the radio
subsystem and the network subsystem

26
GSM - TDMA/FDMA
935-960 MHz 124 channels (200 kHz) downlink
frequency
890-915 MHz 124 channels (200 kHz) uplink
time
GSM TDMA frame
GSM time-slot (normal burst)
guard space
guard space
tail
user data
Training
S
S
user data
tail
3 bits
57 bits
26 bits
57 bits
1
1
3
27
GSM hierarchy of frames
hyperframe
0
1
2
2045
2046
2047
...
3 h 28 min 53.76 s
superframe
0
1
2
48
49
50
...
6.12 s
0
1
24
25
...
multiframe
0
1
24
25
...
120 ms
0
1
2
48
49
50
...
235.4 ms
frame
0
1
6
7
...
4.615 ms
slot
burst
577 µs
28
GSM protocol layers for signaling
Um
Abis
A
MS
BTS
BSC
MSC
CM
CM
MM
MM
RR BTSM
BSSAP
RR
BSSAP
RR
BTSM
SS7
SS7
LAPDm
LAPDm
LAPD
LAPD
radio
radio
PCM
PCM
PCM
PCM
16/64 kbit/s
64 kbit/s / 2.048 Mbit/s
RR Radio Resource Mgmt, LAPD Link Access
Procedure D Channel, MM Mobility Management, CM
Call Management (CC, SMS, SS), BSSAP BSS
Application Part
29
Mobile Terminated Call

1 calling a GSM subscriber
2 forwarding call to GMSC
3 signal call setup to HLR
4, 5 request MSRN from VLR
6 forward responsible MSC to GMSC
7 forward call to
current MSC
8, 9 get current status of MS
10, 11 paging of MS
12, 13 MS answers
14, 15 security checks
16, 17 set up connection

4
HLR
VLR
5
8
9
3
6
14
15
7
calling station
GMSC
MSC
1
2
10
13
10
10
16
BSS
BSS
BSS
11
11
11
11
12
17
MS
MSRN Mobile Station Roaming Number
30
Mobile Originated Call

1, 2 connection request
3, 4 security check
5-8 check resources (free circuit)
9-10 set up call

VLR
3
4
6
5
GMSC
MSC
7
8
2
9
MS localization numbers MSISDN Mobile station
ISDN IMSI International Mobile Subscriber
Identity MCC(62), MNC(812), MSIN TMSI Temporary
MSI (security) MSRN MS Roaming Number
1
BSS
MS
10
31
MTC/MOC
32
4 types of handover
1
2
3
4
MS
MS
MS
MS
BTS
BTS
BTS
BTS
BSC
BSC
BSC
MSC
MSC
Intra-cell narrow frequency interference,
frequency change Inter-cell signal
strength/traffic, BTS change Inter-BSC signal
strength/traffic, BSC change Inter-MSC signal
strength, MSC change
33
Handover decision
receive level BTSold
receive level BTSold
HO_MARGIN
MS
MS
BTSold
BTSnew
34
Handover procedure
MSC
BTSold
BSCnew
BSCold
MS
BTSnew
measurement report
measurement result
HO decision
HO required
HO request
resource allocation
ch. activation
ch. activation ack
HO request ack
HO command
HO command
HO command
HO access
Link establishment
HO complete
HO complete
clear command
clear command
clear complete
clear complete
35
Security in GSM

Security services
access control/authentication
user ? SIM (Subscriber Identity Module) secret
PIN (personal identification number)
SIM ? network challenge response method
confidentiality
voice and signaling encrypted on the wireless
link (after successful authentication)
anonymity
temporary identity TMSI (Temporary Mobile
Subscriber Identity)
newly assigned at each new location update (LUP)
encrypted transmission
3 algorithms specified in GSM
A3 for authentication (secret, open interface)
A5 for encryption (standardized)
A8 for key generation (secret, open interface)

secret
A3 and A8 available via the Internet (1998)
network providers can use stronger mechanisms

