1. Wireless Networks and mobile communication system NET 332D (Cellular Network and Generations)
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2. AGENDA: PART 1 Introduction Key Characteristics & Differentiation
System Architecture
Radio Access
Transmission
Transport
Core (Voice, Packet)
Cellular Generation Architectures
Basic Elements of a Cellular Network
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3. Pre-cursor of cellular networks
The objective of early mobile system was to achieve a large coverage using single high power transmitter (antenna) mounted on a very tall tower.
Good coverage but very minimal capacity
Impossible to reuse the same frequencies in that large coverage area due to interference.
For example, Bell mobile system in 1970 could support maximum of 12 simultaneous calls over a thousand square mile.
The government regulatory could not make spectrum allocation proportion to the increasing demand
Became imperative to restructure the telephone system to achieve high capacity with limited radio spectrum while at the same time covering very large areas.

4. Key characteristics & Differentiation
Cellular
Fixed Line
WiFi
Network Type
Wide Area Network (WAN)
WAN
Local Area Network (LAN)
Range
Based on Coverage
Based on Penetration
~100 m
Bandwidth / Data Rates
Medium  High
Medium  Very High
High
Terminal Battery Life
~1-3 days
Not applicable
~7 days
Cost
CAPEX = High
OPEX = High
CAPEX = Very High
OPEX = Medium
CAPEX = Medium
OPEX = Low
Licensed
Strictly
Un-licensed
User Mobility
Full
None
Nomadic

5. Network Architecture Technology Sub-Network Microwave Access Optical
Aggregation
Technology
Elements
R99
MSC, VLR, HLR R4
MSS, MGW, et al
Technology
Radio/Air Interface
GSM (2G)
Um (F/TDMA)
UTRAN (3G)
Uu (WCDMA)
Lte (4G)
Lte-Uu (OFDM)
Technology
Elements
2G, 3G
SGSN, GGSN 4G
MME, S-GW, P-GW
Technology BS
GSM
BTS
UTRAN
Node B
Lte
eNode B

6. Generational Architectures
2G (GSM)
User Plane
Control Plane
3G (UMTS) 4G
(Lte)

7. Multiple Access
Cellular systems need to cater to increasingly more & heavy users
This is done by using advanced & efficient Multiple Access techniques
Generation
System
Multiple Access
1st
AMPS
FDMA
2nd (2G)
GSM
FDMA + TDMA
3rd (3G)
UMTS
WCDMA
4th (4G)
Lte
DL: OFDMA, UL: SC-FDMA
DL = Downlink = from BS  UE
UL = Uplink = from UE  BS

8. How a mobile call is made?
Communication between mobile and base station is defined by a standard common air interface (CAI) that specifies four different channels.
Two types of channels are available between the mobile unit and the base station (BS): control channels and traffic channels.
Control channels are used to exchange information having to do with setting up and maintaining calls and with establishing a relationship between a mobile unit and the nearest BS.
The two channels (FCC and RCC) responsible for initiating the mobile calls are called the control channels or the setup channels.
They are involved in call setup and moving it to an unused voice channel.
Traffic channels carry a voice or data connection between users.
Forward Voice channels (FVC)-The channels used for voice transmission from BS to mobile.
Reverse Voice Channels (RVC)-Channels used for voice transmission from the mobile to the base station.
Behrouz A. Forouzan” Data communications and Networking

9. Call initiated by a mobile is established
To place a call from a mobile station, the caller enters a code of 7 or 10 digits (a phone number) and presses the send button.
The mobile station then scans the band, seeking a setup channel with a strong signal, and sends the data (phone number) to the closest base station using that channel.
The base station relays the data to the MSC.
The MSC sends the data on to the telephone central office.
If the called party is available, a connection is made and the result is relayed back to the MSC.
At this point, the MSC assigns an unused voice channel to the call, and a connection is established. The mobile station automatically adjusts its tuning to the new channel, and communication can begin.
Behrouz A. Forouzan” Data communications and Networking

10. Timing diagram illustrating how a call initiated by a mobile is established
Fig. 1.7
Figure 1.7 Timing diagram illustrating how a call initiated by a mobile is established.

