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InterferenceInterference in voice channels can cause
Cross talkInterference in control channels leads to
missed and blocked callsInterference is major bottleneck in increasing
capacity and is often responsible for dropped calls
Interference is of two types:Co-channel interferenceAdjacent channel interference
InterferenceSources of interference :
Another mobile in the same cellA call in progress in a neighboring cellOther base stations operating in the same
frequency bandAny non-cellular system which leaks energy
into cellular frequency band
Interference(Cont)The interference created by out of band users
is very difficult to controlThe transmitters from competing cellular
carriers are often a significant source of out-of band interference
because they often locate their base stations in close proximity to one another in order to provide comparable coverage
Co-Channel InterferenceCells which use the same set of frequencies
are called as co-channel cellsThe interference between signals from these
cells is called as co-channel interferenceThe co-channel interference cannot be
combated by increasing the carrier power of transmitter (as we do in case of thermal noise)
To reduce this, co-channel cells must be physically separated by minimum distance to provide isolation
Co-channel Reuse RatioThe parameter Q, called as co-channel re-use
ratio is defined as :Q=D/R
where D=distance between centers of the nearest co-channel cells
R=radius of the cell
By increasing the D/R, the spatial separation between co-channel cells relative to the coverage distance of a cell is increased
Co-channel Reuse Ratio (Q)A small value of Q ---- larger capacity Large value of Q----Improvement in
transmission quality due to small co-channel interference
Adjacent Channel InterferenceInterference resulting from signals which are
adjacent in frequency is called as adjacent channel interference.
It results from imperfect receiver filters which allow nearby frequencies to leak into the pass band.
This issue is very serious if an adjacent channel user is transmitting in very close range to a subscriber’s receiver while the receiver attempts to receive a base station on the desired channel
This is referred to as near-far effect.
ContNear-far effect also occurs in a case when a mobile
close to a base station transmits on a channel close to one used by a weak mobile.
The base station may have difficulty in discriminating the desired mobile user from the “bleedover” caused by the close adjacent channel mobile.
This can be minimized through careful filtering and channel assignments.
By keeping the frequency separation between each channel in a given cell as large as possible, this interference can be reduced considerably.
Cont..By sequentially assigning successive
channels in the frequency band to different cells , many channel allocation schemes also prevent a secondary source of adjacent channel interference by avoiding the use of adjacent channels in neighboring cell sites
Power Control for reducing InterferenceIn practical cellular radio systems, the power
level transmitted by every subscriber unit are under constant control by the serving base station.
This is done to ensure that each mobile transmits the smallest power necessary to maintain a good quality link on the reverse channel.
Power control helps prolong battery life for the subscriber unit.
It also reduces the reverse channel S/I in the system.
TrunkingCellular radio systems rely on trunking to
accommodate a large number of users in a limited radio spectrum
Trunking allows a large number of users to share the relatively small number of channels in a cell by providing access to each user , on demand from a pool of available channels.
A channel is allocated to user on per call basis and upon termination , the channel is returned to a pool of available channels.
ContFor designing trunked radio system that can
handle a specific capacity and at specific GOS ,it is essential to understand trunking theory and queuing theory.
Erlang(A Danish mathematician) developed the fundamentals of trunking theory
One Erlang represents the amount of traffic intensity carried by the channel that is completely occupied
A radio channel that is occupied for 30 min during an hour carries 0.5 erlangs of traffic
GOSGOS is the measure of the ability of user to
access a trunked system during the busiest hour.
The GOS is the benchmark used to define the desired performance of a particular trunked system by specifying a desired likelihood of a user obtaining channel access given a specific number of channels available in the system
GOS is typically given as the likelihood of a call experiencing a delay greater than a certain queuing time
The traffic intensity offered by each user is equal to the call request rate multiplied by the holding time. i.e. each user generates a traffic intensity of Au Earlangs given by :
Au=lamdaH Where H is the average duration of call and lamda is the average number of call requests per unit time for
each user.For a system containing U users and an unspecified number of
channels , the total offered traffic intensity A , is given asA=UAu
In a C channel trunked system ,if the traffic is equally distributed among the channels ,then the traffic intensity per channel Ac is given by
Ac=UAu/C
The offered traffic is not necessarily the traffic which is carried by the trunked system only that which is offered to the trunked system
When the total traffic exceeds the maximum capacity of the system , the carried traffic becomes limited due to limited capacity.
The maximum possible carried traffic is the total number of channels C, in erlangs
The AMPS cellular system is designed for GOS of 2% blocking.
Probability of BlockageLet C be the total number of
trunks(channels),and A be the offered traffic in erlangs, then the probability of all the C trunked channels are busy or “Probability of blocking” is given by eq 3.16 (Please refer to text book)
Example 1Consider a small system of 4 channels.There
are altogether 20 subscribers and each subscriber is expected to generate a traffic of 0.1 erlang. Determine the probability of blockage that at any time all four channels get busy
Example2GOS required is 0.02 and it is expected that
1000 calls are generated per hour with average call duration of 2 minutes. Calculate the total number of channels required by the system per cell.
System Capacity Improvement TechniquesAs the demand of wireless service increases , the
number of channels assigned to a cell eventually becomes insufficient to support the required number of users. At this point , cellular design techniques are needed to provide more channels per unit area.
System Capacity:C=MKNIn terms of traffic intensity , the total traffic handled
by the system is given by:A=UAu
Where U=number of users in system Au=traffic generated by typical user
Cont..Maximum value of A can assume C.Given an allocated spectrum S=KN which is
fixed ,we have to use some cellular design techniques to improve system capacity C, or A is a function of C
Following techniques are used in practice to expand the capacity of cellular systems:(1) Cell Splitting(2) Sectoring(3)Micro-cell zone Approach