36
GSM - authentication
SIM
mobile network
RAND
RAND
Ki
RAND
Ki
128 bit
128 bit
128 bit
128 bit
AC
A3
A3
SIM
SRES 32 bit
SRES 32 bit
SRES
SRES ? SRES
MSC
SRES
32 bit
Ki individual subscriber authentication
key SRES signed response
37
GSM - key generation and encryption
MS with SIM
mobile network (BTS)
RAND
RAND
Ki
RAND
Ki
AC
SIM
128 bit
128 bit
128 bit
128 bit
A8
A8
cipher key
Kc 64 bit
Kc 64 bit
SRES
encrypteddata
data
data
BSS
MS
A5
A5
38
GSM Logical Channels

TCH (Traffic Channel)
Full rate (TCH/F)22.8Kbit/s, Half rate
(TCH/H)11.4kbit/sTCH/FS error correction (early
GSM era)
CCH (Control Channel)
BCCH (Broadcast Control Channel) from BTS to
MSs, to transmit CellId, options (frequencies,
hopping) available for this cell.
FCCH (Frequency correction),
SCH (Synchronization)
CCCH (Common Control Channel) for connection
setup
PCH (Paging Channel)
RACH (Random Access Channel) slotted Aloha
AGCH (Access Granted Channel)
DCCH (Dedicated Control Channel)
SDCCH (Standalone DCCH) for signaling
(authentication, registration, etc)
SACCH (Slow Associated DCCH) channel quality,
power level
FACCH (Fast Associated DCCH) data exchange
during handover
Typical slot usage pattern TTTTTTTTTTTTSTTTTTTTTT
TTTx

39
Data services in GSM I

Data transmission standardized with only 9.6
kbit/s
advanced coding allows 14,4 kbit/s
not enough for Internet and multimedia
applications
HSCSD (High-Speed Circuit Switched Data)
mainly software update
bundling of several time-slots to get higher
AIUR (Air Interface User Rate)(e.g., 57.6
kbit/s using 4 slots, 14.4 each)
advantage ready to use, constant quality, simple
disadvantage channels blocked for voice
transmission

40
Data services in GSM II

GPRS (General Packet Radio Service)
packet switching
using free slots only if data packets ready to
send (e.g., 50 kbit/s using 4 slots temporarily)
standardization 1998, introduction 2001
advantage one step towards UMTS, more flexible
disadvantage more investment needed (new
hardware)
GPRS network elements
GSN (GPRS Support Nodes) GGSN and SGSN
GGSN (Gateway GSN)
interworking unit between GPRS and PDN (Packet
Data Network)
SGSN (Serving GSN)
supports the MS (location, billing, security)
GR (GPRS Register)
user addresses

41
GPRS quality of service
42
Examples for GPRS device classes
43
GPRS user data rates in kbit/s
44
GPRS architecture and interfaces
45
GPRS protocol architecture
MS
BSS
SGSN
GGSN
Um
Gb
Gn
Gi
apps.
IP/X.25
IP/X.25
GTP
SNDCP
SNDCP
GTP
LLC
UDP/TCP
LLC
UDP/TCP
RLC
BSSGP
RLC
BSSGP
IP
IP
MAC
MAC
FR
FR
L1/L2
L1/L2
radio
radio
46
DECT

DECT (Digital European Cordless Telephone)
standardized by ETSI (ETS 300.175-x) for cordless
telephones
standard describes air interface between
base-station and mobile phone
DECT has been renamed for international marketing
reasons into Digital Enhanced Cordless
Telecommunication
Characteristics
frequency 1880-1990 MHz
channels 120 full duplex
duplex mechanism TDD (Time Division Duplex) with
10 ms frame length
multplexing scheme FDMA with 10 carrier
frequencies, TDMA with 2x 12 slots
modulation digital, Gaußian Minimum Shift Key
(GMSK)
power 10 mW average (max. 250 mW)
range approx. 50 m in buildings, 300 m open space

47
DECT system architecture reference model
D3
D4
VDB
D2
local network
FT
PT
PA
HDB
PT
PA
D1
global network
FT
local network
48
DECT reference model
U-Plane
C-Plane

close to the OSI reference model
management plane over all layers
several services in C(ontrol)- and U(ser)-plane

signaling, interworking
application processes
network layer
OSI layer 3
management
data link control
data link control
OSI layer 2
medium access control
physical layer
OSI layer 1
49
DECT layers I