11. Behrouz A. Forouzan” Data communications and Networking
Call to the Mobile
When a mobile phone is called, the telephone central office sends the number to the MSC.
The MSC searches for the location of the mobile station by sending query signals to each cell in a process called paging.
Once the mobile station is found, the MSC transmits a ringing signal and, when the mobile station answers, assigns a voice channel to the call, allowing voice communication to begin.
Behrouz A. Forouzan” Data communications and Networking

12. Timing diagram how a call to a mobile user initiated by a landline subscriber is established.
Fig. 1.6
Figure 1.6 Timing diagram illustrating how a call to a mobile user initiated by a landline subscriber is established.

13. AGENDA: PART 2 System design fundamentals
Introduction
Cellular Concept
Cells
Frequency Reuse
Handoff Strategies
Trunking and Grade of service
Interference and system capacity
Improving system capacity

14. Introduction The design objective of early mobile radio systems:
Achieve a large coverage area by using a single, high powered transmitter with an antenna mounted on a tall tower.
Good coverage but impossible to reuse those same frequencies throughout the system, since any attempts to achieve frequency reuse would result in interference.
Example:
Bell mobile system in New York City in the 1970s could only support a maximum of twelve simultaneous calls over a thousand square miles.
Problem
Faced with the fact that government regulatory agencies could not make spectrum allocations in proportion to the increasing demand for mobile services,
Requirement:
To restructure the radio telephone system to achieve high capacity with limited radio spectrum, while at the same time covering very large areas.

15. Cellular Concept
The cellular concept -----breakthrough in solving the problem of spectral congestion and user capacity.
It offered very high capacity in a limited spectrum allocation without any major technological changes.
Cellular Concept Fundamentals
Replace a single, high power transmitter (large cell) with many low power transmitters (small cells), each providing coverage to only a small portion of the service area (cell).
The essence of a cellular network is the use of multiple low-power transmitters, of the order of 100W or less.
Because the range of such a transmitter is small, an area can be divided into cells, each one served by its own antenna.
Each base station
Allocated a portion of the total number of channels available to the entire system be used in a small geographic area/Cell.
The base station antennas are designed to achieve the desired coverage within the particular cell.
Nearby base stations are assigned different groups of channels and limiting the coverage area
Such that the interference between base stations (and the mobile users under their control) is minimized.
The available channels are distributed throughout the geographic region and may be reused as many times as necessary, so long as the interference between co-channel stations is kept below acceptable levels.
The design process of selecting and allocating channel groups for all of the cellular base stations within a system is called frequency reuse or frequency planning

16. Cellular Concept
Demand for service increases (i.e., as more channels are needed within a particular market),
The number of base stations may be increased
With a corresponding decrease in transmitter power to avoid added interference
Thereby providing additional radio capacity with no additional increase in radio spectrum.

17. Behrouz A. Forouzan” Data communications and Networking
Cells
Shape of cells to cover an area.
A matrix of square cells is the simplest layout .
If the width of a square cell is d, then a cell has four neighbors at a distance d and four neighbors at a distance V2d.
As a mobile user within a cell moves toward the cell's boundaries, it is best if all of the adjacent antennas are equidistant.
A hexagonal pattern provides for equidistant antennas.
The radius of a hexagon is defined to be the radius of the circle that circumscribes it (equivalently, the distance from the center to each vertex; also equal to the length of a side of a hexagon).
For a cell radius R, the distance between the cell center and each adjacent cell center is d = V3R.
This simplifies the task of determining when to switch the user to an adjacent antenna and which antenna to choose.
Behrouz A. Forouzan” Data communications and Networking
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18. Behrouz A. Forouzan” Data communications and Networking
TYPEs of Cells
Coverage is the key criterion for this classification
Characteristic
Macrocell
Microcell
Small cell
Coverage Distance
250m  20Km
(Urban  Remote Rural)
100m  500m
(Urban)
~100m
(Dense Urban)
Antenna Heights
10m  100m
~10m
Roof Height
Power
30W  120W
20W  40W
~10W
Weight / Volume
Full Cabinet
Compact Cabinets
Close to WiFi AP
Capacity Tier
High
Medium
Hotspot
Behrouz A. Forouzan” Data communications and Networking

