frequency re use nb

3.2 FREQUENCY RE USE

AJAL.A.J Assistant Professor –Dept of ECE,

Federal Institute of Science And Technology (FISAT) TM  MAIL: ec2reach@gmail.com

The key characteristic of a cellular network is the ability to re-use frequencies to increase both coverage and capacity.

Cellular ConceptCellular Concept

The limited capacity of the first mobile radio-telephone services was related to the spectrum used…not much sharing and a lot of bandwidth dedicated to a single call.– good coverage

– interference: impossible to reuse the same frequency

The cellular concept addressed many of the shortcomings of the first mobile telephones– Frequency reuse

– Wasted spectrum allocated to a single user

In 1968, Bell Labs proposed the cellular telephony concept to the FCC

It was approved and then the work began!– FCC allocated spectrum (took away TV UHF channels 70-83) in the

825-845 MHz and 870-890 MHz bands

Cellular ConceptCellular Concept developed by Bell Labs 1960’s-70’s

areas divided into cells

a system approach, no major technological changes

a few hundred meters in some cities, 10s km at country side

each served by base station with lower power transmitter

each gets portion of total number of channels

neighboring cells assigned different groups of channels, interference minimized

hexagon geometry cell shape

What is a Cell?• Cell is the Basic Union in The System

– defined as the area where radio coverage is given by one base station.

• A cell has one or several frequencies, depending on traffic load. – Fundamental idea: Frequencies are reused, but not in

neighboring cells due to interference.

Cellular Concept

Limited number of frequencies => limited channels Single high power antenna => limited number of users Smaller cells => frequency reuse possible => more number of users

Base stations (BS): implement space division multiplex– Each BS covers a certain transmission area (cell)

– Each BS is allocated a portion of the total number of channels available

– Cluster: group of nearby BSs that together use all available channels

Mobile stations communicate only via the base station– FDMA, TDMA, CDMA may be used within a cell

As demand increases (more channels are needed)– Number of base stations is increased

– Transmitter power is decreased correspondingly to avoid interference

Cellular Concept

Cell size:– 100 m in cities to 35 km on the country side (GSM) – even less for higher frequencies– Umbrella cell: large cell that includes several smaller cells

• Avoid frequent handoffs for fast moving traffic

Cell shape:– Hexagonal is useful for theoretical analysis– Practical footprint (radio coverage area) is amorphous

BS placement:– Center-excited cell: BS near center of cell

• omni-directional antenna– Edge-excited cell: BSs on three of the six cell vertices

• sectored directional antennas

Cellular Concept

Advantages:– higher capacity, higher number of users– less transmission power needed– more robust, decentralized– base station deals with interference, transmission area etc. locally

Problems:– fixed network needed for the base stations– handover (changing from one cell to another) necessary– interference with other cells: co-channel, adjacent-channel

Important Issues:– Cell sizing– Frequency reuse planning– Channel allocation strategies

Bottom line: Attempt to maximize availability of channels in an area

• Cells labeled with the same letter use the same group of channels.

• Cell Cluster: group of N cells using complete set of available channels

• Many base stations, lower power, and shorter towers• Small coverage areas called “cells”• Each cell allocated a % of the total number of

available channels• Nearby (adjacent) cells assigned different channel

groups– to prevent interference between neighboring base

stations and mobile users

Cell characteristics• Implements space division multiplex: base station

covers a certain transmission area (cell)• Mobile stations communicate only via the base

station• Advantages of cell structures:

– higher capacity, higher number of users– less transmission power needed– more robust, decentralized– base station deals with interference, transmission area etc. locally

• Problems:– fixed network needed for the base stations– handover (changing from one cell to another) necessary– interference with other cells

• Cell sizes from some 100 m in cities to, e.g., 35 km on the country side (GSM) - even less for higher frequencies

Shape of Cells Square

Width d cell has four neighbors at distance d and four at distance d

Better if all adjacent antennas equidistant Simplifies choosing and switching to new antenna