Physical layer
modulation/demodulation GMSK
generation of the physical channel structure with
a guaranteed throughput
controlling of radio transmission
channel assignment on request of the MAC layer
detection of incoming signals
sender/receiver synchronization
collecting status information for the management
plane
MAC layer
maintaining basic services, activating/deactivatin
g physical channels
multiplexing of logical channels
e.g., C signaling, I user data, P paging, Q
broadcast
segmentation/reassembly
error control/error correction

50
DECT time multiplex frame
1 frame 10 ms
12 down slots
12 up slots
slot
420 bit 52 µs guard time (60 bit) in 0.4167
ms
guard
0
419
sync
D field
0
31
0
387
A network control B user data X transmission
quality
A field
B field
X field
0
63
0
319
0
3
protected mode
25.6 kbit/s
simplex bearer
unprotected mode
DATA
32 kbit/s
51
DECT layers II

Data link control layer
creation and keeping up reliable connections
between the mobile terminal and basestation
two DLC protocols for the control plane (C-Plane)
connectionless broadcast servicepaging
functionality
LcLAPC protocolin-call signaling (similar to
LAPD within ISDN), adapted to the underlying MAC
service
several services specified for the user plane
(U-Plane)
null-service offers unmodified MAC services
frame relay simple packet transmission
frame switching time-bounded packet transmission
error correcting transmission uses FEC, for
delay critical, time-bounded services
bandwidth adaptive transmission
Escape service for further enhancements of the
standard

52
DECT layers III

Network layer
similar to ISDN (Q.931) and GSM (04.08)
offers services to request, check, reserve,
control, and release resources at the basestation
and mobile terminal
resources
necessary for a wireless connection
necessary for the connection of the DECT system
to the fixed network
main tasks
call control setup, release, negotiation,
control
call independent services call forwarding,
accounting, call redirecting
mobility management identity management,
authentication, management of the location
register

53
Enhancements of the standard

Several DECT Application Profiles in addition
to the DECT specification
GAP (Generic Access Profile) standardized by ETSI
in 1997
assures interoperability between DECT equipment
of different manufacturers (minimal requirements
for voice communication)
enhanced management capabilities through the
fixed network Cordless Terminal Mobility (CTM)
DECT/GSM Interworking Profile (GIP) connection
to GSM
ISDN Interworking Profiles (IAP, IIP) connection
to ISDN
Radio Local Loop Access Profile (RAP) public
telephone service
CTM Access Profile (CAP) support for user
mobility

54
TETRA - Terrestrial Trunked Radio

Trunked radio systems
many different radio carriers
assign single carrier for a short period to one
user/group of users
taxi service, fleet management, rescue teams
interfaces to public networks, voice and data
services
very reliable, fast call setup, local operation
TETRA - ETSI standard
formerly Trans European Trunked Radio
offers VoiceData and Packet Data Optimized
service
point-to-point and point-to-multipoint
ad-hoc and infrastructure networks
several frequencies 380-400 MHz, 410-430 MHz
FDD, DQPSK
group call, broadcast, sub-second group-call setup

55
TETRA Architecture

Similar to GSM, but simpler
MS (mobile station)
SwMI (Switching and management Infrastructure)
Um radio interface
HDB (Home Database)
VDB (Visitor Database)
Base station (not always needed)
No Handover
Main services
VD Circuit switched up to four TDMA channel
PDO connection less, statistical mux
Additional services
Group call, acknowledged group call, broadcast
call

56
TDMA structure of the voicedata system
hyperframe
0
1
2
57
58
59
...
61.2 s
multiframe
0
1
2
15
16
17
...
1.02 s
CF
frame
Control Frame
0
1
2
3
56.67 ms
0 slot 509
14.17 ms
57
UMTS and IMT-2000

