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Subject Code : 10EC81 IA Marks : 25
No. of Lecture Hrs/Week : 04 Exam Hours : 03
Total no. of Lecture Hrs. : 52 Exam Marks : 100
PART - A
UNIT1
Introduction to wireless telecommunication systems and Networks,
History and evolution
Different generations of wireless cellular networks 1G, 2g,3G
and 4G
etworks.
6 Hours
UNIT - 2
Common Cellular System components, Common cellular network
components, Hardwareand software, views of cellular networks, 3G
cellular systems components, Cellular
component identification Call establishment.
6 Hours
UNIT - 3
Wireless network architecture and operation, Cellular concept
Cell fundamentals, Capacityexpansion techniques, Cellular backbone
networks, Mobility management, Radio resources
andpowermanagementWirelessnetwork
6 Hours
UNIT - 4
GSM and TDMA techniques, GSM system overview, GSM Network and
system
Architecture,GSMchannelconcepts,GSM
6 Hours
PART - B
UNIT - 5
GSM system operation, Traffic cases, Cal handoff, Roaming, GSM
protocol architecture.
TDMA systems
6 Hours
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UNIT - 6
CDMA technology, CDMA overview, CDMA channel concept CDMA
operations.
8 hours
UNIT - 7
Wireless Modulation techniques and Hardware, Characteristics of
air interface, Path loss
models, wireless coding techniques, Digital modulation
techniques, OFDM, UWB radio
techniques, Diversity techniques, Typical GSM Hardware.
6 Hours
UNIT - 8
Introduction to wireless LAN 802.11X technologies, Evolution of
Wireless LAN
Introduction to 802.15X technologies in PAN Application and
architecture Bluetooth
Introduction to Broadband wireless MAN, 802.16X
technologies.
8 Hours
TEXT BOOK:
1. Wireless Telecom Systems and networks, Mullet: Thomson
Learning 2006.
REFERENCE BOOKS:
1. Mobile Cellular Telecommunication, Lee W.C.Y, MGH, 2002.
2. Wireless communication- D P Agrawal: 2nd
Edition Thomson learning 2007.
3. Fundamentals of Wireless Communication, David Tse, Pramod
Viswanath,
Cambridge 2005.
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INDEX SHEET
Sl.No Unit & Topic of Discussion Page no.
UNIT --- 1
1 Introduction to wireless telecommunication systems
5 to 19
2 Introduction to wireless telecommunication Networks
3 History of different generations of wireless cellular
networks
4 Evolution of different generations of wireless
cellularnetworks
5 1G,2G networks
6 3G and 4G networks
UNIT2
7 Common Cellular System components
20 to 30
8 Common cellular network components9 Hardware and software10
Views of cellular networks11 3G cellular systems components12
Cellular component identification Call establishment13 Call
release
UNIT3
14 Wireless network architecture and operation
31 to 42
15 Cellular concept , Cell fundamentals16 Capacity expansion
techniques, Cellular backbone
networks17 Mobility management18 Radio resources and power
management19 Wireless network security
UNIT --4
43 to 54
20 GSM and TDMA techniques
21 GSM system overview22 GSM Network
23 system Architecture
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24 GSM channel concepts25 GSM identifiers
UNIT5
26 GSM system operation
55 to 67
27 Traffic cases28 Call handoff29 Roaming30 GSM protocol
architecture31 TDMA systems32 NA TDMA
UNIT--6
33 CDMA technology
68 to 81
34 CDMA overview35 CDMA channel concept CDMA operations36 CDMA
channel concept CDMA operations37 CDMA channel concept38 CDMA
channel assignement
UNIT-740 Wireless Modulation techniques and Hardware
82 to 94
41 Characteristics of air interface , Path loss models42
Wireless coding techniques43 Digital modulation techniques, OFDM,
UWB radio
techniques44 Diversity techniques45 Typical GSM Hardware
UNIT-7
46 Introduction to wireless LAN 802.11X technologies
95 to 108
47 Evolution of Wireless LAN48 Introduction to 802.15X
technologies in PAN
architecture
49 802.16X technologies
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UNIT - 1
Introduction to wireless telecommunication systems and Networks,
History and Evolution
Different generations of wireless cellular networks 1G, 2g,3G
and 4G networks.
6 Hours
TEXT BOOK:
1. Wireless Telecom Systems and networks, Mullet: Thomson
Learning 2006.
REFERENCE BOOKS:
1. Mobile Cellular Telecommunication, Lee W.C.Y, MGH, 2002.2.
Wireless communication- D P Agrawal: 2
ndEdition Thomson learning 2007.
3. Fundamentals of Wireless Communication, David Tse, Pramod
Viswanath,
Cambridge 2005.
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UNIT-1
Introduction to wireless telecommunication systems and
networks
1.1 Introduction to wireless telecommunication systems and
networksCommunication is the transfer of information form one point
to another. Invention
of telephone by Bell in 1876 was the first manually switched
wireline network.
Radio or wireless was invented during 20th
century which had the convenience of
mobile operation to electronic communication. Advances in IC
technology gave thecordless telephones during late 1970s , and in
1983 the public had the opportunity
to subscribe for cellular telephone systems. These wireless
systems gave access to
public switched telephone network which had mobile access.
The wireless and mobile communications was found useful in
commerce,
education, defense etc., according to the nature of particular
application they can be
used in home based, industrial, commercial, military
environment. For example, incommercial wireless communications can
be employed for purchase or selling of
goods, services , playing audio and video, payment of telephone
bills , airline , bus
reservations etc.,
1.2 History and Evolution of Wireless Radio Systems
In 1887 , Heinrich Hertz performed laboratory experiments which
proved the
existence of EM waves .
From 1895 to 1901 Marconi experimented with a wireless telegraph
system who
built several radio telegraph stations in England and started
commercial servicebetween England and France in 1899.
Early AM wireless systems
The early wireless transmitter consists of inductance and
capacitance which is used
to tune the output frequency of the spark gap. Max power is
generated at lower freq
and longer wavelength. The transmitter emits the signal either
long or short
duration depending on length of time telegraph key is closed.
The transmitter
signal is the EM noise produced by the spark gap discharge.
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Fig 1. Typical early wireless transmitter
The transmitter signal propagates through the air to a receiver
which is located at some
distance . At the receiver the detected signal is interpreted by
the operator as either a dot ordash depending upon its duration by
use of Morse code.
Modern AM :
Amplitude modulation is used for low frequency radio
broadcasting the AM include
quadrature amplitude modulation which is used for high speed
data transmission at RFfrequencies.
1.2 The Development of Modern Telecommunications
Infrastructure
The early days of telecommunications
The public switched telephone network
The local exchange Intraoffice calls
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Fig: 1.2 A PSTN intraoffice call through a local exchange
Circuit-switched calls Interoffice calls T-carrier transport
Fig: 1.3 A PSTN intraoffice call over an inter-exchange trunk
line
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Signaling System #7
Signal transfer points Service switching points Service control
points Operations support systems
Signalling System No. 7(SS7) is a set of telephony signaling
protocols which are used to
set up most of the world's public switched telephone network
telephone calls. The main
purpose is to set up and tear down telephone calls. Other uses
include number translation,local number portability, prepaid
billing mechanisms, short message service (SMS), and a
variety of other mass market services.
It is usually referenced as Signalling System No. 7 or
Signalling System #7, or simplyabbreviated to SS7. In North America
it is often referred to as CCSS7, an abbreviation for
Common Channel Signalling System 7. In some European countries,
specifically the
United Kingdom, it is sometimes called C7 (CCITT number 7) and
is also known as
number 7 and CCIS7 (Common Channel Interoffice Signaling 7). In
Germany it is oftencalled as N7 (Signalisierungssystem Nummer
7).
There is only one international SS7 protocol defined by ITU-T in
its Q.700-series
recommendations.[1]
There are however, many national variants of the SS7 protocols.
Most
national variants are based on two widely deployed national
variants as standardized byANSI and ETSI, which are in turn based
on the international protocol defined by ITU-T.