Hexagon Provides equidistant antennas Radius defined as radius of circum-circle

Distance from center to vertex equals length of side Distance between centers of cells radius R is R Not always precise hexagons

Topographical limitations Local signal propagation conditions Location of antennas

2

3

Cellular Geometries

Cell Footprint

Cellular Network ArchitectureCellular Network Architecture

MobileSwitching

Center

PublicTelephonenetwork

and Internet

MobileSwitching

Center

Wired network

Frequency ReuseFrequency Reuse

Adjacent cells assigned different frequencies to avoid interference or crosstalk

Objective is to reuse frequency in nearby cells– 10 to 50 frequencies assigned to each cell

– transmission power controlled to limit power at that frequency escaping to adjacent cells

– the issue is to determine how many cells must intervene between two cells using the same frequency

Frequency ReuseFrequency Reuse

each cell allocated a group k channels– a cluster has N cells with unique and disjoint channel

groups, N typically 4, 7, 12

total number of duplex channels S = kN

Cluster repeated M times in a system

Total number of channels that can be used (capacity)– C = MkN = MS

Smaller cells higher M higher C

+ Channel reuse higher capacity

+ Lower power requirements for mobiles

– Additional base stations required

– More frequent handoffs

– Greater chance of ‘hot spots’

Frequency planning

f1

f2

f3

f2

f1

f1

f2

f3

f2

f3

f1

f2

f1

f3f3

f3f3

f3

f4

f5

f1

f3

f2

f6

f7

f3

f2

f4

f5

f1

f3

f5f6

f7f2

f2

f1f1 f1

f2

f3

f2

f3

f2

f3h1

h2

h3g1

g2

g3

h1

h2

h3g1

g2

g3g1

g2

g3

3 cell cluster

7 cell cluster

3 cell clusterwith 3 sector antennas

Figure Frequency reuse patterns

Frequency planning• Frequency reuse only with a certain

distance between the base stations• Standard model using 7 frequencies:

f4

f5

f1

f3

f2

f6

f7

f3

f2

f4

f5

f1

FREQUENCY REUSE

• The allotted frequency spectrum for mobile communication

• during the 1 G is in the range of (800- 900 )Mhz

• but ,Using this small bandwidth, thousands of subscribers need to be served over a large area.

• To manage this situation, a technique called ‘’frequency reuse ‘’ is adopted.

FREQUENCY REUSE

Cellular Networks

• Propagation models represent cell as a circular area• Approximate cell coverage with a hexagon - allows easier• analysis• Frequency assignment of F MHz for the system• The multiple access techniques translates F to T traffic channels• Cluster of cells K = group of adjacent cells which use all of the systems

frequency assignment

Frequency reuse conceptFrequency reuse concept

ALPHABETICAL REPRESENTATION

Wrong implementation

END Result of Wrong implementation

Correct implementation

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Freq reuse Advantage

Freq reuse: Several cells in coverage area that use same set of frequencies

Cochannel cells: Those cells using same freqsCochannel interference: The mobile in cell A also gets signals from other Co channel cells

Cluster1

Cluster2

Cluster3

Cellular Concepts

In this case N=19 (i=3, j=2)

Frequency Reuse

Power of base transceiver controlled Allow communications within cell on given frequency Limit escaping power to adjacent cells Allow re-use of frequencies in nearby cells Use same frequency for multiple conversations 10 – 50 frequencies per cell

E.g. The pattern consists of N cells K total number of frequencies used in systems Each cell has K/N frequencies Advanced Mobile Phone Service (AMPS) K=395, N=7

giving 57 frequencies per cell on average

Characterizing Frequency Reuse D = minimum distance between centers of cells that use

the same band of frequencies (called cochannels) R = radius of a cell d = distance between centers of adjacent cells (d = R) N = number of cells in repetitious pattern

