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CHAPTER NO. 6

MULTIPLE ACCESS TECHNIQUES FOR MOBILE COMMUNICATION

Frequency Division Multiple Access (FDMA)

Time Division Multiple Access (TDMA)

Code Division Multiple Access (CDMA)

These multiple access systems have very different approaches to the bandwidth problem.

6.1: FREQUENCY DIVISION MULTIPLE ACCESS (FDMA)

Each FDMA subscriber is assigned a specific frequency channel (Fig. 6.1). No one

else in the same cell or a neighboring cell can use the frequency channel while it is

assigned to a user. This reduces interference, but severely limits the number of users.

FIG. NO. 6.1 FREQUENCY DIVISION MULTIPLE ACCESS (FDMA)

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Frequency-division multiplexing (FDM) advantage of the fact that the useful bandwidth of

the medium exceeds the required bandwidth of a given signal

6.2: TIME DIVISION MULTIPLE ACCESS (TDMA)

TDMA users share a common frequency channel (Fig. 6.2), but use the channel for

only a very short time. They are each given a time slot and only allowed to transmit during

that time slot. When all available time slots in a given frequency are used, the next user

must be assigned a time slot on another frequency. These time slices are so small that the

human ear does not perceive the time slicing

FIG. NO. 6.2: TIME DIVISION MULTIPLE ACCESS (TDMA)

Time-division multiplexing (TDM) takes advantage of the fact that the achievable bit rate

of the medium exceeds the required data rate of a digital signal

6.3: CODE DIVISION MULTIPLE ACCESS (CDMA)

Code-Division Multiple Access (CDMA) is one of the most important concepts to

any cellular telephone system is that ofmultiple access.A large number of users share acommon pool of radio channels and any user can gain access to any channel. In other

words CDMA is a form ofmultiplexing, which allows numerous signals to occupy a single

transmission channel, optimizing the use of available bandwidth. Though CDMAs

application in cellular telephone is relatively new, but it is not a new technology. CDMA

has been used in many military applications, such as anti-jamming (because of the spread

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6.4: GENERATING A CDMA SIGNAL

There are five steps in generating a CDMA signal (Fig. 6.4).

I. Analog to digital conversion

II. Vocoding

III. Encoding and interleaving

IV. Channelizing the signals

V. Conversion of the digital signal to a Radio Frequency (RF) signalThe use of codes is a key part of this process.

FIG. NO. 6.4: GENERATING A CDMA SIGNAL

(I) ANALOG TO DIGITAL CONVERSION

The first step of CDMA signal generation is analog to digital conversion,

sometimes called A/D conversion. CDMA uses a technique called Pulse

Code Modulation (PCM) to accomplish A/D conversion.

(II) VOCODING (or Voice Compression)

The second step ofCDMA signal generation is voice compression. CDMA

uses a device called a vocoder to accomplish voice compression (Fig. 6.5).

The term "vocoder" is a contraction of the words "voice" and "code."

Vocoders are located at the BSC and in the phone.A CDMA vocoder variescompression of the voice signal into one offour data rates based on the rate

of the user's speech activity. The four rates are: Full, 1/2, 1/4 and 1/8. The

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vocoder uses its full rate when a person is talking very fast. It uses the 1/8

rate when the person is silent or nearly so.

FIG. NO. 6.5: GENERATING AN A/D COMPRESSED SIGNAL

(III) ENCODING AND INTERLEAVING

Encoders and interleavers are built into the BTS and the phones. The

purpose of the encoding and interleaving is to build redundancy into the

signal so that information lost in transmission can be recovered. The type of

encoding done at this stage is called "convolutional encoding." A simplified

encoding scheme is shown here. A digital message consists offour bits (A,

B, C, D) ofvocoded data. Each bit is repeated three times. These encoded

bits are called symbols. The decoder at the receiver uses a majority logic

rule. Thus, if an error occurs, the redundancy can help recover the lost

information.

EXAMPLE:

BURST ERROR: A burst error is a type of error in received digital

telephone signals. Burst errors occur in clumps ofadjacent symbols. These

errors are caused by fading and interference. Encoding and interleaving

reduce the effects of burst errors. Interleaving is a simple but powerful

method ofreducing the effects of burst errors and recovering lost bits. In the

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example shown in the Fig. 6.6, the symbols from each group are interleaved

(or scrambled) in a pattern that the receiver knows.De-interleaving at the

receiver unscrambles the bits, spreading any burst errors that occur during

transmission.