Each national variant has its own unique characteristics. Some
national variants with rather
striking characteristics are the China (PRC) and Japan (TTC)
national variants.
The Internet Engineering Task Force (IETF) has also defined
level 2, 3, and 4 protocols
that are compatible with SS7:
Message Transfer Part (MTP) level 2 (M2UA and M2PA)
Message Transfer Part (MTP) level 3 (M3UA)
Signalling Connection Control Part (SCCP) (SUA)
The public data network Connectionless systems Private data
networks Virtual private data networks Tunneling protocols
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Fig: 1.4 Network elements of the SS7 system
1.3 Different Generations of wireless cellular networks:
1G Cellular Systems
AMPS system components and layout Radio base stations
Communications links Mobile switching office
First-generation cellular systems have been around for a few
decades now, and we expect
them to remain in place for some time because of the significant
infrastructure investmentsmade by operators. All of these systems
support circuit data services and may be utilizedfor various forms
of mobile VPN, albeit not without difficulties. This section
provides a
high-level overview of the air interfaces utilized by most
widely deployed 1G systems.
AMPS
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All 1G cellular systems rely on analog frequency modulation for
speech and data
transmission and in-band signaling to move control information
between terminals and the
rest of the network during the call. Advanced Mobile Phone
System is a good example of first-generation analog technology
mostly used in the United
States. AMPS is based on FM radio transmission using the FDMA
principle where everyuser is assigned their own frequency to
separate user channels within the assigned spectrum
(see Figure 3.2). FDMA is based on narrowband channels, each
capable of supporting one
phone circuit that is assigned to a particular user for the
duration of the call. Frequencyassignment is controlled by the
system, and transmission is usually continuous in both
uplink and downlink directions. The spectrum in such systems is
allocated to the user for
the duration of the call, whether it is being used to send
voice, data, or nothing at all.
As with other 1G technologies, in AMPS a circuitrepresented by a
portion of spectrum
is allocated to the user and must remain available for this
user, similar to the telephone
copper pair used for voice communications. Similar to the analog
wireline connection, a
modem is also used for data access (see Chapter 4 for more on
this). Error correctionprotocols used by wireless modems tend to be
more robust than their landline counterparts,
because of the necessity of dealing with a more challenging
physical environment withinherently higher interference and
signal-to-noise ratios than copper or fiber. The peak datarate for
an AMPS modem call under good conditions is usually up to 14.4
Kbps, and as low
as 4.8 Kbps under poor conditions. It can take anywhere up 20
seconds or more to establish
an AMPS data connection.
Fig 1.5 An early AMPS cellular system
Information flow over AMPS channels
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Analog color codes Digital color codes Transponder Signaling
tones
Fig 1.6 AMPS forward and reverse control and voice channels
Typical AMPS operations AMPS security and identification Summary
of basic AMPS operations
Initialization
Fig 1.7 AMPS mobile phone initialization
AMPS ongoing idle mode tasks
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Mobile-to-land calls Handshaking operations Signaling operations
Service requests
Fig 1.8 AMPS mobile originated call
Land-to-mobile and mobile-to-mobile calls
Paging ID information exchange Signaling Control messages
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Fig 1.9 AMPS mobile terminated call
AMPS network operations
Radio base station operations Base station control operations
Mobile switching center operations
Fig 1.10 AMPS network operations for a mobile originated
call
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Handoff operations
Handshaking operations Signal strength measurements MSC
operations during handoff Confirmation messages
Fig 1.11 AMPS handoff operation
2G Cellular Systems
Second-generation (2G) digital cellular systems constitute the
majority of cellularcommunication infrastructures deployed today.
2G systems such as GSM, whose rollout
started in 1987, signaled a major shift in the way mobile
communications is used
worldwide. In part they helped fuel the transition of a mobile
phone from luxury to
necessity and helped to drive subscriber costs down by more
efficient utilization of airinterface and volume deployment of
infrastructure components and handsets.
Major geographical regions adopted different 2G systems, namely
TDMA and CDMA in
North America, GSM in Europe, and Personal Digital Cellular
(PDC) in Japan.
cellular systems. It effectively shows how the GSM system has
been successful and why it
is now being adopted in geographical areas other than Europe
(such as North America,
China, the Asia-Pacific region, and more recently, South
America). CDMA, which
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originated in North America, has also proliferated in South
America and later in the Asia-
Pacific region. TDMA remains to be widely deployed in North and
South America regions,
but it is expected to decline mostly because of the decisions
taken by few major NorthAmerican carriers to convert their TDMA
networks to GSM.
This second-generation system, widely deployed in the United
States, Canada, and SouthAmerica, goes by many names, including
North American TDMA, IS-136, and D-AMPS(Digital AMPS). For the sake
of clarity, we will refer to it as North American TDMA, as
well as simply TDMA, when the context makes it clear. TDMA has
been used in North
America since 1992 and was the first digital technology to be
commercially deployed there.As its name indicates, it is based on
Time Division Multiple Access. In TDMA the
resources are shared in time, combined with frequency-division
multiplexing (that is, when
multiple frequencies are used). As a result, TDMA offers
multiple digital channels using
different time slots on a shared frequency carrier. Each mobile
station is assigned both aspecific frequency and a time slot during
which it can communicate with the base station.
The TDMA transmitter is active during the assigned time slot and
inactive during othertime slots, which allows for power-saving
terminal designs, among other advantages. North
American TDMA supports three time slots, at 30 kHz each, further
divided into three or six
channels to maximize air interface utilization. A sequence of
time-division multiplexed
time slots in TDMA makes up frames, which are 40 ms long. The
TDMA traffic channeltotal bit rate is 48.6 Kbps. Control overhead
and number of users per channel, which is
greater than one, decrease the effective throughput of a channel
available for user traffic to
13 Kbps. TDMA is a dual-band technology, which means it can be
deployed in 800-MHzand 1900-MHz frequency bands. In regions where
both AMPS and TDMA are deployed,
TDMA phones are often designed to operate in dual mode, analog
and digital, in order to
offer customers the ability to utilize coverage of the existing
analog infrastructure.
Global System for Mobile Communications (GSM)
There are still some analog cellular systems in operations in
Europe, but their number is
declining, and some regional networks are being completely shut
down or converted to
Global System for Mobile Communications. The GSM cellular system
initiative wasinitiated in 1982 by the Conference of European Posts
and Telecommunications
Administrations (CEPT) and is currently governed by European
Telecommunications
Standards Institute (ETSI), which in turn has delegated GSM
specifications maintenance
and evolution to 3GPP (reviewed in part in Chapter 1). The
intent behind GSMintroduction was to have a common approach to the
creation of digital systems across
European countries, to allowamong other advantages of a common
standardeasy
international roaming and better economies of scale by
decreasing handset andinfrastructure components costs through mass
production. In hindsight, this was a smart
political decision, which contributed to the worldwide success
of European cellular
infrastructure providers and equipment manufacturers.
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2.5g Cellular Systems
"2.5G" is an informal term, invented solely for marketing
purposes, unlike "2G" or "3G"
which are officially defined standards based on those defined by
the InternationalTelecommunication (ITU). The term "2.5G" usually
describes a 2G cellular system
combined with General Packet Radio Services (GPRS), or other
services not generally
found in 2G or 1G networks.Wireless telecommunication technology
like CDMA200 1x-RTT, Enhanced Data Rates for GSM Evolution (EDGE)
or Enhanced General Packet
Radio Service (EGPRS), since they have data transmission rates
of 144 kbps or higher,
may qualify as 3G technology. However, they are usually
classified as 2.5G technology
because they have slower network speeds than most 3G
services.
GPRS is a service commonly associated with 2.5G technology. It
has data transmissionrates of 28 kbps or higher. GPRS came after
the development of the Global System for
Mobile (GSM) service, which is classified as 2G technology, and
it was succeeded by thedevelopment of the Universal Mobile
Telecommunication Service (UMTS), which is
classified as 3G technology.A 2.5G system may make use of 2G
system infrastructure, but
it implements a packet-switched network domain in addition to a
circuit-switched domain.This does not necessarily give 2.5G an
advantage over 2G in terms of network speed,
because bundling of timeslots is also used for circuit-switched
data services (HSCSD).