Reuse factor Each cell in pattern uses unique band of frequencies

Hexagonal cell pattern, following values of N possible  N = I2 + J2 + (I x J), I, J = 0, 1, 2, 3, …

 Possible values of N are 1, 3, 4, 7, 9, 12, 13, 16, 19, 21, … D/R= D/d =

N3N

35

Distance

DR

R

36

4

1

3

6

5

27

4

1

3

6

5

27

4

1

3

6

5

27

4

1

3

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27

4

1

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5

27

D

R

Example of frequency reuse factor or pattern 1/4

The frequency reuse factor is the rate at which the same frequency can be used in the network. It is 1/K (or K according to some books) where K is the number of cells which cannot use the same frequencies for transmission. Common values for the frequency reuse factor are 1/3, 1/4, 1/7, 1/9 and 1/12 (or 3, 4, 7, 9 and 12 depending on notation).

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Reuse Ratio : q

NqR

D3

where:D: Distance between the centres of cellsR: Radius of the cellq: Reuse ratioN: Cluster size

Assuming hexagonal shape cells of equal size

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Example

RND 3

For N = 7 and R 5 km

573 D

The minimum distance at which the same frequency can be reused is approximately 4.6 times R, which is in this case 22.91 km

91.225583.4 D

FrequencyReusePatterns

N=7, 32 cells, R=1.6km, in total 336 channels

So what is FREQUENCY REUSE ?

• After allotting the available total bandwidth among a set of cells , the same frequency band will be used in another set of cells .

• This kind of reuse can be adopted until the entire area to be covered is exhausted .

• Note• Seven cells in a set is the most frequently

used configuration.this configuration usually operates with a cell diameter of 1-3 km range

Cellular architecture

One low power transmitter per cell

Frequency reuse–limited spectrum

Cell splitting to increase capacityA

B

Reuse distance: minimum distance between two cells using same channel for satisfactory signal to noise ratio

Measured in # of cells in between

Reuse distance 2 – reuse pattern

One frequency can be (re)used in all cells of the same color

Reuse distance 3 – reuse pattern

Signal-to-interference ratio S/I or SIR

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Capacity calculation—FDMA

n: capacity (number of total users)m: number of cells to cover the areaN: frequency reuse factor (# cells/cluster)B: bandwidth per userW: total available bandwidth (spectrum)

B

W

N

mn

Problem In an FDMA system calculate

frequency re use factor ?

• m= 70

• W= 100

• n=10

• B=100

• N = ? cells/cluster

52

Capacity calculation—FDMA

In the previous example, • m=20, • W=25 MHz, • N=4, and • B=30 KHz.

166,430

25000

4

20

B

W

N

mn

53

Capacity calculation—TDMA

• n: capacity (number of total users)• m: number of cells to cover the area• N: frequency reuse factor (# cells/cluster)• B: bandwidth per user• W: total available bandwidth (spectrum)

• Nu: number of time slots per carrier

uNB

W

N

mn

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Capacity calculation—TDMA (contd.)

Assuming again, • m=20, • W=25 MHz, • N=4, • B=200 KHz,• Nu=4.

500,24200

25000

4

20 uN

B

W

N

mn

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Capacity of CDMA

n: number of users

W: total bandwidth

R: data rate

Sr: signal to noise ratio

rSR

Wn

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Capacity per cell (CDMA)

Assume:

W=1.25MHz=1,250,000 Hz

R=9600 bps

Sr should be larger than 3dB => 2 times

usersSR

Wn

r

6529600

1250000

System architecture

• A set of seven cells will be controlled by a BSC base station controller

• The terminal station located in every cell will have access to the BSC.

• 7 base terminal stations will have one BSC

• For every frequency reuse , 1 BSC is required.

The elements that determine frequency reuse are the reuse distance and the reuse factor

Scenario

• For 100 BTS we require more than 14 BSC’s

• All BSC are connected to a Mobile Switching centre.

• Here mobile stations are connected to BTS by wireless means

• All Base stations are connected to their respective BSC’sby cables.