19. Frequency reuse
The essence of a cellular network is the use of multiple low-power transmitters, of the order of 100W or less.
Because the range of such a transmitter is small, an area can be divided into cells, each one served by its own antenna.
Each cell is allocated a band of frequencies and is served by a base station, consisting of transmitter, receiver, and control unit.
Adjacent cells are assigned different frequencies to avoid interference
Cells sufficiently distant from each other can use the same frequency band. This is termed as “Frequency Re-use”.

20. Behrouz A. Forouzan” Data communications and Networking
Frequency Reuse
The set of frequencies available is limited, and frequencies need to be reused.
In general, neighboring cells cannot use the same set of frequencies for communication because of interference
The objective of frequency reuse is to use the same frequency band in multiple cells at some distance from one another.
This allows the same frequency band to be used for multiple simultaneous conversations in different cells.
Within a given cell, multiple frequency bands are assigned, the number of bands depending on the traffic expected.
A frequency reuse pattern is a configuration of N cells, N being the reuse factor, in which each cell uses a unique set of frequencies. When the pattern is repeated, the frequencies can be reused. There are several different patterns.
Behrouz A. Forouzan” Data communications and Networking

21. 𝐷 𝑅 = 3𝑁 or alternatively 𝐷 𝑑 = 𝑁
Frequency Reuse
A key design issue is to determine the minimum separation between two cells using the same frequency band, so that the two cells do not interfere with each other.
𝐷 𝑅 = 3𝑁 or alternatively 𝐷 𝑑 = 𝑁
D = minimum distance between centers of cells that use the same frequency band (called co-channels)
R = radius of a cell
d = distance between centers of adjacent cells (d = √3R)
N = termed as reuse factor = no. of cells in a repetitious pattern = unique available frequencies
Behrouz A. Forouzan” Data communications and Networking

22. Behrouz A. Forouzan” Data communications and Networking
Frequency Reuse
The numbers in the cells define the pattern.
The cells with the same number in a pattern can use the same set of frequencies. We call these cells the reusing cells.
In a pattern with reuse factor 4, only one cell separates the cells using the same set of frequencies
In a pattern with reuse factor 7, two cells separate the reusing cells
D = R 3 𝑁 = R = 4.5 R (where Diameter = 2R)
Reuse Factor = 4
Reuse Factor = 7
Behrouz A. Forouzan” Data communications and Networking

23. Frequency REuse example
To understand the frequency reuse concept, consider a cellular system
Total available duplex channels for use in cellular system=S
Number of channels allocated per cell= k
The cells which collectively use the complete set of available frequencies is called a cluster=cluster size=N
𝑆=𝐾𝑥𝑁
If a cluster is replicated M times within the system, the total number of duplex channels, C, can be used as a measure of capacity and is given by:
𝐶=𝑀𝑥𝐾𝑥𝑁=𝑀𝑥𝑆
The capacity of a cellular system is directly proportional to the number of times a cluster is replicated in a fixed service area.

24. Frequency reuse example
The capacity of a cellular system is directly proportional to the number of times a cluster is replicated in a fixed service area (M).
If the cluster size N is reduced while the cell size is kept constant, more clusters (M) are required to cover a given area and hence more capacity (a larger value of C) is achieved.
Conversely, a small cluster size indicates that co-channel cells are located much closer together.
The value for N is a function of how much interference a mobile or base station can tolerate while maintaining a sufficient quality of communications.
From a design viewpoint, the smallest possible value of N is desirable in order to maximize capacity over a given coverage area (i.e.. to maximize C)
The frequency reuse factor of a cellular system is given by 1/N, since each cell within a cluster is only assigned 1/N of the total available channels in the system.