The services and infrastructure of a 2.5G network may be used on
a per-transaction basis
rather than a per-minute-of-use basis, thanks to its
packet-switched domain. This makes its
infrastructure more efficient and improves the service delivery.
This impetus is known asthe "always-on" capability.2.5G networks
may support services such as WAP, MMS, SMSmobile games, and search
and directory.
3G Cellular Systems
Cell phones and systems are classified by the generation they
belong to. Third generation
(3G) phones were developed in the late 1990s and 2000s. The goal
was to improve the data
capability and speed. 3G phones were defined by the Third
Generation Partnership Project
(3GPP) and later standardized by the ITU-T. Generally known as
the Universal MobileTelecomunications System (UMTS), this 3G system
is based on wideband CDMA that
operates in 5 MHz of bandwidth and can produce download data
rates of typically 384 kb/sunder normal conditions and up to 2 Mb/s
in some instances. Another 3G standard,
cdma2000, was developed by Qualcomm. It uses 1.25 MHz bands to
produce data rates to
2 Mb/s. Another version of cdma2000 is an improved IS-95
version. It is a 3GPP2
standard. It can transmit data at a rate to 153 kb/s and up to 2
Mb/s in some cases.
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3G phone standards have been expanded and enhanced to further
expand data speed and
capacity. The WCDMA phones have added high speed packet access
(HSPA) that use
higher level QAM modulation to get speeds up to 21 or 42 Mb/s
downlink (cell site tophone) and up to 7 and/or 14 Mb/s uplink
(phone to cell site). AT&T and T-Mobile use
HSPA technology. The cdma2000 phones added 1xRTT as well as Rev.
A and Rev B
modifications that boost speed as well. Verizon and Sprint use
cdma2000 3G standardtechnology. Virtually all standard and
smartphone models and most tablets still use someform of 3G.
Fig 1.12 3G operating environments
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Table 1.1 3G characteristics by cell size and mobile speed
4G Cellular Systems and Beyond
The fourth generation has been defined but we are not in it,
yet. Yes, many if not most ofthe mobile carriers and the various
phone and equipment manufacturers actually advertise
4G now. The formal definition of 4G as declared by the 3GPP and
the ITU-T is something
called Long Term Evolution-Advanced (LTE-A). The standard has
not been fullycompleted but basically it is an improved and
enhanced version of LTE that uses wider
bandwidth channels and a greater number of MIMO antennas. The
theoretical upper data
rate is 1 Gb/s. That remains to be seen in practice.
As for what the various companies are calling 4G, Verizon says
that their LTE network is
4G. AT&T promotes their LTE and HSPA networks as 4G.
T-Mobile indicates that their
HSPA+ networks are 4G. Furthermore Sprint and Clearwire say that
their WiMAXnetwork is 4G. As mentioned, WiMAX is actually defined
as a 3G technology by ITU-T
like LTE.
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UNIT - 2
Common Cellular System components, Common cellular network
components, Hardware
and software, views of cellular networks, 3G cellular systems
components, Cellularcomponent identification Call
establishment.
6 Hours
TEXT BOOK:
1. Wireless Telecom Systems and networks, Mullet: Thomson
Learning 2006.
REFERENCE BOOKS:
1. Mobile Cellular Telecommunication, Lee W.C.Y, MGH, 2002.
2. Wireless communication- D P Agrawal: 2nd
Edition Thomson learning 2007.3. Fundamentals of Wireless
Communication, David Tse, Pramod Viswanath,
Cambridge 2005.
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UNIT-2
COMMON CELLULAR SYSTEM COMPONENTSIt is very much essential to
implement increased system functionality to meet the demands
of the increasing number of subscribers with the more
sophisticated wireless cellular
network. To achieve this the various hardware network elements
used to create the wireless
cellular network plays an important role.The network element
scan be divided into three basic groups
1.The mobile or subscriber device (providers the user link to
the wireless network.
2.Base station ( provides wireless system links to the
subscriber over air interface)3.Network switching system (provides
interface to the PSTN and PDN )
2.1 COMMON CELLULAR NETWORK COMPONENTS
Fig 2.1 Typical wireless cellular system componentsDuring 1G
wireless cellular system , it consists of several subsystems to
perform certain
operations in support of the entire system. For 2G and 2.5G
cellular networks , the air
interface functions are performed by fixed Radio Base Station
and Mobile Station orSubscriber device that provide user mobility.
The radio base station is controlled by a base
station controller which is referred as base station system.The
base station system is connected to a fixed switching system that
handles the routing of
both voice calls and data services to and from the mobile
switching centre and various
databases and functional nodes to support the mobility
management and security operations
of the system. The switching system is usually connected to the
PSTN , the PDN , otherpublic land mobile networks(PLMN ) and
various data messaging networks through gate
way switches.
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The various network elements that make up the wireless system
are interconnected by
communication links that transport system messages between
network elements to facilitate
network operations and deliver the actual voice call or data
services information.SUBSCRIBER DEVICES:
The subscriber device is the link between the customer and the
wireless network. The SD
must be able to provide a means for the subscriber to control
and input information to thephone and display its operation
status.
Fig 2.2 subscriber device
The subscriber device must be able to sample , digitize and
process audio and othermultimedia signals, transmit and receive RF
signals, process system control messages and
provide the power needed to operate the complex electronics
subsystems .
A SD consists of man machine interface, an RF transceiver
section a signal processingsection , a system control processor and
a power supply/ management section.
BASE STATION SYSTEM COMPONENTS:
The Base station system handles all radio interface related
functions for the wirelessnetwork .The BSS consists of several to
many radio base stations , a base station
contr5oller , Transcoder controller .The radio equipment
required to serve one cell is
typically called a base transceiver system. A single radio base
station might contain three
base transceiver systems which is used to serve a cell site that
consists of three 120 degreesectors or cells.
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Fig 2.3 components of base station system
Typical CDMA wireless system
The base station controller functions as the interface between
mobile switching centre and
packet core network and all the radio base stations controlled
by BSC. The BSC systemprovides timing signals and connectivity to
every subsystem within it and computer
interfaces to the entire system. The BSC will supply signaling
towards the MSC using
message transfer part protocol to transfer the message over a
PCM link connected to SS7signaling terminals located within MSC and
the BSC.
The TRC consists of subsystems that perform transcoding and rate
adaptation which can be
either stand alone or combined.REGISTERS IN WIRELESS
SYSTEMS:VISITOR LOCATION REGISTER:It is a database that temporarily
stores information about any mobile station that attaches to
a RBS in the area services by a particular MSC. This temporary
subscriber information is
required by the MSC to provide service to a visiting subscriber
.HOME LOCATION REGISTER:
It is a data base that stores information about every user that
has a cellular service contractwith specific wireless service
provider . This database stores permanent data about the
networks subscribers, information about the subscribers present
location. The HLR alsoplays a major role in the process of handling
calls terminating at the MS. The HLR
analyzes the information about the incoming call and controls
the routing of the call.
AUC Interconnection:
The AUC provides authentication and encryption information for
the MS being used in thecellular network. Upon a request from a VLR
the HLR will be delivered a triplet for a
particular mobile subscriber .the HLR receives the triplet
information in response to a
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request to the AUC for verification of a subscriber. The HLR
forwards the random
number and returns it to the MSC/VLR and from there to the HLR
.The AUC contains a
processor, a database for the storage of key information for
each subscriber maintenancefunctions for subscriber and an
interface fro communication with HLR.
EQUIPMENT IDENTITY REGISTER:
Then EIR database is used to validate then status of mobile
equipment . This globaldatabase is updated daily to reflect the
current status of an MS. The MS can be black listedindicating that
it has been reported stolen or missing and does not approve for
network
operation.
INTERWORKING UNITS:
IWUs are required to provide an interface to various data
networks. These nodes are used
to connect the base station controller and hence the radio base
stations to various data
services networks.