Proposals for IMT-2000 (International Mobile
Telecommunications formerly FPLMTS)
UWC-136 (IS-136), cdma2000(IS-95), WP-CDMA
UMTS (Universal Mobile Telecommunications System)
from ETSI
UMTS
UTRA (was UMTS, now Universal Terrestrial Radio
Access)
enhancements of GSM
EDGE (Enhanced Data rates for GSM Evolution) GSM
up to 384 kbit/s
CAMEL (Customized Application for Mobile Enhanced
Logic)
VHE (virtual Home Environment)
fits into GMM (Global Multimedia Mobility)
initiative from ETSI
requirements
min. 144 kbit/s rural (goal 384 kbit/s)
min. 384 kbit/s suburban (goal 512 kbit/s)
up to 2 Mbit/s urban

58
IMT-2000 Services/Capabilities

Capabilities to support circuit and packet data
at high bit rates
- 144 kbs or higher in high mobility (vehicular)
traffic
- 384 kbs or higher for pedestrian traffic
- 2 mbs or higher for indoor traffic
Interoperability and roaming among IMT-2000
family of systems
Common billing/user profiles
- Sharing of usage/rate information between
service providers
- Standardized call detail recording
- Standardized user profiles
Capability to determine geographic position of
mobiles and report it to
both the network and the mobile terminal
Support of multimedia services/capabilities
- Fixed and variable rate bit traffic
- Bandwidth on demand
- Asymmetric data rates in the forward and
reverse links

59
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60
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61
Frequencies for IMT-2000
1850
1900
1950
2000
2050
2100
2150
2200
MHz
ITU allocation (WRC 1992)
IMT-2000
MSS ?
IMT-2000
MSS ?
UTRA FDD ?
UTRA FDD ?
T D D
T D D
MSS ?
MSS ?
DE CT
GSM 1800
Europe
IMT-2000
MSS ?
IMT-2000
MSS ?
GSM 1800
China
cdma2000 W-CDMA
MSS ?
MSS ?
cdma2000 W-CDMA
PHS
Japan
MSS ?
MSS ?
PCS
rsv.
North America
MHz
1850
1900
1950
2000
2050
2100
2150
2200
62
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63
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64
Why New Spectrum?
65
Mobility, range, throughput trade-off

Mobile radio access networks are designed to
meet certain maximum requirements
for grade of mobility and range
WLANs are designed for high data rates, low
ranges and generally low mobility

66
IMT-2000 family
Interface for Internetworking
IMT-2000 Core Network ITU-T
GSM (MAP)
ANSI-41 (IS-634)
IP-Network
Initial UMTS (R99 w/ FDD)
IMT-DS (Direct Spread) UTRA FDD (W-CDMA) 3GPP
IMT-TC (Time Code) UTRA TDD (TD-CDMA) TD-SCDMA 3G
PP
IMT-MC (Multi Carrier) cdma2000 3GPP2
IMT-SC (Single Carrier) UWC-136 (EDGE) UWCC/3GPP
IMT-FT (Freq. Time) DECT ETSI
IMT-2000 Radio Access ITU-R
67
Licensing Example UMTS in Germany, 18. August
2000

UTRA-FDD
Uplink 1920-1980 MHz
Downlink 2110-2170 MHz
duplex spacing 190 MHz
12 channels, each 5 MHz
UTRA-TDD
1900-1920 MHz,
2010-2025 MHz
5 MHz channels
Coverage 25 of the population until 12/2003,
50 until 12/2005

Sum 50.81 billion
68
UMTS architecture (Release 99 used here!)

UTRAN (UTRA Network)
Cell level mobility
Radio Network Subsystem (RNS)
Encapsulation of all radio specific tasks
UE (User Equipment)
CN (Core Network)
Inter system handover
Location management if there is no dedicated
connection between UE and UTRAN

Iu
Uu
UTRAN
UE
CN
69
UMTS domains and interfaces I

User Equipment Domain
Assigned to a single user in order to access UMTS
services
Infrastructure Domain
Shared among all users
Offers UMTS services to all accepted users

Home Network Domain
Zu
Cu
Uu
Iu
Yu
USIM Domain
MobileEquipment Domain
Access Network Domain
Serving Network Domain
Transit Network Domain
Core Network Domain
User Equipment Domain
Infrastructure Domain
70
UMTS domains and interfaces II