FIG. NO. 6.6: ENCODING AND INTERLEAVING

(IV) CHANNELIZING

The encoded voice data is further encoded to separate it from other encoded

voice data. The encoded symbols are then spread over the entire bandwidth

of the CDMA channel. This process is called channelization.

The receiver knows the code and uses it to recover the voice data.

KINDS OF CODES: CDMA uses two important types of codes to

channelize users.

(a) Walsh codes channelize users on the forward link (BTS to mobile).

Walsh codes provide a means to uniquely identify each user on the

forward link. Walsh codes have a unique mathematical property,

that is, they are "orthogonal." In other words, Walsh codes are

unique enough that a receiver applying the same Walsh code can only

recover the voice data. All other signals are discarded as

background noise.

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(a)Pseudorandom Noise (PN) codes channelize users on the reverse link

(mobile to BTS). Pseudorandom Noise (PN) codes uniquely identify

users on the reverse link. A PN code is one that appears to be random,

but isn't. The PN codes used in CDMA yield about 4.4 trillion

combinations of code. This is a key reasonwhy CDMA is so secure.

(IV) CONVERSION OF DIGITAL TO RADIO FREQUENCY (RF) SIGNAL

The BTS combines channelized data from all calls into one signal. It then

converts the digital signal to a Radio Frequency (RF) signal for

transmission.

6.5: CODE CHANNELS USED IN CDMA

A code channel is a stream of data designated for a specific use or person. This

channel may be voice data or overhead control data. Channels are separated by codes. The

forward and reverse links use different types of channels.

(I) FORWARD LINK CHANNELS: uses four types ofchannels to transmit voice

and control data to the mobile. The types of forward link channels are:

i. Pilot

ii. Sync

iii. Paging

iv. Traffic

FIG. NO. 6.7: FORWARD LINK CHANNELS

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(i) PILOT CHANNELThe BTS constantly transmits the pilot channel. The mobile uses the pilot signal

to acquire the system. It then uses the pilot signal to monitor and adjust the power

needed in order to transmit back to the BTS.

FIG. NO. 6.8: PILOT CHANNEL

(ii) SYNC CHANNEL

The BTS constantly transmits over the sync channel so the mobile can synchronize with

the BTS. It provides the mobile with the system time and the identification number of

the cell site. The mobile ignores the sync channel after it is synchronized.

FIG. NO. 6.9: SYNC CHANNEL

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(III) PAGING CHANNEL

CDMA uses up to seven paging channels. The paging channel transmits overhead

information such as commands and pages to the mobile. The paging channel also

sends commands and traffic channel assignment during call set-up. The mobile

ignores the paging channel after a traffic channel is established.

FIG. NO. 6.10: PAGING CHANNEL

(IV) FORWARD LINK TRAFFIC CHANNEL

CDMA uses between fifty-five and sixty-one forward traffic channels to send both

voice and overhead control data during a call. Once the call is completed, the

mobile tunes back in to the paging channel for commands and pages.

FIG. NO. 6.11: TRAFFIC CHANNEL

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(II) REVERSE LINK CHANNELS: uses two types ofchannels to transmit voice and

control data to BTS. The types of reverse link channels are:

i. Access

ii. Traffic

FIG. NO. 6.12: REVERSE LINK CHANNELS

(i) ACCESS CHANNEL

The mobile uses the access channel when not assigned to a traffic channel. The

mobile uses the access channel to:

Register with the network

Originate calls

Respond to pages and commands from the base station

Transmit overhead messages to the base station

FIG. NO. 6.13: ACCESS CHANNEL

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(II) REVERSE LINK TRAFFIC CHANNEL

The reverse traffic channel is only usedwhen there is a call. The reverse traffic

channel transmits voice data to the BTS. It also transmits the overhead control

information during the call.

FIG. NO. 6.14: REVERSE LINK TRAFFIC CHANNNEL

6.6: CALL PROCESSING STAGES IN CDMA

There are four stages or modes in CDMA call processing(Fig. 6.15):

Initialization mode Idle mode Access mode Traffic mode.

(I) INITIALIZATION MODE: During initialization, the mobile acquires the system

via the Pilot code channelsynchronizes with the system via the Sync code channel

(II) IDLE MODE: The mobile is not involved in a call during idle mode, but it must

stay in communication with the base station. The mobile and the base station

communicate over the access and paging code channels. The mobile obtains

overhead information via the paging code channel.