GATEWAYS and its types
1. Gateway MSC: (GMSC)gateway MSC is an MSC that interfaces the
wirelessmobile network to other telecommunication networks. A
cellular network will have
numerous MSCs to facilitate coverage of large area but all
switching centers need to
be connected to other wireline network .to support its function
as gateway the
GMSC will have ability to reroute a call to an MS using the
information provided
by the HLR of a subscriber.
2. Billing gateway : (BGW) this collects billing information
from various wireless
network elements which becomes a file use by customer
administrative system to
generate billing information for the system subscribers like
monthly access fees,
home usage , roaming , data and special services etc.,
3. Service order Gateway :(SOG) It is used to connect a customer
administrative
system to the switching system. This system is used to input new
subscriber data to
the HLR or to update current subscriber data already contained
in the HLR. The
SOG allows access to the AUC and EIR for equipment
administration. When a
customer signs a service contract with cellular service provider
the information
about the contract is entered into the customer administrative
system.
2.2 HARDWARE AND SOFTWARE VIEWS OF CELLULAR NETWORK: Hardware
view of a cellular network
Serving areas
Cells
MSC boundaries
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Fig 2.4 Hardware view of cellular network
Software view of a cellular network
Location area identity
Cell global identity
Mobile country code and network code
Fig 2.5 Software view of Cellular system
2.3 3G Cellular System Components Core network
Radio access network
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Radio network controller
Radio base station
Fig 2.6 The 3G radio network controller
2.4
Cellular Component Identification
Subscriber device identification
Mobile station ISDN identification number
North American version
The rest of the world
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Fig 2.6 Formation of MSISDN number Cellular Component
Identification
International mobile subscriber identity
Fig 2.7 Formation of IMSI number
International mobile equipment identity
Fig 2.8 Formation of IMEI number
Cellular system component addressing
Location area identity
Cell global identity
Radio base station identity code
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Location numbering
Addressing cellular network switching nodes
Global title and global title translation
2.5 Call Establishment
Mobile-terminated call
PSTN messages
GMSC operations
MSC/VLR operations
BSC operations
Fig 2.9 Mobile terminated call operations
Mobile-originated call
Mobile operations
Radio base station operations
Base station controller operations
MSC operations
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Fig 2.10 Mobile originated call operations Call release
Connection management operations
Radio resource operations
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Fig 2.11 Call release
The above figure shows the operation during release of a mobile
call through MSC . the
steps involved as shown in detail which is self explanatory.
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UNIT - 3
Wireless network architecture and operation, Cellular concept
Cell fundamentals, Capacity
expansion techniques, Cellular backbone networks, Mobility
management, Radio resources
and power management Wireless network security
6 Hours
TEXT BOOK:
1. Wireless Telecom Systems and networks, Mullet: Thomson
Learning 2006.
REFERENCE BOOKS:
1. Mobile Cellular Telecommunication, Lee W.C.Y, MGH, 2002.
2. Wireless communication- D P Agrawal: 2nd
Edition Thomson learning 2007.
3. Fundamentals of Wireless Communication, David Tse, Pramod
Viswanath,
Cambridge 2005.
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UNIT-3
WIRELESS NETWORK ARCHITECTURE AND OPERATION
3.1 The Cellular ConceptSolves the problem of spectral
congestion and user capacity,Offer very high capacity ina limited
spectrum without major technological changes,Reuse of radio channel
in
different cells.Enable a fix number of channels to serve an
arbitrarily large number of
users by reusing the channel throughout the coverage
region.Simplex and duplex
Each cellular base station is allocated a group of radio
channels within a smallgeographic area called a cell.Neighboring
cells are assigned different channel groups.
By limiting the coverage area to within the boundary of the
cell, the channel groups
may be reused to cover different cells.Keep interference levels
within tolerable limits.Frequency reuse or frequency planning seven
groups of channel from A to G.footprint
of a cell - actual radio coverage ,omni-directional antenna v.s.
directional antenna
Steps for frequency reuse:
Consider a cellular system which has a total of Sduplex
channels. Each cell is allocated a group of kchannels, . The
Schannels are divided amongNcells. The total number of available
radio channels
TheNcells which use the complete set of channels is called
cluster. The cluster can be repeated M times within the system. The
total number of
channels, C, is used as a measure of capacity
The capacity is directly proportional to the number of
replicationM. The cluster size,N, is typically equal to 4, 7, or
12. SmallNis desirable to maximize capacity. The frequency reuse
factor is given by Hexagonal geometry has
exactly six equidistance neighbors
the lines joining the centers of any cell and each of its
neighbors areseparated by multiples of 60 degrees. Only certain
cluster sizes and cell layout are possible. The number of cells per
cluster,N, can only have values which satisfy Co-channel neighbors
of a particular cell, ex, i=3andj=2.
The Cellular Concept Cellular hierarchy
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Picocells Microcells Macrocells Megacells and femtocells
Fig 3.1 Cellular concept
3.2 Cell Fundamentals The use of hexagons
Reuse number Cellular reuse patterns
Fig 3.2 Frequency reuse concept
Frequency reuse scheme increases capacity
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minimize interference Channel assignment strategy
fixed channel assignment dynamic channel assignment
Fixed channel assignment
each cell is allocated a predetermined set of voice channel any
new call attempt can only be served by the unused channels the call
will be blockedif all channels in that cell are occupied
Dynamic channel assignment channels are not allocated to cells
permanently. allocate channels based on request. reduce the
likelihood of blocking, increase capacity.
Cell Fundamentals Reuse number
Frequency reuse distance The reuse distance can be calculated by
using the equation:
Fig 3.3 Frequency Reuse number
Cell Fundamentals Cellular interference issues
Signal-to-interference ratio Channel assignments
Fig 3.4 Cellular calculations
3.3 Capacity Expansion Techniques
Cell splitting
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Split congested cell into smaller cells. Preserve frequency
reuse plan. Reduce transmission power.
Transmission power reduction from to Examining the receiving
power at the new
and old cell boundary
If we take n = 4and set the received power equal to each
other
The transmit power must be reduced by 12 dB in order to fill in
the originalcoverage area.
Problem: if only part of the cells are splited Different cell
sizes will exist simultaneously
Handoff issues - high speed and low speed traffic can be
simultaneouslyaccommodated
Fig 3.5 cell splitting
Capacity Expansion Techniques Cell sectoring
Sectoring concept
Decrease the co-channel interference and keep the cell
radiusRunchanged Replacing single omni-directional antenna by
several directional antennas Radiating within a specified
sector
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Fig 3.6 Cell sectoring
Capacity Expansion Techniques Overlaid cells
Overlay concept
Fig 3.7 Cell overlaid
Capacity Expansion Techniques Channel allocation Other capacity
expansion schemes
Lees microcell technology Smart antenna technology Migration to
digital technology
3.4 Cellular Backhaul Networks Introduction Standards for PSTN
carriers
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Fig 3.8 cellular backhaul network
Fig 3.9 cellular backhaul network
3.5 Mobility Management
Location management Need Frequency Location updating
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Fig 3.10 Location management in cellular network
Mobility Management Paging messages Different paging schemes
Transmission of the location information between network
elements
Mobility Management Handoff management
Handoff control Handoff operation
Handoff algorithm
When a mobile moves into a different cell while a conversation
is in progress, theMSC automatically transfers the call to a new
channel belonging to the new base
station.
Handoff operation identifying a new base station re-allocating
the voice and control channels with the new base station.
Handoff Threshold Minimum usable signal for acceptable voice
quality (-90dBm to -100dBm) Handoff margin cannot be too large or
too small.
If it is too large, unnecessary handoffs burden the MSC If it is
too small, there may be insufficient time to complete handoff
before
a call is lost.
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Fig 3.10 Mobility management in cellular network
Handoff must ensure that the drop in the measured signal is not
due to momentaryfading and that the mobile is actually moving away
from the serving base station.
Running average measurement of signal strength should be
optimized so thatunnecessary handoffs are avoided.
Depends on the speed at which the vehicle is moving. Steep short
term average -> the hand off should be made quickly The speed
can be estimated from the statistics of the received short-term
fading signal at the base station
Dwell time: the time over which a call may be maintained within
a cell withouthandoff.