• In modern communication , fibre optic cables are used to connect BTS

Fig: Advanced cellular mobile communication system Architecture

@ 3G

Cell Planning (1/3)• The K factor and Frequency Re-Use Distance

K = i2 + ij + j2

K = 22 + 2*1 + 12

K = 4 + 2 + 1

K = 7i

j

1

2

34

5

6

7

Frequency re-use distance is based on the cluster size K

The cluster size is specified in terms of the offset of the center of a cluster from the center of the adjacent cluster

D = 3K * R

D = 4.58R

1

2

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6

7

D

R

Cell Planning (2/3)

A3A1

A2G3

G1

G2C3

C2

B3B1

B2

F3F1

F2

D3D1

D2E3

E1

E2

G3G1

G2

F3F1

F2

C3C1

C2

A3A1

A2B3

B1

B2

E3E1

E2

D3D1

D2

7-cell reusepattern

Frequencyreuse

C1

Cell Planning (3/3)• Cell sectoring

– Directional antennas subdivide cell into 3 or 6 sectors

– Might also increase cell capacity by factor of 3 or 6

• Cell splitting– Decrease transmission

power in base and mobile

– Results in more and smaller cells

– Reuse frequencies in non-contiguous cell groups

– Example: ½ cell radius leads 4 fold capacity increase

BTS• BTS acts as an interface between the Mobile unit & BSC

• BTS connects mobile units by wireless means to the BSC

BTS Antenna• BTS has got an antenna usually at an elevation location.

• Invariantly , Roof tops,

• Small steel towerare used for erecting the BTS antenna.

Omni directional coverage= coverage in all directions

• Compact power supply systems (some even chargeable batteries) are used at the base terminal stations.

• BTS is usually located at the centre of the cell area for omni directional coverage.

INDIAN ANALOGY

Bandwidth vs mobility

• The wireless interface at BTS and wired topologytopology between BTS- BSC & BSC – MSC necessitates certain translation in protocols.

• Upto the stage of BTS , air interface protocols are used. After BTS , the transmission media happen to be wired one , mostly fibre optic communication.

• Hence at the BTS or BSC stage , there is a need for the translation of these protocols

Illustration – of translation requirement

• In mobile communication at the mobile user’s unit the speech signal is connected into 13 kbps digitized voice. This conversion is is required to have an air interface with bandwidth efficiency.

• But the backbone network through which the voice has to travel in certain applications can provide 64 kbps.

Contd…

Contd…

• PCM digitization is adopted in fixed telephone network which make use of these backbone network.

• When mobile unit converts the analog information into 13kbps digital information , the BSC converts the same into 64 kbps information.

[[6868]]

Frequency reuse revisited: cluster size and reuse distanceFrequency reuse revisited: cluster size and reuse distance

DD

frequency group A

frequency group B

Cluster with cluster size N

Co-channel cells

[[6969]]

The geometry of a hexagonal cellThe geometry of a hexagonal cell

Unit scale is distance between neighboring cell centers.

For cell radius

To find the distance from the origin, , of point , convertconvert axis:

[[7070]]

The geometry of a hexagonal cell The geometry of a hexagonal cell [continue] [continue]

– So,

– Using this equation to locate co-channel cells, we start from a reference cell and move i hexagons along the u-axis and then j hexagons along the v-axis.

– The distance between co-channel cells in adjacent clusters is

– The number of cells in a cluster, N, is hence since i and j can only take integer values.

