distributed wireless communication system - copy
TRANSCRIPT
Distributed Wireless Communication System
PRESENTED BY –
ABHA SINGH
(EC FINAL YEAR)
Tech-N-Gen’10
Event - Vent
INSTITUTE OF TECHNOLOGY & MANAGEMENTGIDA , GORAKHPUR
Tech-N-Gen'10 ITM GIDA GKP
Contents
History Of Mobile Phone1
Problem in Wireless System
Limited resources in Telecommuniction
Distributed Wireless Communication System
2
3
4
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HISTORY OF MOBILE PHONE
Mobile Phone Generation
4G
3G
2G
1G
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SOME DEFINITIONS
FREQUENCY REUSE CELL BTS (BASE TRANSCEIVER STATION) SHADOW FADING OUTAGE PROBABILITY RNC (RADIO NETWORK CONTROLLER) HANDOFF
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Limited resources in Telecommuniction
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Problems in Wireless system
• Limited spectrum for unlimited service requirement
• Great attenuation of energy
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Clue for Solution
It seems that the only solution for the first problem is to explore the space resource. The cellular system is a successful example. With a cellular structure, the frequency can be reused as many times as needed. Also, the cellular structure reduces the maximum distance from the terminal to the nearest base station, which is also a clue to solve the second problem.
However, in a traditional cellular system, when the cell size gets smaller, capacity can be increased linearly with cell density. But this is based on the assumption of a large path loss exponent. Path loss is the amount of loss introduced by the propagation environment between transmitter and receiver.
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4G Networks
3G networks were proposed to eliminate many problems faced by 2G and 2.5G networks, like low speeds and incompatible technologies (TDMA/CDMA) in different countries.
A 4G or 4th generation network is the name given to an IP-based mobile system that provides access through a collection of radio interfaces. A 4G network promises seamless roaming/handover and best connected service, combining multiple radio access interfaces (such as HIPERLAN, WLAN, Bluetooth, GPRS) into a single network that subscribers may use.
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Characteristics Of 4G
• High Speed
• High Network capacity
• Next-generation multimedia support • Fast/Seamless handover across multiple networks
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LOGIC STRUCTURE OF DWCSFor comparison, Fig. a shows the traditional tree structure of a cellular system, where each base transceiver station (BTS) processes the signals to and from mobile terminals within its coverage, and considers the signals of other cells as interference.
Fig. a
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Continue………The basic idea of the distributed wireless communication
system is to flatten such architecture, as indicated in Fig. b. The structure consists of three layers: distributed antennas, distributed signal processing, and distributed high-layer control.
Fig. b
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DWCS Subsystem
1
DISTRIBUTED ANTENNAS
3
DISTRIBUTED HIGH-LAYER CONTROL
2
DISTRIBUTED SIGNAL PROCESSING
Tech-N-Gen'10 ITM GIDA GKP
DISTRIBUTED ANTENNAS
The new structure has a very high density of distributed antennas which converts radio frequency (RF) to and from digital intermediate frequency (IF) signals. The received IF signal is transmitted to the processing center through optical fiber. Thus, we may have a large number of very low-cost transceivers with no information loss introduced
Tech-N-Gen'10 ITM GIDA GKP
DISTRIBUTED SIGNAL PROCESSING
All signal processing concerning wireless access is involved in this layer, including modulation/demodulation, channel coding/decoding, joint detection, channel measurements, medium access control (MAC),link layer control (LLC), radio link control (RLC), radio network control (RNC), and so on.Physically, this layer consists of two sublayers, distributed processing centers (DPCs) and the dedicated optical network.
The optical network has two main tasks: to collect and deliver digital IF signals to and from distributed antennas, and to connect the processing centers so that co-processing among different DPCs can be performed based on high-speed real-time data exchange.
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DISTRIBUTED HIGH-LAYER CONTROL
This is also a logic layer, which may be performed on the same platform as signal processing. This layer performs all high-layer protocol control, including all signaling, switching, and mobility management (gateway to core network).
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NEW CONCEPTS
DISTRIBUTED PROCESSING OF WIRELESS SIGNALS THE VIRTUAL CELL THE VIRTUAL BASE STATION
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SYSTEM CAPACITY VIEW
UPLINK CAPACITY
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UPLINK CAPACITY
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DOWNLINK CAPACITY
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ADVANTAGES
• No fast handoff problem• Large capacity • Much lower power consumption • Seamless coverage • Suitable for nonuniformly distributed traffic • Opened structure • Flexible• Extendibility• Easy to update Less harmful to human health
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CONCLUSION
DWCS, proposed here, is a new architecture for a future wireless access system. Although it has many advantages, discussed here, it is still immature at this time. In order to make it a reasonable structure for the future, some of its ideas must be applied in existing systems. As the first stage, the existing distributed repeater connected by optical fibers can be regarded as a special but simple case of DWCS.
Since beyond 3G is aimed at the system for at least 10 years from now, much larger capacity and coverage requirements are put forward. DWCS is one of the candidate architectures to fulfill these requirements.