Dwell time depends on propagation interference distance
speed
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Handoff measurement In first generation analog cellular systems,
signal strength measurements
are made by the base station and supervised by the MSC. In
second generation systems (TDMA), handoff decisions are mobile
assisted, called mobile assisted handoff (MAHO)
Intersystem handoff: If a mobile moves from one cellular system
to a differentcellular system controlled by a different MSC.
Handoff requests is much important than handling a new call.
Different type of users
High speed users need frequent handoff during a call.
Low speed users may never need a handoff during a call.
Microcells to provide capacity, the MSC can become burdened if
high speed users
are constantly being passed between very small cells. Minimize
handoff intervention handle the simultaneous traffic of high speed
and low speed users.
Large and small cells can be located at a single location
(umbrella cell) different antenna height different power level
Cell dragging problem: pedestrian users provide a very strong
signal to the basestation
The user may travel deep within a neighboring cell
Handoff for first generation analog cellular systems ,10 secs
handoff time, is in theorder of 6 dB to 12 dB,Handoff for second
generation cellular systems, e.g., GSM 1 to
2 seconds handoff time, mobile assists handoff , is in the order
of 0 dB to 6 dB
Handoff decisions based on signal strength, co-channel
interference, and adjacentchannel interference.
IS-95 CDMA spread spectrum cellular system ,Mobiles share the
channel in every
cell.No physical change of channel during handoff ,MSC decides
the base station withthe best receiving signal as the service
station Handoff within a cell, No channel re-
assignment, Switch the channel to a different zone site, Reduce
interference, Low
power transmitters are employed
Frequency reuse - there are several cells that use the same set
of frequencies co-channel cells co-channel interference
To reduce co-channel interference, co-channel cell must be
separated by aminimum distance.
When the size of the cell is approximately the same
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co-channel interference is independent of the transmitted power
co-channel interference is a function of
R: Radius of the cell D: distance to the center of the nearest
co-channel cell
Increasing the ratio Q=D/R, the interference is reduced.
Qis called the co-channel reuse ratio
Fig 3.11 Handoff management
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Fig 3.12 analysis of handoff operation
3.6 Radio Resources and Power Management
Power control Power saving schemes
Discontinuous transmission Sleep modes
Energy efficient designs Radio resource management
Need Schemes
3.7 Wireless Network Security
Wireless network security requirements Network security
requirements Network security
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UNIT - 4
GSM and TDMA techniques, GSM system overview, GSM Network and
systemArchitecture, GSM channel concepts, GSM identifiers
6 Hours
TEXT BOOK:
1. Wireless Telecom Systems and networks, Mullet: Thomson
Learning 2006.
REFERENCE BOOKS:1. Mobile Cellular Telecommunication, Lee W.C.Y,
MGH, 2002.
2. Wireless communication- D P Agrawal: 2nd
Edition Thomson learning 2007.
3. Fundamentals of Wireless Communication, David Tse, Pramod
Viswanath,
Cambridge 2005.
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Unit-4
GSM AND TDMA TECHNOLOGIES
4.1 Introduction to GSM and TDMA
Global System for Mobile Communications (GSM) servicesare a
standard collection of
applications and features available to mobile phone subscribers
all over the world. TheGSM standards are defined by the 3GPP
collaboration and implemented in hardware andsoftware by equipment
manufacturers and mobile phone operators. The common standard
makes it possible to use the same phones with different
companies' services, or even roam
into different countries. GSM is the world's most dominant
mobile phone standard.
The design of the service is moderately complex because it must
be able to locate a moving
phone anywhere in the world, and accommodate the relatively
small battery capacity,
limited input/output capabilities, and weak radio transmitters
on mobile devices.
In order to gain access to GSM services, a user needs three
things:
A billing relationship with a mobile phone operator. This is
usually either where
services are paid for in advance of them being consumed
(prepaid), or where billsare issued and settled after the service
has been consumed (postpaid).
A mobile phone that is GSM compliant and operates at the same
frequency as the
operator. Most phone companies sell phones from third-party
manufacturers.
A Subscriber Identity Module (SIM) card, which is activated by
the operator oncethe billing relationship is established. After
activation the card is then programmed
with the subscriber's Mobile Subscriber Integrated Services
Digital Network
Number (MSISDN) (the telephone number). Personal information
such as contactnumbers of friends and family can also be stored on
the SIM by the subscriber.
After subscribers sign up, information about their identity
(telephone number) and whatservices they are allowed to access are
stored in a "SIM record" in the Home Location
Register (HLR).
Once the SIM card is loaded into the phone and the phone is
powered on, it will search for
the nearest mobile phone mast (also called a Base Transceiver
Station/BTS) with the
strongest signal in the operator's frequency band. If a mast can
be successfully contacted,
then there is said to be coverage in the area. The phone then
identifies itself to the networkthrough the control channel. Once
this is successfully completed, the phone is said to be
attached to the network.
The key feature of a mobile phone is the ability to receive and
make calls in any area where
coverage is available. This is generally called roaming from a
customer perspective, but
also called visiting when describing the underlying technical
process. Each geographic areahas a database called the Visitor
Location Register (VLR), which contains details of all the
mobiles currently in that area. Whenever a phone attaches, or
visits, a new area, the Visitor
Location Register must contact the Home Location Register to
obtain the details for thatphone. The current cellular location of
the phone (i.e., which BTS it is at) is entered into
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the VLR record and will be used during a process called paging
when the GSM network
wishes to locate the mobile phone.
Every SIM card contains a secret key, called the Ki, which is
used to provide authentication
and encryption services. This is useful to prevent theft of
service, and also to prevent "over
the air" snooping of a user's activity. The network does this by
utilising the AuthenticationCenter and is accomplished without
transmitting the key directly.
Every GSM phone contains a unique identifier (different from the
phone number), calledthe International Mobile Equipment Identity
(IMEI). This can be found by dialing *#06#.
When a phone contacts the network, its IMEI may be checked
against the Equipment
Identity Register to locate stolen phones and facilitate
monitoring.
TDMA
It can be easily adapted to the transmission of data and voice
communication.TDMA offers the ability to carry data rates of 64
kbps to 120 Mbps (expandable in
multiples of 64 kbps). This enables operators to offer personal
communication-likeservices including fax, voiceband data, and short
message services (SMSs) as well as
bandwidth-intensive applications such as multimedia and
videoconferencing.
It will not experience interference from other simultaneous
transmissions
Unlike spread-spectrum techniques which can suffer from
interference among the
users all of whom are on the same frequency band and
transmitting at the same time,TDMAs technology, which separates
users in time, ensures that they will not
TDMA is the only technology that offers an efficient
utilization
of hierarchical cell structures (HCSs) offering pico, micro, and
macrocells. HCSsallow coverage for the system to be tailored to
support specific traffic and service
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needs. By using this approach, system capacities of more than
40-times AMPS can
be achieved in a cost-efficient way. TDMA allows service
compatibility with the use of
dual-mode handsets because of its inherent compatibility with
FDMA analog systems.
4.2 GSM Network and System ArchitectureMobile station
Subscriber identity module
Base station system
Network switching system
SMS gateway
Flexible numbering register
Operation and support system and other nodes
Administrative and control system
Fig 4.1 components of GSM network
GSM network interfaces and protocols
GSM interfaces
Abis interface
A interface
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Um interface
Layered structure/OSI model
Fig 4.2 interfaces in GSM
GSM network interfaces and protocols
GSM protocols and signaling model
Um interface
Abis interface
A interface
Ater interface
The network structure is defined within the GSM standards.
Additionally each interface
between the different elements of the GSM network is also
defined. This facilitates the
information interchanges can take place. It also enables to a
large degree that network
elements from different manufacturers can be used. However as
many of these interfaceswere not fully defined until after many
networks had been deployed, the level of
standardisation may not be quite as high as many people might
like.
1. Um in terf ace The "air" or radio interface standard that is
used for exchangesbetween a mobile (ME) and a base station (BTS /
BSC). For signalling, a modified
version of the ISDN LAPD, known as LAPDm is used.