– The frequency reuse factorfrequency reuse factor, Q, is defined by

Frequency Reuse Factor

Effective reuse of resources can highly enhance the system capacity Frequency reuse factor (FRF) K defines frequency

reuse pattern

With a smaller frequency reuse factor (FRF), more available bandwidth can be obtained by each cell

Previous Frequency Reuse Schemes

With the usage of FRF-1, the most user terminals (UTs) are afflicted with heavy Inter-cell interference (ICI) Especially near the cell edge

The conventional method to figure out this problem is by increasing the FRF mitigate the ICI efficiently but decrease on available bandwidth

The most representative approaches improving cell-edge performance while retaining spectrum efficiency Soft Frequency Reuse (SFR) scheme Incremental Frequency Reuse (IFR) scheme

Soft Frequency Reuse (SFR) Scheme

Incremental Frequency Reuse (IFR) Scheme

Enhanced Fractional Frequency Reuse (EFFR)

FREQUENCY REUSE SCHEME

Soft frequency Reuse

CCU: cell-centre usersCEU: cell-edge users

Soft Frequency Reuse (SFR) Scheme CCU: cell-centre users

CEU: cell-edge users

Limitations of SFR

How to define the borderline to divide cell area for CCUs and CEUs is a key issue Generally, there are more CEUs than CCUs in a cell

since the outer surface area is much larger than the inner part CEUs have maximum one third of the entire bandwidth to utilize,

which results in lower spectrum efficiency

More ICI could happen even in a low traffic-load situation, while there are still subchannels in idle and underutilized in the system The resource allocation via the SFR scheme starts always from

the first subchannel up

Incremental Frequency Reuse (IFR) Scheme (1)

The only difference between the IFR design and the classical reuse-1 Classical reuse-1: allocate resources always from

the first subchannel IFR: start dispensing resources from different points

Incremental Frequency Reuse (IFR) Scheme (2)

IFR scheme can overcome the low spectrum reuse efficiency problem and the more ICI at low loading traffic problem

IFR scheme only performs better when just fewer traffic exists in a system When the loading factor is greater than 0.3, it is

inferior to the SFR scheme

Enhanced Fractional Frequency Reuse (EFFR) (1)

Enhanced Fractional Frequency Reuse (EFFR) scheme intends to retain the advantages of the both approaches

Concept Define 3 cell types for directly contiguous cells in a cellular system Reserves for each cell-type a part of the whole frequency band named

Primary Segment The Primary Segments among different type cells should be

orthogonal The Primary Segment of each cell will be further divided into

reuse-3 part: cannot be reused by directly neighboring cells reuse-1 part: is at the same time a part of the Secondary Segments

belonging to the other two cell-types

HYBRIDS

Enhanced Fractional Frequency Reuse (EFFR) (2)

Power Allocation and SINR Estimation Transmission Power Allocation

Any cell-type is not allowed to use the reuse-3 subchannels dedicated to the other two cell types The power allotted to the reuse-3 subchannels can be tripled

Signal-to-Interference-Ratio (SINR) Estimation A cell acts on the Secondary Segment as a guest, and occupying

secondary subchannels is actually reuse the primary subchannels belonging to the directly adjacent cells

Reuse on the Secondary Segment should conform to two rules: monitor before use resource reuse based on SINR estimation

Each cell listens on every secondary subchannel all the time Before occupation, a cell makes SINR evaluation and chooses resources

with best estimation values for reuse If all available secondary resources are either occupied or not good

enough to a link, this cell will give up scheduling resources

Worst Case InterferenceWorst Case Interference

S/I ~ R-4 /[2(D-R)-4 + 2(D+R)-4 + 2D-4]

In CDMA reuse patterns are not required.

Subscriber in every cell can use the same frequency at the same time. Subscriber is discriminated from another by the assignment of a unique code to every conversation.

In GSM freq. Reuse pattern of 7 is used.

Frequency Reuse @ CDMA

Problems– Propagation path loss for signal power: quadratic or higher in distance – fixed network needed for the base stations– handover (changing from one cell to another) necessary– interference with other cells:

• Co-channel interference: Transmission on same frequency

• Adjacent channel interference:Transmission on close frequencies

Solution: Topology of Different Areas

100

100

100

20

60 100

100

60 60

20

20

20

20

20

20

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40 20

20

Town

Rural

Suburb

Highway

Q Q UERRIES ??