25. Frequency Reuse: AMPS FDMA
System has a total of K frequencies available (e.g. in AMPS, K = 395)
If the pattern consists of N cells and each cell is assigned the same number of frequencies, each cell can have K / N frequencies
Example
For AMPS, K = 395
Consider N = 7 as the smallest pattern that can provide sufficient isolation between two cells of the same frequency.
This implies that there can be at most 57 frequencies per cell on average (i.e. K / N)
i.e. we will have 7 unique frequency groups now which will be re-used
If we want to increase reuse factor (e.g. from 7  14) we will have to reduce capacity / cell (i.e. from 57  lesser)
Behrouz A. Forouzan” Data communications and Networking

26. Channel assignment strategies
For efficient utilization of the radio spectrum, a frequency reuse scheme that is consistent with the objectives of increasing capacity and minimizing interference is required.
A variety of channel assignment strategies have been developed to achieve these objectives.
Fixed Channel Assignment
Dynamic Channel assignment
In a fixed channel assignment strategy; each cell is allocated a predetermined set of voice channels.
Any call attempt within the cell can only be served by the unused channels in that particular cell.
If all the channels in that cell are occupied, the call is blocked and the subscriber does not receive service.
Several variations of the fixed assignment strategy exist. In one approach, called the borrowing strategy, a cell is allowed to borrow channels from a neighboring cell if all of its own channels are already occupied. The mobile switching center (MSC) supervises such borrowing procedures and ensures that the borrowing of a channel does not disrupt or interfere with any of the calls in progress in the donor cell.
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27. Channel assignment strategies
Dynamic Channel Assignment
In a dynamic channel assignment strategy, voice channels are not allocated to different cells permanently.
Each time a call request is made, the serving base station requests a channel from the MSC.
The switch then allocates a channel to the requested cell following an algorithm that takes into account the likelihood of fixture blocking within the cell, the frequency of use of the candidate channel, the reuse distance of the channel, and other cost functions.

28. Handoff
Handoff is the procedure for changing the assignment of a mobile unit from one BS to another as the mobile unit moves from one cell to another.
The principal parameter used to make the handoff decision is measured signal strength from the mobile unit at the BS.
Relative signal strength: The. mobile unit is handed off from BS A to BS B. When the signal strength at B first exceeds that at A. If the signal strength at B subsequently falls below that of A, the mobile unit is handed back to A. L1
Relative signal strength with threshold:
Handoff only occurs if (1) the signal at the current BS is sufficiently weak (less than a predefined threshold) and (2) the other signal is the stronger of the two. The intention is that so long as the signal at the current BS is adequate, handoff is unnecessary.

29. Handoff strategies
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. This is called a Handoff.
The handoff operation involves a new base station
Requires that the voice and control signals be allocated to channels associated with the new base station.
Processing handoffs is an important task in any cellular radio system.
Many handoff strategies prioritize handoff requests over call initiation requests when allocating unused channels in a cell site.
Handoffs must be performed successfully and as infrequently as possible, and be imperceptible to the users.
In order to meet these requirements, system designers must specify an optimum signal level at which to initiate a handoff.

30. Handoff strategies
Once a particular signal level is specified as the minimum usable signal for acceptable voice quality at the base station receiver (normally taken as between —90 dBm and —100 dBm), a slightly stronger signal level is used as a threshold at which a handoff is made.
This margin, given by ∆= 𝑃 𝑟,ℎ𝑎𝑛𝑑𝑜𝑓 − 𝑃 𝑟,𝑚𝑖𝑛𝑖𝑚𝑢𝑚𝑢𝑠𝑎𝑏𝑙𝑒
∆ cannot be too large or too small.
If ∆ is too large, unnecessary handoffs which burden the MSC may occur.
If ∆ is too small, there may be insufficient time to complete a handoff before a call is lost due to weak signal conditions.
Therefore, A is chosen carefully to meet these conflicting requirements.

