lec 3 and 4 cellular concept 1
TRANSCRIPT
Cellular Concept - 1
By
Dr. Muhammad Moinuddin
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Outline Frequency Reuse and the Cellular Concept Cellular Architecture Co-Channel Reuse Factor Cell Types Advantages and Disadvantages of Cellular System Spectral Efficiency of a Cellular System Interference System Capacity Capacity enhancement
Cell Sectoring Micro cell deployment
Examples related to system capacity evaluation
Cellular Concept
Cellular concept is a major breakthrough in solving problems ofSpectral congestionUser Capacity
Cellular concept is a system level idea to replace a single high power transmitter with many low power transmitters.
Concept of “Frequency reuse” 3
Definitions / Terminology Frequency reuse Frequency reuse factor=1/N, N=cluster size A cell / sector is a logical network element that uses
given resources. A cell site (or site or base station) can include multiple
of cells/sectors at the same physical location. Cell coverage is defined as geographical area where
the cell is likely to serve mobiles. Network coverage refers to sum of individual cell
coverage. Actual radio coverage of a cell is called footprint and is
determined from the field measurement or propagation prediction models.
Examples of frequency reuse
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Cellular Architecture
In practice the cells are not regular hexagons, but instead are distorted and overlapping areas.
The hexagon is an ideal choice for representing macrocellular coverage areas, because it closely approximates a circle and offers a wide range of tesellating (a regular tiling of polygons) reuse cluster sizes.
A tesellating reuse cluster of size N can be constructed if,
where i and j are non-negative integers, and i ≥ j. It follows that the allowable cluster sizes are N=1,3,4,7,9,12,…..
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Commonly used cellular reuse structures Examples of 3-, 4-, and 7-cell reuse
clusters are shown The reuse clusters are tesellated to form a
frequency plan.
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Macrocellular deployment using 7-cell reuse pattern A simplified 7-cell frequency reuse plan is
shown where similarly marked cells use identical sets of carrier frequencies.
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19-cell reuse example (N=19)
Figure shows method of locating co-channel cells in a cellular system. In this example, N = 19 (i.e., i = 3, j = 2).
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Co-channel Reuse Factor
The co-channel reuse factor D / R (sometimes also referred as Q), is defined as the ratio of the co-channel reuse distance D between cells using the same set of carrier frequencies and the radius of the cells R.
For hexagonal cells, the reuse cluster size N and the co-channel reuse factor D / R are related by,
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Smaller N is greater capacity
Co-channel Reuse Ratio:
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Microcellular Deployment
For microcellular systems with lower BS antenna heights, regular hexagons are no longer appropriate for approximating the radio coverage zones.
Typical microcell BSs use an antenna height of about 15 m, well below the skyline of any buildings that might be present.
For microcells, the choice of cell shape depends greatly upon the particular deployment.
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Microcellular deployment along a highway with a 3-cell reuse pattern
The linear cells may provide a more accurate model of highway microcells that are deployed along a highway with directional antennas.
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Microcellular deployment in an urban canyon In an area with urban canyons, the buildings act as wave guides to
channel the signal energy along the street corridors. Figure shows a typical Manhattan microcell deployment that is
often used to model microcells that are deployed in city centers.
Base stations are deployed
at every intersection in a dense
urban area with a 2-cell
reuse pattern
Summary of cellular concept
Advantages Higher capacity
More frequent resource utilization increases the capacity Less transmission power
Reduced cell sizes, less power needed to cover the cell area Relaxed power amplifier specs at base stations Longer life-time for mobile station batteries
Localized interference Due to smaller service areas of cells, interference is as well localized to a
smaller area Robustness
In case that one cell is down, overlapping of cells guarantees that a mobile is able to get connected through other base stations
No technological challenges in deployment Major problems related to minimizing the implementation and operational
expenses of the system Technological challenges related to capacity improvement methods
Disadvantages Massive infrastructure
Number of base stations increases, if more capacity is required Lots of infrastructure needed also after radio air interface (location
registers, switches, management servers etc.) More complex mobility management
Seamless connections throughout the network has to be provided Handovers needed
Management of handover procedures might get complicated Resource planning and management
Tight resource planning strategy needed (time slots, frequencies) Resource management needed to support resource planning
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Spectral Efficiency of a Cellular System Main factors that determine the spectral efficiency of a cellular
system. The cell sizes, The ability of radio links to withstand interference, and The ability of the cellular system to react to variations in traffic.
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Requirement for High Spectral Efficiency High spectral efficiency require:
effective cellular architecture, fast and accurate link quality measurements, rapid control in all types of environments, installation of BSs to provide radio coverage virtually
everywhere, and power and bandwidth efficient air interface schemes that can
mitigate the harsh effects of the propagation environment and tolerate high levels of noise and interference.
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Spectrum Allocation
In cellular systems, the available spectrum is partitioned among the BSs with two types of channels Voice Channels Control Channels
A given frequency is reused at the closest possible distance that the radio link will allow.
Smaller cells have a shorter distance between reused frequencies, and this results in an increased spectral efficiency and traffic carrying capacity.
Example 3.1
Interference and system capacity
Interference limits the system capacity and the performance of a single radio link.
The higher is the interference level, the lower is the system capacity and poorer is the quality of communication links.
Interference can origin from Mobiles under the same cell Mobile under different cell Base stations operating at the same frequency (or in general
using simultaneously the same resources) From non-cellular systems
Co-channel interference is the most problematic. Also adjacent channel interference affect the system capacity.
However, adjacent channel interference is also filtering problem, which can be decreased by assigning channels intelligently.
Interference and system capacity
Hence, the target of frequency (or resource) allocation is to plan frequency usage in such a manner that system capacity is maximized (i.e., frequencies should be utilized as frequently as possible).
However, simultaneously the interference should be kept at adequate level.
For cellular planning point of view, this can be achieved by providing as much isolation as possible between co-channel cells.
SIR
Signal strength from the serving cell is denoted as S and co-channel interference as I. The resulting relation is signal-to-interference ratio (SIR) that defines the quality of the signal.
where Ij is the co-channel interference received from jth co-channel cell. For simplicity, if transmission powers (P) of all cells is assumed to be the same as well as radio signal attenuation equal from all cells, SIR can be written as
SIR
where d0 is the distance from the serving cell and dj from the jth cochannel cell.
Propagation exponent (n) varies according to environment (in free space n=2, in dense urban environment n=4)
In simple scenario, where R is the distance from the serving cell, and D is the distance from the first tier of interfering co-channel cell, SIR can be expressed
Capacity and quality enhancement methods System capacity can be improved by decreasing the
frequency reuse factor and quality by improving SIR. System capacity or SIR can be improved by
Introducing multiple antennas at the base station site sectoring
Minimization of out-of-cell interference (base station antenna characteristics)
Decreasing antenna height Microcell deployment
Sectoring
Sectoring implies to increasing the number of logical cells belonging to a single base station.
Hence, one physical location (base station) includes multiple of antennas of the cells.
Co-channel interference can be thus reduced. However, omni-directional antennas (1-sectored base station)
has to be changed into directional ones. More intra-cell handovers
Sectoring
Illustration of reduction of co-channel interference in N=4 using 3-sectored base stations.
Example 3.2
Microcell deployment A network having antennas above
roof top level is referred to as macrocellular network.
Deploying antennas below roof top level reduces the frequency reuse factor microcellular network.
Building prevent the signal propagation co-channel interference reduced significantly.
Simultaneously, cell coverage is reduced and more cells are needed to cover certain area.
Frequency reuse factor can be 5-7. Microcell deployment is expensive
solution.