2. Abis interf ace This is a BSS internal interface linking the
BSC and a BTS, and ithas not been totally standardised. The Abis
interface allows control of the radio
equipment and radio frequency allocation in the BTS.
3. A interf ace The A interface is used to provide communication
between the BSSand the MSC. The interface carries information to
enable the channels, timeslots
and the like to be allocated to the mobile equipments being
serviced by the BSSs.
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The messaging required within the network to enable handover etc
to be undertaken
is carried over the interface.
4. B in terf ace The B interface exists between the MSC and the
VLR . It uses aprotocol known as the MAP/B protocol. As most VLRs
are collocated with an
MSC, this makes the interface purely an "internal" interface.
The interface is used
whenever the MSC needs access to data regarding a MS located in
its area.5. C in terf ace The C interface is located between the
HLR and a GMSC or a SMS-G.When a call originates from outside the
network, i.e. from the PSTN or another
mobile network it ahs to pass through the gateway so that
routing information
required to complete the call may be gained. The protocol used
for communicationis MAP/C, the letter "C" indicating that the
protocol is used for the "C" interface. In
addition to this, the MSC may optionally forward billing
information to the HLR
after the call is completed and cleared down.
6. D in terf ace The D interface is situated between the VLR and
HLR. It uses theMAP/D protocol to exchange the data related to the
location of the ME and to the
management of the subscriber.
7. E in terf ace The E interface provides communication between
two MSCs. The Einterface exchanges data related to handover between
the anchor and relay MSCsusing the MAP/E protocol.
8. F interface The F interface is used between an MSC and EIR.
It uses the MAP/Fprotocol. The communications along this interface
are used to confirm the status ofthe IMEI of the ME gaining access
to the network.
9. G interf ace The G interface interconnects two VLRs of
different MSCs and usesthe MAP/G protocol to transfer subscriber
information, during e.g. a locationupdate procedure.
10.H interface The H interface exists between the MSC the SMS-G.
It transfers shortmessages and uses the MAP/H protocol.
11.I interf ace The I interface can be found between the MSC and
the ME. Messagesexchanged over the I interface are relayed
transparently through the BSS.
Although the interfaces for the GSM cellular system may not be
as rigorously defined asmany might like, they do at least provide a
large element of the definition required,
enabling the functionality of GSM network entities to be defined
sufficiently.
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Fig 4.3 GSM network interfaces and protocols
4.3 GSM Channel Concept Time division multiple access
Frames
Multiframes
A single GSM RF carrier can support up to eight MS subscribers
simultaneously. Eachchannel occupies the carrier for one eighth of
the time.
This is a technique called Time Division Multiple Access. Time
is divided into discreteperiods called timeslots . The timeslots
are arranged in sequence and are
conventionally numbered 0 to 7. Each repetition of this sequence
is called a TDMA
frame . Each MS telephone call occupies one timeslot (07) within
the frame until the
call is terminated, or a handover occurs.
The TDMA frames are then built into further frame structures
according to the type ofchannel. We shall later examine how the
information carried by the air interface builds into
frames and multi-frames and discuss the associated timing. For
such a system to work
correctly, the timing of the transmissions to and from the
mobiles is critical. The MS or
Base Station must transmit the information related to one call
at exactly the right moment,or the timeslot will be missed. The
information carried in one timeslot is called a
burst . Each data burst, occupying its allocated timeslot within
successive TDMA
frames, provides a single GSM physical channel carrying a
varying number of logicalchannels between the MS and BTS.
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Fig 4.4 TDMA time frame structure
GSM Channel Concept
Logical channels
Broadcast channels
Broadcast control channel
Frequency correction channel
Synchronization channel
Logical channels
Common control channels
Paging channel
Random access channel
Access grant channel
Dedicated control channels
Stand-alone dedicated control channel
Slow associated control channel
Fast associated control channel
Cell broadcast channel
Speech processing
Operations
Bit rate
GSM speech processing
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Fig 4.5 GSM processing of speech
Timeslots and TDMA frames
TDMA frames
TDMA multiframes
Hyperframes
Superframes
Multiframes
26 frame
51 frame
Timeslot bursts
Normal burst
Frequency correction burst
Synchronization burst
Access burst
Dummy burst
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Fig 4.6 TDMA Hyperframe structure
A hyperframe is a multiframe sequence that is composed of 2048
superframes and is
largest time interval in the GSM system (3 hours, 28 minutes, 53
seconds). Every time slotduring a hyperframe has a sequential
number (represented by an 11 bit counter) that is
composed of a frame number and a time slot number. This counter
allows the hyperframe
to synchronize frequency hopping sequence, encryption processes
for voice privacy ofsubscribers' conversations. The hyperframe in
an IS-136 TDMA system consists of 192
frames.
The basic GSM frame defines the structure upon which all the
timing and structure of theGSM messaging and signalling is based.
The fundamental unit of time is called a burst
period and it lasts for approximately 0.577 ms (15/26 ms). Eight
of these burst periods are
grouped into what is known as a TDMA frame. This lasts for
approximately 4.615 ms(i.e.120/26 ms) and it forms the basic unit
for the definition of logical channels. One
physical channel is one burst period allocated in each TDMA
frame.
In simplified terms the base station transmits two types of
channel, namely traffic andcontrol. Accordingly the channel
structure is organised into two different types of frame,
one for the traffic on the main traffic carrier frequency, and
the other for the control on thebeacon frequency.
GSM multiframe
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The GSM frames are grouped together to form multiframes and in
this way it is possible to
establish a time schedule for their operation and the network
can be synchronised.
There are several GSM multiframe structures:
Traff ic multifr ame: The Traffic Channel frames are organised
into multiframesconsisting of 26 bursts and taking 120 ms. In a
traffic multiframe, 24 bursts are used
for traffic. These are numbered 0 to 11 and 13 to 24. One of the
remaining bursts is
then used to accommodate the SACCH, the remaining frame
remaining free. Theactual position used alternates between position
12 and 25.
Control mul tif rame: the Control Channel multiframe that
comprises 51 bursts and
occupies 235.4 ms. This always occurs on the beacon frequency in
time slot zero
and it may also occur within slots 2, 4 and 6 of the beacon
frequency as well. Thismultiframe is subdivided into logical
channels which are time-scheduled.
GSM Superframe
Multiframes are then constructed into superframes taking 6.12
seconds. These consist of 51traffic multiframes or 26 control
multiframes. As the traffic multiframes are 26 bursts long
and the control multiframes are 51 bursts long, the different
number of traffic and control
multiframes within the superframe, brings them back into line
again taking exactly the
same interval.
GSM Hyperframe
Above this 2048 superframes (i.e. 2 to the power 11) are grouped
to form one hyperframewhich repeats every 3 hours 28 minutes 53.76
seconds. It is the largest time interval within
the GSM frame structure.
Within the GSM hyperframe there is a counter and every time slot
has a unique sequential
number comprising the frame number and time slot number. This is
used to maintainsynchronisation of the different scheduled
operations with the GSM frame structure. These
include functions such as:
Frequency hopping: Frequency hopping is a feature that is
optional within the
GSM system. It can help reduce interference and fading issues,
but for it to work,
the transmitter and receiver must be synchronised so they hop to
the samefrequencies at the same time.
Encryption: The encryption process is synchronised over the GSM
hyperframe
period where a counter is used and the encryption process will
repeat with eachhyperframe. However, it is unlikely that the
cellphone conversation will be over 3
hours and accordingly it is unlikely that security will be
compromised as a result.
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UNIT - 5
GSM system operation, Traffic cases, Cal handoff, Roaming, GSM
protocol architecture.
TDMA systems
6 Hours
TEXT BOOK:
1. Wireless Telecom Systems and networks, Mullet: Thomson
Learning 2006.
REFERENCE BOOKS:1. Mobile Cellular Telecommunication, Lee W.C.Y,
MGH, 2002.
2. Wireless communication- D P Agrawal: 2nd
Edition Thomson learning 2007.3. Fundamentals of Wireless
Communication, David Tse, Pramod Viswanath,
Cambridge 2005.