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FIG. NO. 6.15: CALL PROCESSING STAGES IN CDMA

(III) ACCESS MODE: The mobile accesses the network via the Access code

channel during call origination. The Access channel and Paging channel carry

the required call set-up communication between the mobile phone and the BTS

until a traffic channel is established.

(IV) TRAFFIC MODE: During a land to mobile (LTM) call: The mobile receives a

page on the paging channel. The mobile responds on the access channel. The

traffic channel is established and maintained throughout the call.

During a mobile to land call (MTL): The call is placed using the Access channel.

The base station responds on the paging channel. The traffic channel is

established and maintained throughout the call.

Call processing (messages): During the call overhead messaging continues on

the traffic channel in a limited fashion. This messaging uses "Dim and Burst"

or "Blank and Burst" signaling, which replaces part of the voice traffic with

system messages. The user does not detect this signaling, however, due to the

strong data recovery schemes inherent to CDMA.

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FIG. NO. 6.16: MOBILE CALL PROCESSING

6.7: FEATURES OF CDMA

CDMA has several unique features that make it a cost-effective, high quality

wireless solution. The following features are unique to CDMA technology:

(a) Universal frequency reuse

(b)Fast and accurate power control

(c)Different types of handoff(a)FREQUENCY REUSE: The frequency spectrum is a limited resource.

Therefore, wireless telephony, like radio, must reuse frequency assignments.

Each BTS in a CDMA network can use all available frequencies. Adjacent

cells can transmit at the same frequency because users are separated by code

channels, not frequency channels. This feature of CDMA, called "frequency

reuse of one," eliminates the need for frequency planning

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FIG. NO. 6.17: POWER CONTROL

(b)POWER CONTROL: Power control is a CDMA feature that enables mobiles

to adjust the power at which they transmit. This ensures that the base station

receives all signals at the appropriate power. The CDMA network

independently controls the power at which each mobile transmits. Both forward

and reverse links use power control techniques.

Reverse link power control: Reverse link power control consists of two

processes:

Open loop power control: Open loop is the mobile's estimate of the

power at which it should transmit. The open loop estimate is based

on the strength of the pilot signal the mobile receives. As the pilot

signal gets weaker or stronger, the mobile adjusts its transmission

strength upwards or downwards. Open loop is used any time the

mobile transmits.

Closed loop power control: In closed loop, the BTS sends a command

to the mobile to increase or decrease the strength at which it is

transmitting. The BTS determines this command based on the quality

of the signal it receives from the mobile. Closed loop is only used

during a call. Closed loop commands are sent on the forward traffic

channel.

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(C) HANDOFF IN CDMA: Handoffis the process of transferring a call from one

cell to another. This is necessary to continue the call as the phone travels.

CDMA is unique in how it handles handoff.

TYPES OF CDMA HANDOFF: CDMA has three primary types of

handoff:

i. SOFT

ii. HARD

iii. IDLE

(i) SOFT HANDOFF

A soft handoff establishes a connection with the new BTS prior to breaking the

connection with the old one. This is possible because CDMA cells use the same

frequency and because the mobile uses a rake receiver.

FIG. NO. 6.18: SOFT HANDOFF

Variations of the soft handoff: There are two variations of soft handoffs involving

handoffs between sectors within a BTS:

Softer

Soft-softer

The softer handoff: occurs between two sectors of the same BTS. The BTS decodes and

combines the voice signal from each sector and forwards thecombined voice frame to the

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BSC. The soft-softer handoff is combination handoff involving multiple cells and multiple

sectors within one of the cells.

FIG. NO. 6.19: SOFTER HANDOFF

(ii) HARD HANDOFF

A hard handoffrequires the mobile to break the connection with the old BTS prior

to making the connection with the new one. CDMA phones use a hard handoff

when moving from a CDMA system to an analog system because soft handoffs are

not possible in analog systems. A Pilot Beacon Unit (PBU) at the analog cell site

alerts the phone that it is reaching the edge of CDMA coverage. The phone

switches from digital to analog mode as during the hard handoff.

Hard handoffmay also be used when moving to a different:

- RF channel- MTSO- Carrier- Market

(iii) IDLE HANDOFF

An idle handoffoccurs when the phone is in idle mode. The mobile will detect a

pilot signal that is stronger than the current pilot. The mobile is always searching

for the pilots from any neighboring BTS. When it finds a stronger signal, the mobile

simply begins attending to the new pilot.