Universal Subscriber Identity Module (USIM)
Functions for encryption and authentication of
users
Located on a SIM inserted into a mobile device
Mobile Equipment Domain
Functions for radio transmission
User interface for establishing/maintaining
end-to-end connections
Access Network Domain
Access network dependent functions
Core Network Domain
Access network independent functions
Serving Network Domain
Network currently responsible for communication
Home Network Domain
Location and access network independent functions

71
Spreading and scrambling of user data

Constant chipping rate of 3.84 Mchip/s
Different user data rates supported via different
spreading factors
higher data rate less chips per bit and vice
versa
User separation via unique, quasi orthogonal
scrambling codes
users are not separated via orthogonal spreading
codes
much simpler management of codes each station
can use the same orthogonal spreading codes
precise synchronisation not necessary as the
scrambling codes stay quasi-orthogonal

data1
data2
data3
data4
data5
spr. code3
spr. code2
spr. code1
spr. code4
spr. code1
scrambling code1
scrambling code2
sender1
sender2
72
OSVF coding
1,1,1,1,1,1,1,1
...
1,1,1,1
1,1,1,1,-1,-1,-1,-1
1,1
1,1,-1,-1,1,1,-1,-1
...
1,1,-1,-1
X,X
1,1,-1,-1,-1,-1,1,1
1
X
1,-1,1,-1,1,-1,1,-1
X,-X
...
1,-1,1,-1
1,-1,1,-1,-1,1,-1,1
1,-1
SFn
SF2n
1,-1,-1,1,1,-1,-1,1
...
1,-1,-1,1
1,-1,-1,1,-1,1,1,-1
SF1
SF2
SF4
SF8
73
OVSF
74
OVSF example

Data Code
Transmission
User1 -1 1 1 1 1
-1 -1 -1 -1
x x x x
User2 1 -1 1 -1
1 -1 -1 1
-1 1 1 -1 0
Two Users, two different data rates, orthogonal
transmission.

75
UMTS FDD frame structure

W-CDMA
1920-1980 MHz uplink
2110-2170 MHz downlink
chipping rate 3.840 Mchip/s
soft handover
QPSK
complex power control (1500 power control
cycles/s)
spreading UL 4-256 DL4-512

Radio frame
0
1
2
12
13
14
...
10 ms
Time slot
Pilot
FBI
TPC
TFCI
666.7 µs
uplink DPCCH
2560 chips, 10 bits
Data
uplink DPDCH
666.7 µs
2560 chips, 102k bits (k 0...6)
Data1
TPC
TFCI
Pilot
Data2
downlink DPCH
666.7 µs
FBI Feedback Information TPC Transmit Power
Control TFCI Transport Format Combination
Indicator DPCCH Dedicated Physical Control
Channel DPDCH Dedicated Physical Data
Channel DPCH Dedicated Physical Channel
DPCCH
DPDCH
DPDCH
DPCCH
2560 chips, 102k bits (k 0...7)
Slot structure NOT for user separation but
synchronisation for periodic functions!
76
Typical UTRA-FDD uplink data rates
77
UMTS TDD frame structure (burst type 2)
Radio frame
0
1
2
12
13
14
...
10 ms
Time slot
Data 1104 chips
Midample 256 chips
Data 1104 chips
GP
666.7 µs
Traffic burst
GP guard period 96 chips
2560 chips

TD-CDMA
2560 chips per slot
spreading 1-16
symmetric or asymmetric slot assignment to UL/DL
(min. 1 per direction)
tight synchronisation needed
simpler power control (100-800 power control
cycles/s)

78
UTRAN architecture
RNC Radio Network Controller RNS Radio Network
Subsystem
RNS
UE1
Iub
Node B
Iu
RNC
CN
UE2
Node B
Node B
UTRAN comprises several RNSs Node B can support
FDD or TDD or both RNC is responsible for
handover decisions requiring signalingto the
UE Cell offers FDD or TDD
UE3
Iur
Node B
Iub
Node B
RNC
Node B
Node B
RNS
79
UTRAN architecture
RNC Radio Network Controller RNS Radio Network
Subsystem
RNS
UE
Iub
Node B
UTRAN comprises several RNSs Node B can support
FDD or TDD or both RNC is responsible for
handover decisions requiring signaling to the
UE Cell offers FDD or TDD
RNC
Iu
Node B
Node B
CN
Iur
Node B
Iub
Node B
RNC
Node B
Node B
RNS
80
UTRAN functions