31. Handoff strategies
Figure demonstrates the case where a handoff is not made and the signal drops below the minimum acceptable level to keep the channel active.
This dropped call event can happen when there is an excessive delay by the MSC in assigning a handoff, or when the threshold ∆ is set too small for the handoff time in the system.
In deciding when to handoff, it is important to ensure that the drop in the measured signal level is not due to momentary fading and that the mobile is actually moving away from the serving base station
Excessive delays may occur during high traffic conditions due to computational
loading at the MSC or due to the fact that no channels are available on
any of the nearby base stations (thus forcing the MSC to wait until a channel in
a nearby cell becomes free).
In order to ensure this, the base station monitors the signal level for a certain period of time before a handoff
is initiated. This running average measurement of signal strength should be
optimized so that unnecessary handoffs are avoided, while ensuring'that necessary
handoffs are completed before a call is terminated due to poor signal level.
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32. Practical handoff considerations
In practical cellular systems, several problems arise when attempting to design for a wide range of mobile velocities.
High speed vehicles pass through the coverage region of a cell within a matter of seconds
Pedestrian users may never need a handoff during a call.
With the addition of microcells to provide capacity, the MSC can quickly become burdened if high speed users are constantly being passed between very small cells.
Umbrella cell approach
By using different antenna heights (often on the same building or tower) and different power levels, it is possible to provide "large" and "small" cells which are co-located at a single
location.
This technique is called the umbrella cell approach and is used to provide large area coverage to high speed users while providing small area coverage to users traveling at low speeds.

33. PRACTICAL HANDOFF CONSIDERATIONS
Figure illustrates an umbrella cell which is co-located with some smaller microcells.
The umbrella cell approach ensures
Minimum number of handoffs is minimized for high speed users and provides additional microcell channels for pedestrian users.
The speed of each user may be estimated by the base station or MSC by evaluating how rapidly the short term average signal strength on the the RVC changes over time
If a high speed user in the large umbrella cell is approaching the base station, and its velocity is rapidly decreasing, the base station may decide to hand the user into the co-located microcell, without MSC intervention.

34. Umbrella cell approach

35. TrunkinG and Gos Channel Capacity – Voice/Speech, GSM
Max Capacity
We have 4 Transceivers (TRXs)
Each on a different frequency (FDMA) of 200KHz
Each TRX has 8 timeslots (TSLs) each of which can take 1 call/user (TDMA)
1 TSL is reserved for signaling & control (leaves 31 user timeslots)
Maximum Speech Users = 31, 32nd call will be rejected
Realistic Channel Capacity
Calls have different Holding / Conversation time + different start times!!!
Erlang Distributions help calculate ‘realistic voice channel capacity”
Erlang = Simultaneous Voice Minutes, defines relationship b/w channels, call holding time & a specific Grade or Quality of Service (GoS, QoS)
The grade of service (GOS) is a measure of the ability of a user to access a trunked system during the busiest hour.
Grade of Service for GSM (2G) was typically ~2% 1 2 3 4 5 6 7
TRX 1 8 9 10 11 12 13 14 15
TRX 2 23
TRX 3 31
TRX 4
Erlang (Calling Minutes, Represented in Hours)
1 user x 1hr = 1 Erl = 60mins
2 users x 30mins = 1 Erl = 60mins
3 users x 20mins = 1 Erl = 60mins
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36. Behrouz A. Forouzan” Data communications and Networking
Erlang Explained
Erlang B  used in GSM  probability of channel allocation
Channels
Erlang B GoS)
Erlang B GoS) 7 ~3
3.7 15 9
10.6 23
~16 18 31
~23
~26
So if there are C channels allocated to a specific area/cell. The maximum channel capacity can be C Earlangs. That means if all channels are occupied all the time. But actually calls are random and they have different holding times and start and end times. So the actual capacity of the systeem will be less than C Earlangs.
So using these relationships we can design and dimension a cellular system. How many channels to allocate to a particular area.
So depending upon the population and the channel holding times we allocate the channels to s particular cell/area. or in other cases Based on the Earlang Capacity we can allocate the Number of channels.
Later if we observe that we are getting more blockings more than that dictated by the GOS we will allocate more channels.
Erlang B Calculator
Behrouz A. Forouzan” Data communications and Networking
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37. INTERFERENCE and SYSTEM CAPACITY
Interference is the major limiting factor in the performance of cellular radio
systems.
Sources of interference include
Another mobile in the same cell
A call in progress in a neighboring cell
Other base stations operating in the same frequency band
Any non-cellular system which inadvertently leaks energy into the cellular frequency band.
Interference on voice channels causes cross talk, where the subscriber hears interference in the background due to an undesired transmission.
On control channels, interference leads to missed and blocked calls
due to errors in the digital signaling.
Interference is more severe in urban areas
Due to the greater HF noise floor
The large number of base stations and mobiles.

