cellular ppt

CELLULAR CONCEPT

Divya BansalECE 6TH Sem110326105786

CELLULAR CONCEPT• The cellular concept was a major breakthrough in solving

the problem of spectral congestion and user capacity.• It offered very high capacity in a limited spectrum.• Each cellular base station is allotted a group of radio

channels to be used within a small geographic area called cells.

Contd…• Use multiple low-power transmitters.• Areas divided into cells• Each served by its own antenna• Served by base station consisting of transmitter, receiver, and control unit• Band of frequencies allocated• Cells set up such that antennas of all neighbors are equidistant (hexagonal pattern)

CELLULAR NETWORK ARCHITECTURE

CELLS STRUCTURE• Determined by the desired received signal level by

the mobile subscriber from its base station transmitter in its operating area ideal, actual and fictitious cell models.

Contd…

A CELL WITH A CS AND MOBILE

HEXAGONAL CELLULAR GEOMETRY

• Offers best possible non-overlapped cell radio coverage.

• Multiple hexagons can be arranged next to each other.• The hexagons covers the large area.• Simplifies the planning and design of the cellular system.

HEXAGONAL CELLULAR GEOMETRY

CELLULAR CLUSTER• A group of cells that use a different set of frequencies

in each cell.• Only selected number of cells can form a cluster.• Can be repeated any number of times in a systematic

manner.• The cluster size is the number of cells with in it and designated by K.

HEXAGONALS CLUSTER PATTERNS

CONVENTIONAL MOBILE COMMUNICATION

• One very powerful transmitter located at the highest spot in an area would broadcast in a radius of upto 50 kilometers.

LIMITATIONS:• High power consumption.• Low capacity.• Large size of the mobile.

SYSTEM DESIGN PROBLEMMain limitations of a conventional mobile wireless communication system is:• Minimum availability of FREQUENCY SPECTRUM!!!So the big challenge is… to serve large no. of mobile users…• within limited allocated frequency spectrum.• with a specified system quality.

SYSTEM CAPACITY AND & SPECTRUM UTILIZATION

How to increase the capacity and Spectrum utilization

?

The Need:• optimum spectrum usage• More capacity• High quality of service• Low cost

POSSIBLE SOLUTION-FREQUENCY REUSE

• Reuse allocated RF spectrum or a given set of frequencies in a given large geographical service area without increasing the interference.

• Divide the service area into a number of small areas called cells.

• Allocate a subset of frequencies to each cell.• Use low-power transmitters with lower height antennas at the base stations

FREQUENCY REUSE CONCEPT• Large coverage area, efficient spectrum utilization and

enhanced system capacity are the major attributes of cellular communications.

• Frequency reuse is the core concept of cellular communications.

• The design process of selecting and allocating channel groups for all the cellular base stations within a system is called frequency reuse.

IILUSTRATION OF FREQUENCY REUSE

CO-CHANNEL & ADJACENT CHANNEL CELLS

• Cells, which use the same set of frequencies are referred to as co-channel cells.

• Co-channel cells are located sufficiently physically apart so as not to cause co-channel interference.

• The space between adjacent co-channel cells filled with other cells that use different frequencies to provide frequency isolation.

TECHNICAL ISSUESTechnical issues for proper design & planning of a cellular network:• Selection of a suitable frequency reuse pattern.• Analysis of the relationship between the capacity, cell

size & the cost of the infra structure.

CLUSTER SIZE AND CELL CAPACITY

• In a cellular system, the whole geographical service area is divided into a number of clusters having finite number of cells.

• The K number of cells in a cluster use the complete set of available frequency channels, N.

• Each cell in the cluster contain J = (N/K) number of channels only.

Therefore, N = J * K ; where J ≤ N

CLUSTER SIZE & SYSTEM CAPACITY

• The cluster can be replicated many times to cover the desired geographical area by a cellular communication system.

• Let M be a number of clusters in the system, then overall system capacity, C is given as:

C = M * N C = M * J * K (N = J * K) • When K is reduced, J is proportionally increased since

N = J * K is constant.• To increase co-channel interference!

CO-CHANNEL CELLS• Cells which use the same set of frequencies are referred to as co-channel cells.• The interference between co-channel cells is referred to as co-channel interference.• The space between adjacent co-channel cells are filled with cells using different frequencies.

Contd…

Shift Parameters I and j in a Hexagonal Geometry

• The Shift parameters i and j are separated by 60 degrees in a hexagonal geometry.• It can have any integer value 0,1,2,…..• These can be used to determine the location of co-channel cells.

Contd…

METHOD TO LOCATE THE CO-CHANNEL CELLS

Rules for determining the nearest co-channel cell using “Shift parameters” (i , j) to lay out a cellular system is:• Step 1: Move I cells along any side of a hexagon.• Step 2: Turn 60 degrees anticlockwise.• Step 3: Move j cells. Where I and j are shift parameters and can have integer value 0,1,2,3 & so on ….

Co-Channel cells for i=3, j=2

FREQUENCY REUSE DISTANCE, D

• Reusing an identical frequency channel in different cells is limited by co-channel interference between cells.•The co-channel interference can become a major problem in cellular communication.•It is desirable to find the minimum frequency reuse distance D in order to reduce this co-channel interference.

Factors Which Influence ‘D’• The number of co-channels in the vicinity of the center

cell.• The antenna height• The transmitted power at each cell site

NOTE: As long as the cell size is fixed, co-channel interference is independent of transmitter power of each cell.

Frequency Reuse Ratio, q

q = D/RThe frequency reuse ratio, q is also referred to as:• The co-channel reuse ratio.• The co-channel reuse factor.• Co-channel interference reduction factor.

q = D/R RatioThe real power of the cellular concept is that interference is not related to the absolute distance between cells but related to ratio of the distance between co-channel (same frequency) cells to the cell radius.