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6.8: ADVANTAGES OF CDMA

CDMA technology has numerous advantages including:

i. COVERAGE

ii. CAPACITY

iii. CLARITY

iv. COST

v. COMPATIBILITY

vi. CUSTOMER SATISFACTION

(i) COVERAGE

CDMA's features result in coverage that is between 1.7 and 3 times that ofTDMA.

Power control helps the network dynamically expand the coverage area. Coding

and interleaving provide the ability to cover a larger area for the same amount of

available power used in other systems.

(II) CAPACITY

CDMA capacity is ten to twenty times that ofanalog systems, and it's up to four

times that ofTDMA.

Reasons for this include:

CDMA's universal frequency reuse

CDMA users are separated by codes, not frequencies

Power control minimizes interference, resulting in maximized capacity.

CDMA's soft handoffalso helps increase capacity. This is because a soft handoffrequires

less power.

FIG. NO. 6.20: ADVANTAGES OF CDMA

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(iii) CLARITY

Often CDMA systems can achieve "wire line" clarity because of CDMA's strong

digital processing.Specifically:

The rake receiverreduces errors

The variable rate vocoder reduces the amount of data transmitted per

person, reducing interference.

The soft handoffalso reduces power requirements and interference.

Power controlreduces errors by keeping power at an optimal level.

CDMA's wide band signal reduces fading. Encoding and interleaving reduce

errors that result from fading.

(iv) COSTCDMA's better coverage and capacity result in cost benefits:

Increased coverage per BTS means fewer are needed to cover a given area.

This reduces infrastructure costs for the providers.

Increased capacity increases the service provider's revenue potential.

A CDMA cost per subscriber has steadily declined since 1995 for both

cellular and PCS applications.

FIG. NO. 6.21: COST OF CDMA

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(v) COMPATIBILITY

CDMA phones are usually dual mode. This means they can work in both CDMAs

systems and analog cellular systems. Some CDMA phones are dual band as well

as dual mode. They can work in CDMA mode in the PCS band, CDMA mode in

the cellular band, or analog mode in an analog cellular network.

(vi) CUSTOMER SATISFACTION

CDMA results in greater customer satisfaction because CDMA provides better:

Voice quality

Longer battery life due to reduced power requirements

No cross-talk because of CDMA's unique coding

Privacy--again, because of coding

FIG. NO. 6.22 CDMA CUSTOMER SATISFACTION6.8: ARCHITECTURE OF THE CDMA NETWORK

A CDMA network is composed ofseveral functional entities, whose functions and

interfaces are specified. The CDMA network can be divided into three broad parts. The

Mobile Station is carried by the subscriber. The Base Station Subsystem controls the radio

link with the Mobile Station. The Network Subsystem, the main part of which is the

Mobile services Switching Center (MSC), performs the switching of calls between the

mobile users, and between mobile and fixed network users. The MSC also handles the

mobility management operations. Not shown is the Operations and Maintenance Center,

which oversees the proper operation and setup of the network. The Mobile Station and the

Base Station Subsystem communicate across the Um interface, also known as the air interface

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or radio link. The Base Station Subsystem communicates with the Mobile services Switching

Center across the A interface.

FIG. NO. 6.23 GENERAL ARCHITECTURE OF A CDMA NETWORK

(I) MOBILE STATION

The mobile station (MS) consists of the mobile equipment. The mobile equipment

is uniquely identified by the International Mobile Equipment Identity (IMEI).

FIG. NO. 6.24: MOBILE EQUIPMENTS

(II) BASE STATION SUBSYSTEM

The Base Station Subsystem is composed of two parts:

(a) The Base Transceiver Station (BTS)

(b) The Base Station Controller (BSC).

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These communicate across the standardized Abis interface, allowing operation between

components made by different suppliers.

FIG. NO. 6.25: BASE STATION SUBSYSTEM

(a) The Base Transceiver Station (BTS)houses the radio transceivers that define a

cell and handles the radio-link protocols with the Mobile Station. In a large urban area,

there will potentially be a large number of BTSs deployed, thus the requirements for a BTS

are ruggedness, reliability, portability, and minimum cost.

The base station is under direction of a base station controller so traffic gets sent

there first. The base station controller gathers the calls from many base stations and passes

them on to a mobile telephone switch. From that switch come and go the calls from the

regular telephone network.