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UNIT-5
GSM SYSTEM OPERATIONS
5.1 GSM IdentitiesTo switch a call to a mobile subscriber, the
right identities need to be involved. It istherefore important to
address them correctly. Followings are those identities;
Mobile Station ISDN Number (MSISDN)
The MSISDN is a number, which uniquely identifies a mobile
telephone
subscription in the public switched telephone network numbering
plan. These arethe digits dialed when calling a mobile
subscriber.
The MSISDN is consisted with followings;
Country Code (CC)
National Destination Code (NDC)
Subscriber Number (SN)
MSISDN = CC + NDC + SN
International Mobile Subscriber Identity (IMSI)
The IMSI is a unique identity allocated to each subscriber to
allow correct
identification over the radio path and through the network and
is used for allsignaling in the PLMN. All network-related
subscriber information is connected to
the IMSI. The IMSI is stored in the SIM, as well as in the HLR
and in the serving
VLR.
The IMSI is consisted with followings;
Mobile Country Code (MCC)
Mobile Network Code (MNC)
Mobile Subscriber Identification Number (MSIN)
IMSI = MCC + MNC + MSIN
Temporary Mobile Subscriber Identity (TMSI)
The TMSI is a temporary number used instead of IMSI to identify
an MS. The
TMSI is used for the subscribers confidentiality on the air
interface. The TMSI has
only local significance (that is, within the MSC/VLR area) and
is changed at certain
events or time intervals.
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International Mobile Equipment Identity (IMEI)
The IMEI is used for equipment identification and uniquely
identifies a MS as a
piece or assembly of equipment.
The IMEI is consisted with followings;
Type Approval Code (TAC), determined by a central GSM body
Final Assembly Code (FAC), identifies the manufacture
Serial Number (SNR), uniquely identifies all equipment within
each TAC &
FAC
Spare, a spare bit for future use.
IMEI = TAC + FAC + SNR + Spare
Mobile Station Roaming Number (MSRN)
A MSRN is used during the call setup phase for mobile
terminating calls. Each
mobile terminating call enters the GMSC in the PLMN. The call is
then re-routedby the GMSC, to the MSC where the called mobile
subscriber is located. For this
purpose MSRN is allocated by the MSC and provided to the
GMSC.
The MSRN is consisted with followings;
Country Code (CC)
National Destination Code (NDC)
Subscriber Number (SN)
MSRN = CC + NDC + SN
Location Area Identity (LAI)
The LAI is used for paging, to indicate to the MSC in which
Location Area (LA)the MS is currently situated and also for
location updating of mobile subscribers.
The LAI is consisted with followings;
Mobile Country Code (MCC)
Mobile Network Code (MNC)
Location Area Code (LAC)
LAI = MCC + MNC + LAC
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Cell Global Identity (CGI)
Each cell is identified by cell identity (CI). A CI is unique
within a location area(LA).
CGI is consisted with following;
Mobile Country Code (MCC)
Mobile Network Code (MNC)
Location Area Code (LAC)
Cell Identity (CI)
CGI = MCC + MNC + LAC + CI
Base Station Identification Code (BSIC)
In GSM, the mobile station uses BSIC to distinguish between
neighboring basestation.
The BSIC is consisted with
Network Colour Code (NCC)
Base Transceiver Colour Code (BCC).
5.2 GSM System Operations (Traffic Cases)Registration, call
setup, and location updating
Call setup
Interrogation phase
Radio resource connection establishment
Service request
Authentication
GSM System Operations (Traffic Cases)
Call setup
Ciphering mode setting
IMEI check
TMSI reallocation
Call initiation procedure
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Assignment of a traffic channel
Call confirmation, call accepted, and call release
GSM System Operations (Traffic Cases)
Other aspects of call establishment
Location updating
Normal location updating (idle mode)
IMSI detach/attach location updating
Periodic location updating
Fig 5.1 GSM channel assignment
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Fig 5.2 GSM channel establishment
GSM System Operations (Traffic Cases)
Call handoff
Intra-BSC handover
The process that occurs during the handover intra BSC as
follows:
A). During the call, MS will measure the strength and quality of
the signal on the
TCH and the signal strength from the neighboring cell. MS to
evaluate and assessthe average for each cell.
MS send the results to the BTS measurements every two times in
one second cell
not only on their own but also the results of measurements from
the BTS
neighboring cell.
B). The BTS will send the results of measurements on the TCH to
the BSC. In the
BSC, the function is activated when the placement is required to
handover to
another cell.
C). When the handover is done, BSC will check whether the
channel had requested
be met by another cell, if not the BSC will be the new BTS to
enable TCH.
D). BSC will ask the BTS for a long time to send a message to MS
with information
about the frequency, time slot, and the output power for the
change.
E). MS choose a new frequency handover and access to the
appropriate time slot.
F). When the BTS to detect the handover, the BTS will send the
informationcontains the physical "timing advance" (the distance
between MS to the BTS) to
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MS. BTS also inform the BSC to send a "message HO detection" so
that point on
the new GS is connected.
G). MS send a "HO complete message."
H). Last time the BTS ordered not to activate the old TCH.
Fig 5.3 Intra BSC handover
Inter-BSC handoverIn this case BSC1, (old BSC) does not control
the better cell which is the target for
the handover. This means that the MSC will be part of the link
procedure between
BSC1 and BSC2 (new BSC).Handover request - BSC1 will use the MSC
to send a handover request to
BSC2. The MSC will know which BSC controls that cell.Activation
of new channel - BSC2 will allocate a TCH in the targetcell and
thenorder the BTS to activate it. The chosen HO ref. no. will be
part of the activation
message. The BTS will acknowledge that the activation has been
made.
Handover command - After the activation the new BSC commands the
MS tochange to the new channel. The message is sent on FACCH via
the old channel and
will contain a full description of the new channel and the HO
ref. no.
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3. Handover bursts - When the MS has changed to the new channel,
it will send
handover bursts on the new channel. The information content is
the HO ref. no.
The bursts are as short as the access bursts. This is because
the MS does not knowthe new Timing Advance (TA) value yet. On the
detection of the handover bursts,
and check of HO ref. no., the new BTS will send the new TA.
4. Handover complete - Now the MS is ready to continue the
traffic and willsend a handover complete message, which will be
addressed to the old BSC as
a clear command.
5. Release of old channel - When the old BSC receives the clear
command
from the MSC, the BSC knows that the handover was successful.
The BSC
orders the BTS to release the TCH and the BTS will
acknowledge.
Fig 5.4 Inter BSC handover
Inter-MSC handover
Handing over a GSM call is a complicated procedure. It is even
more so when thesource and target GSM cells are controlled by
different MSCs. The following call flows
analyze the different steps involved in a inter-MSC
handover:
The source BSC analyzes the signal quality measurement reports
and initiates a
handover.
The source MSC finds that the call needs to be handed over to a
cell controlled by adifferent MSC.
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The source MSC and target MSC interact and then command the UT
to move to the
new cell.
The target MSC informs the source MSC when the call has been
successfullyhanded over.
The source MSC releases the radio resources for the call. Note
that the call is still
routed via the source MSC
Fig 5.5 Inter MSC handover
GSM Infrastructure Communications (Um Interface)
A GSM network is a bearer data communication protocol families.
Any protocol stackfor data communication, for example TCP/IP, can
be implemented to use a bearer.
GSM protocol architecture is - as for ISDN - structured into
three independent planes .
User plane ,Control plane,Management plane
The user plane defines protocols to carry connection oriented
voice and user data. At
the radio interface Um, user plane data will be carried by the
logical traffic channel
called TCH. The control plane defines a set of protocols for
controlling these
connections with signalling information, for example signalling
for connection setup.Such signalling data is carried over logical
control channels called D-channels (Dm-
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channels). As the control channels often have spare capacities,
also user data, the
packet oriented SMS data, is transported over these channels
(see Figure gsm8). All
logical channels, however, will be finally multiplexed onto the
physical channel.