38. Interference and system capacity
There are two major types of system generated cellular interference
Co-channel interference
Adjacent channel interference

39. COCHANNEL INTERFENCE Co-channel Cells and Co-channel interference
Frequency reuse implies that in a given coverage area there are several cells that use the same set of frequencies. These cells are called co-channel cells, and the interference between signals from these cells is called co-channel interference.
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.
To reduce co-channel interference, co-channel cells must be physically separated by a minimum distance to provide sufficient isolation due to propagation.
When size of each cell is approximately the same, and the base stations transmit the same power, the co-channel interference ratio is independent of the transmitted power and becomes a function of the radius of the cell (R) and the
distance between centers of the nearest co-channel cells (D).
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40. COCHANNEL INTERFENCE
The co-channel interference ratio is a function of the radius of the cell (R) and the distance between centers of the nearest co-channel cells (D).
By increasing the ratio of D/R, the spatial separation between co-channel cells relative to the coverage distance of a cell is increased. Thus interference is reduced from improved isolation of HF energy from the co-channel cell.
The parameter Q, called the co-channel reuse ratio, is related to the cluster size given by the following expression.
𝑄= 𝐷 𝑅 = 3𝑁
There is a tradeoff between the two objectives: Improved transmission quality and the system capacity.
A small value of Q provides larger capacity since the cluster size N is small. A large value of Q improves the transmission quality, due to a smaller level of co-channel interference.
A trade-off must be made between these two objectives in actual cellular design.
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41. COCHANNEL INTERFENCE
The 𝑺 𝑰 worst case (signal to interference ratio) is related to the co channel interference ratio given by the following expression (approximation).

42. Adjacent channel interference
Interference resulting from signals which are adjacent in frequency to the desired signal is called adjacent channel interference.
Adjacent channel interference results from imperfect receiver filters which allow nearby frequencies to leak into the pass band.
The problem of adjacent channel interference can be solved using the following strategies:
Careful filtering and channel assignments.
Since each cell is given only a fraction of the available channels, a cell need not be assigned channels which are all adjacent in frequency.
By keeping the frequency separation between each channel in a given cell as large as possible, the adjacent channel interference may be reduced considerably.
Assigning channels which form a contiguous band of frequencies within a particular cell, channels are allocated such that the frequency separation between channels in a given cell is maximized.
Sequentially assigning successive channels in the frequency band to different cells,
Many channel allocation schemes are able to separate adjacent channels in a cell by as many as N channel bandwidths, where N is the cluster size. Some channel allocation schemes also prevent a secondary source of adjacent channel interference by avoiding the use of adjacent channels in neighboring cell sites.
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43. Power control for reducing interference
In practical cellular radio and personal communication systems the power levels transmitted by every subscriber unit are under constant control by the serving base stations.
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 dramatically reduces the reverse channel S/I in the system.
The received power must be sufficiently above the background noise for effective communication, which dictates the required transmitted power.
As the mobile unit moves away from the transmitter, the received power declines due to normal attenuation. In addition, the effects of reflection, diffraction, and scattering can cause rapid changes in received power levels over small distances.