FREQUENCY REUSEADVANTAGES DISADVANTAGES

The frequency reuse system can be increase the spectrum efficiency, thereby increasing the system capacity.

If the system is not properly designed , co-channel interference may occur due to the simultaneous use of the same channel.

CO-CHANNEL INTERFERENCE

The interference between signals from co-channel cells channel cells.• Unlike thermal noise which can be overcome by increasing the signal-to- noise ration (SNR), co-channel interference cannot be combated by simply increasing the carrier power of a transmitter. • This is because an increase in carrier transmit power increases the interference to neighboring co-channel cells.

How it can be reduced??• Increasing the separation between two co-channel cells.• Using directional antennas at the cell site.• Lowering the antenna heights at the cell site.• Use of diversity scheme at receiver.

ADJACENT CHANNEL INTERFERENCE

1. What is adjacent channel interference? Interference resulting from signals which are adjacent in frequency to desired signal.

2. Why does it occur?This results from imperfect receiver filters which allow nearby frequencies to leak into the pass band.

How it can be reduced?? Careful filtering and channel assignment By keeping the frequency separation between each

channel in a given cell as large as possible By sequentially assigning successive channels in the

frequency band to different cells

Co-channel cells

Adjacent-channel cells

Co-channel interference

Adjacent-channel interference

INTERFERENCE

HANDOFF• When a mobile user travels from one cell to another cell

within a call’s duration the call should be transferred to the new cell’s base station.

• Otherwise, the call will be dropped because the link with the current base station becomes too weak as the mobile recedes.

• This ability for transference is a design matter in mobile cellular system design and is called handoff .

Contd…

HANDOFF STRATIGIES• When a mobile moves into a different cell while a

conversation is in progress, the MSC 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.

Contd…• Handoff Threshold Minimum usable signal for acceptable voice quality (-

90dBm to -100dBm) Handoff margin ( = Pr Handoff – Pr minimum useable)

cannot be too large or too small. If is too large, unnecessary handoffs burden the MSC If is too small, there may be insufficient time to

complete handoff before a call is lost.

Contd…

Contd…• Handoff must ensure that the drop in the measured signal

is not due to momentary fading and that the mobile is actually moving away from the serving base station.

• Running average measurement of signal strength should be optimized so that unnecessary 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

Contd…• Dwell timeThe time over which a call may be maintained within a cell without handoff. • Dwell time depends on propagation interference distance speed

PRACTICAL HANDOFF CONSIDERATIONS

• Different type of users High speed users need frequent handoff during a call. Low speed users may never need a handoff during a call. • The MSC becomes burdened if high speed users are

constantly being passed between very small cells. • To Minimize handoff intervention handle the simultaneous traffic of high speed and low

speed users.

Contd…• Large and small cells can be located at a single location

(Umbrella cell approach) different antenna height different power level• Cell dragging problem: pedestrian users provide a very

strong signal to the base station The user may travel deep within a neighboring cell

UMBRELLA CELLS• Use different antenna heights and Tx power levels to

provide large and small cell coverage • Multiple antennas & Tx can be co-located at single

location if necessary (saves on obtaining new tower licenses)

• large cell → high speed traffic → fewer handoffs • small cell → speed traffic • Example areas: interstate highway passing through urban

center office park, or nearby shopping mall center.

Contd…

Why cell splitting and cell sectoring?

• As users increases channel capacity decreases.

• Techniques are needed to provide extra channels.

• Cell Splitting and cell Sectoring increases the capacity.

CELL SPLITTING• The process of sub dividing a

congested cell into smaller cell.• Each with its own base station

and a corresponding reduction in antenna height.

• Leads to increase in capacity.

LIMITATIONS• Handoffs are more frequent.• Channel assignment becomes difficult.• All Cells are split simultaneously so special care have to

be taken for proper allocation of problem.

CELL SECTORING• The Co- Channel interference in a cellular system may

be reduced by replacing a single Omni-directional antenna at the base station by several directional antennas radiating with in specified sectors.

• A cell is normally partitioned in three 120 degree Sectors or six 60 degree sectors.

• A given cell will receive interference and transmit with only a fraction of the available co-channel cells .

Contd…• In the sectoring scheme, the co-channel interference is

reduced and thus system capacity is improved. • Co-channel interference is reduced because the

number of interferer gets reduced.

Fig(a) 120 degree and fig(b) 60 degree

ADVANTAGES & LIMITATIONS ADVANTAGES• It improves S/I ratio.• It reduces interference which increases system capacity.• It enables to reduce the cluster size and provides

additional freedom in assigning channels.LIMITATIONS• Increased no. of antennas at each base stations• Sectoring reduces the coverage area of a particular group

of channels, the number of handoffs increases as well.

CELL REPEATERS• A cellular repeater, in the cell phone industry, is a device used

for boosting the cell phone reception to the local area by the usage of a reception antenna, a signal amplifier, and an internal rebroadcast antenna.

• They are much smaller, usually intended for use in one building. • Modern cellular repeater amplifiers can rebroadcast cellular

signals inside a building. • The systems usually use an external, directional antenna to collect

the best cellular signal, which is then transmitted to an amplifier unit which amplifies the signal, and retransmits it locally, providing significantly improved signal strength.

Power control for reducing interference

In practical cellular radio and personal communication systems the power levels transmitted by every subscriber unit are controlled by the serving base stationsNeed for Power Control:• Received power must be sufficiently above the background noise

for effective communication• Desirable to minimize power in transmitted signal from the mobile.

Reduce co-channel interference, save battery power• In Spread Spectrum systems using CDMA, it’s desirable to equalize

the received power level from all mobile units at the Base station.