Management plane function are:
plane management functions related to the system as a whole
including planecoordination
functions related to resources and parameters residing in the
layers of the control
and/or user plane.
Management of network element configuration and network element
faults are
examples of management plane functionality
The basic GSM bearer service, Circuit Switched Data (CSD),
simply consists of
transmitting and receiving signals representing data instead of
voice across the airinterface. Modems are used for the conversion
between data bit streams and modulated
radio signals. Data transmission is either transparent or
non-transparent.
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Fig: 5.6 Three layers of interface in GSM
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Fig: 5.7 Linking of Three layers of interface in GSM
GSM Infrastructure Communications (Um Interface)
Layer 3: Networking layer operations
Connection management
Mobility management
Radio resource management
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Fig: 5.8 Linking of RR, RM and MM in GSM
GSM Infrastructure Communications (Um Interface)
Layer 2: Data Link layer operations
LAPD operations
Service access points
Data link procedures
Physical services required by the Data Link layer
Data link timers
North American TDMA
TIA/EIA-136 basics
TIA/EIA-136 channel concept
TIA/EIA-136 timeslots and frame details
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Fig: 5.9 NA -TDMA structure
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UNIT - 6
CDMA technology, CDMA overview, CDMA channel concept CDMA
operations.
8 Hours
TEXT BOOK:
1. Wireless Telecom Systems and networks, Mullet: Thomson
Learning 2006.
REFERENCE BOOKS:
1. Mobile Cellular Telecommunication, Lee W.C.Y, MGH, 2002.
2. Wireless communication- D P Agrawal: 2nd
Edition Thomson learning 2007.3. Fundamentals of Wireless
Communication, David Tse, Pramod Viswanath,
Cambridge 2005.
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UNIT- 6
CDMA TECHNOLOGY
6.1 Introduction to CDMA
Cellular services are now being used every day by millions of
people worldwide. Thenumber of customers requiring such services is
increasing exponentially, and there is a
demand for integration of a variety of multimedia services. The
range of services includes
short messaging, voice, data, and video. Consequently, the bit
rate required for the services
varies widely from just 1.2 kbps for paging up to several Mbps
for video transmission.Furthermore, supporting such a wide range of
data rates with flexible mobility management
increases network complexity dramatically.
The CDMA is a digital modulation and radio access system that
employs signature codes(rather than time slots or frequency bands)
to arrange simultaneous and continuous access
to a radio network by multiple users. Contribution to the radio
channel interference inmobile communications arises from multiple
user access, multipath radio propagation,
adjacent channel radiation and radio jamming.
The spread spectrum systems performance is relatively immune to
radio interference. Cell
sectorisation and voice activity used in CDMA radio schemes
provide additional capacity
compared to FDMA and TDMA. However, CDMA still has a few
drawbacks, the main onebeing that capacity (number of active users
at any instant of time) is limited by the access
interference. Furthermore, Near-far effect requires an accurate
and fast power control
scheme. The first cellular CDMA radio system has been
constructed in conformity with IS-95 specifications and is now
known commercially as cdmaOne.
Fig 6.1 comparison of different techniques
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Fig 6.2 channel allocation
6.2 CDMA Network and System Architecture
There is increasing demand for data traffic over mobile radio.
The mobile radio industry has toevolve the current radio
infrastructures to accommodate the expected data traffic with the
efficientprovision of high-speed voice traffic. The General Packet
Radio Service (GPRS) is being introduced
to efficiently support high-rate data over GSM. GPRS signalling
and data do not travel throughGSM network. The GPRS operation is
supported by new protocols and new network nodes:Serving GPRS
support node (SGSN) and Gateway GPRS support node (GGSN). One
prominentprotocol used to tunnel data through IP backbone network
is the GPRS tunnel protocol (GTP).GPRS obtains user profile data
using location register database of GSM network. GPRS
supportsquality of service and peak data rate of up to 171.2 kbps
with GPRS using all 8 timeslots at thesame time. GPRS uses the same
modulation as that used in GSM, that is Gaussian Minimum
ShiftKeying (GMSK) with 4 coding schemes. GPRS packetises the user
data and transports it over 1 to8 radio channel timeslots using IP
backbone network.
The Enhanced Data Rates for GSM Evolution (EDGE) employs an
Enhanced GPRS (EGPRS) tosupport data rate up to 384 kbps through
optimised modulation. EGPRS support 2 modulationschemes, namely
GMSK with 4 coding schemes and 8-PSK with 5 coding schemes. Unlike
GPRS
where header and data are encoded together, headers are encoded
separately in EGPRS.
Fig 6.3 Network architecture of CDMA
CDMA Network and System Architecture
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Mobile-services switching center and visitor location register
Interworking function Mobile positioning system Unified
messaging/voice mail service HLR/AC, PPCS, and other nodes
Fig 6.3 Packet Network architecture of CDMA
6.2 CDMA Network and System Architecture
Base station subsystem Base station controller Radio base
station
PLMN subnetwork Circuit core network CDMA radio access
network
CDMA Network and System Architecture
PLMN subnetwork Packet core network
AAA server Home agent Packet data serving node Foreign agent
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Fig 6.5 Packet core Network architecture of CDMA
CDMA Network and System Architecture Network management
system
Network management Subnetwork management and element
management
System communications links
Fig 6.6 Network interface architecture of CDMA
6.3 CDMA Channel Concept
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Introduction to Walsh codes
Characteristics Other pseudorandom noise codes Short and long PN
codes
Spreading procedure
Fig 6.7 CDMA channel concept
The IS-95 CDMA system is a narrow band radio system. Bandwidth
is limited to 1.25 MHzand a chip rate of 1.2288 Mcps. The system is
intended to provide voice and low bit ratedata service using
circuit-switching techniques. Data rate varies from 1.2 kbps to 9.6
kbps.
Forward (base station to mobile) and reverse (mobile to base
station) link structures are
different and each is capable of distinctive capacity. Forward
transmission is coherent andsynchronous while the reverse link is
asynchronous. The 'chanellisation' in each link is
achieved by using 64- chip orthogonal codes, including provision
for pilot,
synchronisation, paging, and network access. Consequently, the
number of active users
able to simultaneously access the network is limited by the
level of interference, serviceprovisions and the number of
'channels' available. In IS-95B, an active mobile always has a
fundamental code channel at 9.6 kbps and when high data rate is
required, the base station
assign the mobile up to 7 supplementary code channels.
The Wideband CDMA (W-CDMA) system is the major standard in the
next-generation
Global Mobile Telecommunications standard suite IMT-2000. The
W-CDMA supports
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high data rate transmission, typically 384 kbps for wide area
coverage and 2 Mbps for local
coverage for multimedia services. Thus W-CDMA is capable of
offering the transmission
of voice, text, data, picture (still image) and video over a
single platform. However, inaddition to the drawbacks arising from
the mobile environment and multiple access
interference, high bit rate transmission causes Inter-symbol
interference (ISI) to occur. The
ISI therefore has to be taken into account during transmission.
The W-CDMA has 2versions: frequency division duplex (FDD) and time
division duplex (TDD).
The FDD version of W-CDMA will operate in either of the
following paired bands:
Uplink: 1920 - 1980 MHz Downlink: 2110 - 2170 MHz
Uplink: 1850 - 1010 MHz Downlink: 1930 - 1990 MHz
The 3GPP architecture of the Universal Mobile Telecommunications
System (UMTS) iscomposed of IP-based core network (CN) connected to
the user equipment through UMTS
Terrestrial Radio Access Network (UTRAN). The UTRAN consists of
a set of radionetwork subsystem comprising a radio controller and
one or more node base station. Thenetwork controller is responsible
for the handover decisions that require signalling to the
user equipment. Each subsystem is responsible for the resources
of its set of cells and each
node B has one or more cells.
Fig 6.8 Walsh code in CDMA
CDMA Channel Concept
Forward logical channels Pilot channel Synchronization channel
Paging channel Traffic/power control channels
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Fig 6.9 I channel pilot signals
Fig 6.10 Power control systems
CDMA Channel Concept
Reverse logical channels Differences from forward channel
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