44. Power Control Cellular systems use the two kinds of power control.
Open-loop power control depends solely on the mobile unit, with no feedback from the BS.
Closed-loop power control adjusts signal strength in the reverse (mobile to BS) channel based on some metric of performance in that reverse channel, such as received signal power level, received signal-to-noise ratio, or received bit error rate.
Behrouz A. Forouzan” Data communications and Networking

45. Increasing Capacity of a cellular system
As more customers use the system, traffic may' build up so that there are not enough frequency bands assigned to a cell to handle its calls. A number of approaches have been used to cope with this situation, including the following:
Adding new channels: Typically, when a system is set up in a region, not all of the channels are used, and growth and expansion can be managed in an orderly fashion by adding new channels.
Frequency borrowing: In the simplest case, frequencies are taken from adjacent cells by congested cells. The frequencies can also be assigned to cells dynamically.
Behrouz A. Forouzan” Data communications and Networking

46. Increasing Capacity Cell splitting
Cell splitting is the process of subdividing a congested cell into smaller cells, each with its own base station and a corresponding reduction in antenna height and transmitter power.
Cells in areas of high usage can be split into smaller cells. Generally, the original cells are about 6.5 to 13 km in size.
The smaller cells can themselves be split
To use a smaller cell, the power level used must be reduced to keep the signal within the cell.
Cell splitting increases the capacity of a cellular system since it increases the number of times that channels are reused.
By defining new cells which have a smaller radius than the original cells and by installing these smaller cells (called microcells) between the existing cells, capacity increases due to the additional number of channels per unit area.
Behrouz A. Forouzan” Data communications and Networking

47. Cells are split to add channels with no new spectrum usage
Fig. 2.10

48. Increasing Capacity Cell sectoring:
The technique for decreasing co-channel interference and thus increasing system capacity by using directional antennas is called sectoring.
A way to increase capacity is to keep the cell radius unchanged (unlike cell splitting) and seek methods to decrease the D/R ratio (Interference). In order to do this, it is necessary to reduce the relative interference without decreasing the transmit power.
The co-channel interference in a cellular system may be decreased by replacing a single omni-directional antenna at the base station by several directional antennas, each radiating within a specified sector.
By using directional antennas, a given cell will receive interference and transmit with only a fraction of the available co-channel cells.
The factor by which the co-channel interference is reduced depends on the amount of sectoring used.
A cell is normally partitioned into three 1200 sectors or six 60° sectors as shown in Figure 2.10(a) and (b).
Behrouz A. Forouzan” Data communications and Networking

49. Sectoring improves S/I
Fig. 2.12

50. Power Control
A number of design issues make it desirable to include a dynamic power control capability in a cellular system:
The received power must be sufficiently above the background noise for effective communication, which dictates the required transmitted power.
As the mobile unit moves away from the transmitter, the received power declines due to normal attenuation. In addition, the effects of reflection, diffraction, and scattering can cause rapid changes in received power levels over small distances.
It is desirable to minimize the power in the transmitted signal from the mobile unit, to reduce co-channel interference (interference with channels on the same frequency in remote cells), alleviate health concerns, and save battery power.
Behrouz A. Forouzan” Data communications and Networking

51. Power Control Cellular systems use the two kinds of power control.
Open-loop power control depends solely on the mobile unit, with no feedback from the BS.
Closed-loop power control adjusts signal strength in the reverse (mobile to BS) channel based on some metric of performance in that reverse channel, such as received signal power level, received signal-to-noise ratio, or received bit error rate.
Behrouz A. Forouzan” Data communications and Networking

52. References Forouzan Data and Computer Communications 5th edition
William Stallings Wireless Communications 2nd Wdition
Wireless Communications by Theodore S Rappaport 2nd Edition
Behrouz A. Forouzan” Data communications and Networking