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Equalization, Diversity, and Channel Coding

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Title: PowerPoint Author: Nathan Mou Last modified by: SuperXP Created Date: 3/10/2001 9:48:16 AM Document presentation format: – PowerPoint PPT presentation

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Title: Equalization, Diversity, and Channel Coding


1
Chapter 7
  • Equalization, Diversity, and Channel Coding

2
  • 7.1 Introduction
  • Mobile radio channel (in Ch 45) is particularly
    dynamic due to
  • Multipath fading
  • Doppler spread
  •  
  • As a result, they have a strong negative impact
    on BER of any modulation technique (in Ch 6)
  •  
  • To improve received signal quality in hostile
    mobile radio environment, Equalization, Diversity
    Channel Coding can be used independently or in
    tandem.

3
  • Equalization
  • Compensates for intersymbol interference (ISI)
    created by multipath within time depressive
    channels.
  • Equalizers must be adaptive since the channel is
    generally unknown and time varying.

4
  • Diversity
  • Usually implemented by using two or more
    receiving antennas.
  • Is employed to reduce the depth and duration of
    the fades experienced by a receiver.
  • Spatial diversity
  • Time diversity (RAKE receiver)

5
  • Channel coding
  • Improve link performance by adding redundant data
    bits in the transmitted message
  •  
  •  
  • Used by the receiver to detect or correct some
    (or all) of errors introduced by the channel in a
    particular sequence of message bits
  • Block codes, convolutional codes.

Baseband Signal
Channel coding
Modulation
Carrier
6
  • 7.2 fundamentals of equalization
  • since the mobile fading channel is random and
    time varying, equalizers must take the time
    varying characteristics of the mobile channel,
    and thus are called adaptive equalizers.
  •  
  • General operating modes of an adaptive equalizer
  • Training
  • Tracking

7
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8
  • (7.2)
  • (7.3)
  • (7.4)
  • (7.5)
  • Eq 7.5 an equalizer is actually an inverse
    filter of the channel.

9
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10
  • 7.3 A Generic Adaptive Equalizer
  • Figure 7.2 (P. 359)
  • A time-varying filter which must be constantly be
    returned.
  • Uses ek to minize a cost function and updates the
    equalizer weights in a manner that iteratively
    reduces the cost function.

11
  •  Based on classical equalization theory, the most
    common cost function is the mean square error
    (MSE) between the desired signal and the output
    of the equalizer
  •  
  • (7.14)
  • (7.15)
  • (7.16)
  • (7.17)

12
  • 7.4 Equalizers in a communications Receiver
  • 7.5 Survey of Equalization Techniques
  • Classification of equalizers
  • See Fig 7.3 (P 365)

13
  • 7.6 Linear Equalization
  • 7.7 Nonlinear Equalization
  • 7.8 Algorithms for Adaptive Equalization
  • various factors on the performance of an
    algorithm (P 372)
  •  
  • Algorithms
  • ZeroForcing (ZF)
  • Least Mean Squares (LMS)
  • Recursive least square (RLS)
  •  
  • Comparison (P. 379)

14
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15
  • 7.10 Diversity Techniques
  •  
  • Diversity exploits the random nature of radio
    propagation by finding independent (or at least
    highly uncorrelated) signal paths for
    communication.
  • By having more than one path to select from, both
    the instantaneous and average SNRs at the
    receiver may be improved by as much as 20-30 dB.

16
  • For examples
  • Microscopic diversity can be used to mitigate
    small-scale fading effects. (deep fading)
  • Macroscopic diversity for reducing the
    large-scale fading (selecting different base
    stations), can also be used for uplink.

17
  • Selection Diversity Improvement
  • (7.57)
  • (7.58)
  • (7.59)

18
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19
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20
  • To implement selection diversity
  • Antenna switch
  • Maximal ratio combining
  •  
  • Maximal ratio combining improvement
  • (7.63)
  • (7.64)
  • (7.65)

21
  • (7.66)
  • (7.67)
  • (7.68)
  • (7.69)
  • (7.70)

22
  • The control algorithms for setting the gains and
    phases for maximal ratio combining are similar to
    those required in equalizer and RAKE receiver.
    (Fig. 7.14 P. 387)

23
  • Practical Considerations for space diversity
  • For mobile units
  • For base station
  • to assure the decorrelation (narrow angle of
    incident fields)
  •  
  • Reception Methods of Space Diversity
  • Selection diversity
  • Feedback diversity (or scanning diversity)
  • Maximal Ratio Combining
  • Equal Gain Diversity

24
  • Polarization Diversity

25
  • Frequency Diversity
  • Signal xmitted on more than one fc gt coherence
    bandwidth (wont experience the same fade)
  •  
  • Time Diversity
  • Xmit signal repeatedly gt coherence time
  • RAKE Receiver for CDMA (multipath channel)(P.
    391)

26
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27
  • Interleaving also used
  • for time diversity (P. 394 Fig 7-17)
  • Block interleaver (Fig 7.17)
  • Convolutional interleaver

28
  • Channel Coding
  • Mainly for error control
  • Block Codes
  • Forward error correction (FEC) codes
  • Hamming Codes
  • Hadamard Codes
  • Golay Codes
  • Cyclic Codes
  • BCH cyclic
  • Reed-Solomon Codes
  • Convolutional code (Fig 7-19 P. 408)

29
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30
  • Trellis Coded Modulation (P. 412)
  • Combines both coding and modulation
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