Admission control
Congestion control
System information broadcasting
Radio channel encryption
Handover
SRNS moving
Radio network configuration
Channel quality measurements
Macro diversity
Radio carrier control
Radio resource control
Data transmission over the radio interface
Outer loop power control (FDD and TDD)
Channel coding
Access control

81
UTRAN and System Architecture
82
Connections in Serving RNC relocation
83
Core network protocols
VLR
MSC
GMSC
GSM-CS backbone
RNS
HLR
RNS
SGSN
GGSN
Layer 3 IP
GPRS backbone (IP)
Layer 2 ATM
SS 7
Layer 1 PDH, SDH, SONET
UTRAN
CN
84
Core network architecture
VLR
BSS
Abis
BTS
Iu
BSC
MSC
GMSC
PSTN
Node B
BTS

IuCS

AuC
HLR
EIR
GR
Node B
Iub
Node B
RNC
SGSN
GGSN
Gi
Gn
Node B
Node B

IuPS

CN
RNS
85
Core network

The Core Network (CN) and thus the Interface Iu,
too, are separated into two logical domains
Circuit Switched Domain (CSD)
Circuit switched service incl. signaling
Resource reservation at connection setup
GSM components (MSC, GMSC, VLR)
IuCS
Packet Switched Domain (PSD)
GPRS components (SGSN, GGSN)
IuPS
Release 99 uses the GSM/GPRS network and adds a
new radio access!
Helps to save a lot of money
Much faster deployment
Not as flexible as newer releases (5, 6)

86
UMTS protocol stacks (user plane)
IuCS
UTRAN
3G MSC
Uu
UE
apps. protocols
RLC
SAR
RLC
SAR
Circuit switched
MAC
MAC
AAL2
AAL2
radio
radio
ATM
ATM
Uu
IuPS
UE
UTRAN
3G SGSN
Gn
3G GGSN
apps. protocols
IP, PPP,
IP, PPP,
IP tunnel
Packet switched
GTP
PDCP
GTP
PDCP
GTP
GTP
RLC
UDP/IP
RLC
UDP/IP
UDP/IP
UDP/IP
MAC
MAC
AAL5
AAL5
L2
L2
radio
radio
ATM
ATM
L1
L1
87
Support of mobility macro diversity

Multicasting of data via several physical
channels
Enables soft handover
FDD mode only
Uplink
simultaneous reception of UE data at several Node
Bs
Reconstruction of data at Node B, SRNC or DRNC
Downlink
Simultaneous transmission of data via different
cells
Different spreading codes in different cells

UE
Node B
CN
Node B
RNC
88
Support of mobility handover

From and to other systems (e.g., UMTS to GSM)
This is a must as UMTS coverage will be poor in
the beginning
RNS controlling the connection is called SRNS
(Serving RNS)
RNS offering additional resources (e.g., for soft
handover) is called Drift RNS (DRNS)
End-to-end connections between UE and CN only via
Iu at the SRNS
Change of SRNS requires change of Iu
Initiated by the SRNS
Controlled by the RNC and CN

CN
SRNC
Node B
Iub
Iu
UE
Iur
DRNC
Node B
Iub
89
Example handover types in UMTS/GSM
UE1
RNC1
3G MSC1
Node B1
Iu
UE2
Node B2
Iur
Iub
UE3
RNC2
Node B3
3G MSC2
UE4
BSC
BTS
2G MSC3
Abis
A
90
UMTS services (originally)

Data transmission service profiles
Virtual Home Environment (VHE)
Enables access to personalized data independent
of location, access network, and device
Network operators may offer new services without
changing the network
Service providers may offer services based on
components which allow the automatic adaptation
to new networks and devices
Integration of existing IN services

91
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