(b) The Base Station Controller (BSC) manages the radio resources for one or

more BTSs. It handles radio-channel setup, frequency hopping, and handovers, as

described below. The BSC is the connection between the mobile station and the Mobile

service Switching Center (MSC). Another difference between conventional cellular and

CDMA is the base station controller. It's an intermediate step between the base station

transceiver and the mobile switch. This a better approach for high-density cellular

networks. As If every base station talked directly to the MSC, traffic would become too

congested. To ensure quality communications via traffic management, the wireless

infrastructure network uses Base Station Controllers as a way to segment the network

and control congestion. The result is that MSCs route their circuits to BSCs which in turn

are responsible for connectivity and routing of calls for 50 to 100 wireless base stations."

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FIG. NO. 6.26: BASE STATION CONTROLLER

BSC functions includes:

Performs vocoding of the voice signal

Routes calls to the MTSO

Handles call control processes

Maintains a database of subscribers

Maintains records of calls for billingThe voice coders or vocoders are built into the handsets a cellular carrier

distributes. They're the circuitry that turns speech into digital. The carrier specifies which

rate they want traffic compressed, either a great deal or just a little. The cellular system is

designed this way, with handset vocoders working in league with the equipment of the base

station subsystem.

(III) THE MOBILE SWITCHING CENTER

The central component of the Network Subsystem is the Mobile services

Switching Center (MSC).

FIG. NO. 6.27: THE MOBILE SWITCHING CENTER

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It acts like a normal switching node of the PSTN or ISDN, and additionally

provides all the functionality needed to handle a mobile subscriber, such as registration,

authentication, location updating, handovers, and call routing to a roaming subscriber .

These services are provided in conjunction with several functional entities, which together

form the Network Subsystem. The MSC provides the connection to the fixed networks

(such as the PSTN or ISDN). Signaling between functional entities in the Network

Subsystem uses Signaling System Number 7 (SS7), used for trunk signaling in ISDN and

widely used in current public networks.

(IV) HOME LOCATION REGISTER (HLR) & VISITED LOCATION REGISTER (VLR)

The Home Location Register (HLR) and Visitor Location Register (VLR), together

with the MSC, provide the call routing and roaming capabilities. The HLR contains all the

administrative information of each subscriber registered in the network, along with the

current location of the mobile. The location of the mobile is typically in the form of the

signaling address of the VLR associated with the mobile station. The Visitor Location

Register (VLR) contains selected administrative information from the HLR, necessary for

call control and provision of the subscribed services, for each mobile currently located in

the geographical area controlled by the VLR. Most often these two directories are located

in the same place. The HLR and VLR are big databases maintained on computers called

servers, often UNIX workstations. To operate its nationwide cellular system, iDEN,

Motorola uses over 60 HLRs nationwide.

(V) EQUIPMENT IDENTITY REGISTER (EIR)

The other two registers are used for authentication and security purposes. The

Equipment Identity Register (EIR) is a database that contains a list of all valid mobile

equipment on the network, where each mobile station is identified by its International

Mobile Equipment Identity (IMEI). An IMEI is marked as invalid if it has been reported

stolen or is not type approved.

(Vi) THE INTERFACESCellular radio's most cryptic terms belong to these names: A, Um, Abis, and Ater.

A telecom interface means many things. It can be a mechanical or electrical link connecting

equipment together. Or a boundary between systems, such as between the base station

system and the network subsystem. Interfaces are standardized methods for passing

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information back and forth. The transmission media isn't important. Whether copper or

fiber optic cable or microwave radio, an interface insists that signals go back and forth in

the same way, in the same format. With this approach different equipment from any

manufacturer will work together.

A-bis " is a French term meaning 'the second A Interface. In most cases the

actual span or physical connection is made on an E1 line. But regardless of the material

used, the transmission media, it is the signaling protocol that is most important.

Although the interface is unlabeled, the mobile switch communicates with the

telephone network using Signaling System Seven, an internationally agreed upon

standard. More specifically, it uses ISUP over SS7. "ISUP defines the protocol and

procedures used to set-up, manage, and release trunk circuits that carry voice and data calls

over the public switched telephone network (PSTN). ISUP is used for both ISDN and

non-ISDN calls."

6.9: COMPARISON OF MULTIPLE ACCESS SYSTEMS

The table summarizes in Fig.6.28 shows some of the technical aspects of the multiple

access technologies. The technology used determines the channel's capacity. TDMAtriples

the capacity of FDMA, but CDMA capacity can be up to seven times that of TDMA.

FIG. NO. 6.28: COMPARISON OF MULTIPLE ACCESS SYSTEMS

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