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Distributed Source Coding Using Syndromes DISCUS: Design and Construction

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Title: Distributed Source Coding Using Syndromes DISCUS: Design and Construction


1
Distributed Source Coding Using Syndromes
(DISCUS) Design and Construction
  • S.Sandeep Pradhan, Kannan Ramchandran
  • IEEE Transactions on Information Theory,
  • vol. 49, no.3, pp.626-643, Mar 2003

2
Outline
  • Introduction
  • Preliminaries
  • Encoding with a Fidelity Criterion
  • Problem Formulation
  • Design Algorithm
  • Constructions based on Trellis Codes
  • Simulation Results
  • Conclusion

3
Introduction
  • Slepian-Wolf theorem
  • By knowing joint distribution of X and Y,
    without explicitly knowing Y, encoder of X can
    perform as well as encoder who knows Y.
  • Both encoder and decoder have access to side
    information Y
  • Only decoder has access to side information Y

4
Introduction
  • Wyner-Ziv Problem
  • If decoder knows Y, then the information-theoretic
    rate-distortion performance for coding X is
    identical, no matter encoder knows Y or not.(X Y
    are Gaussian.)
  • Prior work on source quantizer design.
  • Contributions
  • Construction of a framework resting on algebraic
    channel coding principles
  • Performance analysis on Gaussian signals.

Source discrete-alphabet ? continuous-valued Comp
ression lossless ? lossy
5
Outline
  • Introduction
  • Preliminaries
  • Encoding with a Fidelity Criterion
  • Problem Formulation
  • Design Algorithm
  • Constructions based on Trellis Codes
  • Simulation Results
  • Conclusion

6
Preliminaries
  • Example
  • X, Y equiprobable 3-bit binary words
  • Hamming distance is no more than 1.
  • Y is available to decoder.
  • Solution?
  • Cosets 000,111,100,011,010,101,001, 110
  • Only transmit coset index/syndrome.

7
Preliminaries
  • Quantization
  • Digitizes an analog signal.
  • Two parameters a partition and a codebook.
  • Codebook -2, 0.4, 2.3, 6

8
Preliminaries
  • Lloyd Max Quantization
  • partition ai are midpoints.
  • codebook yi are centroids.
  • Optimal scalar quantization.

9
Preliminaries
  • Trellis Coded Quantization (TCQ)24
  • Dual of TCM
  • Example
  • Uniformly distributed source in -A, A
  • Implemented by Viterbi algorithm
  • 24 M.W. Marcellin and T. R. Fischer, Trellis
    coded quantization of memoryless and Gauss-Markov
    sources, IEEE Trans. Commun., vol. 38, pp.8293,
    Jan. 1990.

10
Outline
  • Introduction
  • Preliminaries
  • Encoding with a Fidelity Criterion
  • Problem Formulation
  • Design Algorithm
  • Constructions based on Trellis Codes
  • Simulation Results
  • Conclusion

11
Encoding with a Fidelity Criterion
  • Problem Formulation
  • X, Y correlated, memoryless, i.i.d distributed
    sequences
  • Yi Xi Ni
  • Xi, Yi, Ni continuous-valued
  • Ni i.i.d distributed, independent from X
  • Xi, Ni zero-mean Gaussian random variables with
    known variance
  • Decoder alone has access to Y.
  • Goal Form best approximation to X given R bits
    per sample
  • Encoding in blocks of length L
  • Distortion measure
  • Min R, s.t. reconstruction fidelity is less than
    given value D.

12
Encoding with a Fidelity Criterion
System Model encoder and decoder. Interplay of
source coding, channel coding and estimation
13
Encoding with a Fidelity Criterion
  • Design Algorithm
  • Source Coding (M1, M2)
  • Partition source space
  • Defining source codebook (S)
  • Characterizing active codeword by W (r.v.)
  • Estimation (M3)
  • Get best estimate of X (minimizing distortion)
    conditioned on outcome of Y and the element in
    .
  • Channel Coding (M4, M5)
  • Transmit over an error-free channel with rate R
    (less than Rs)
  • Doable I(WY) gt 0, so H(WY) H(W) I(WY)
  • Build channel code with rate Rc on channel P(YW)
  • R Rs Rc.

14
Encoding with a Fidelity Criterion
  • Summary of Design Algorithm
  • M1 and M3
  • minimize Rs, s.t. reconstruction distortion
    within given criterion.
  • M2 maximize I(WY).
  • M4
  • maximize Rc, s.t. error probability meets a
    desired tolerance level.
  • M5 minimize decoding computational complexity.

15
Encoding with a Fidelity Criterion
  • Scalar Quantization and Memoryless Coset
    Construction (C1)
  • Lloyd-Max (memoryless) quantizer
  • Memoryless coset partition (M4)
  • Example
  • L1, (sample by sample)
  • Quantization codebook r0, r1, , r7, (Rs 3)
  • Channel coding codebook r0, r2, r4, r6, r1,
    r3, r5, r7. (Rc 2)
  • R Rs Rc 1 bit/sample.

16
Encoding with a Fidelity Criterion
  • Scalar Quantization and Trellis-Based Coset
    Construction (C2)
  • Scalar quantizer for Xii1L
  • Coset partition (M4) by trellis code.

Codebook (size of 8L), Rs 3 bits/sample, two
cosets
17
Encoding with a Fidelity Criterion
  • Example
  • Computing syndrome (Rs 3, Rc 2)
  • outcome of quantization be 7, 3, 2, 1, 4.
  • L 5,
  • Syndrome is given by 10110 for 5 samples.

18
Encoding with a Fidelity Criterion
  • Trellis-Based Quantization and Memoryless Coset
    Construction (C3)
  • Trellis coded quantizer
  • Memoryless coset partition
  • Example
  • Quantization codebook Rs 2
  • D0r0, r4, D1r1, r5, D2r2, r6, D3r3,
    r7.
  • Memoryless channel code Rc 1
  • 1 coded bit with another 1 uncoded bit (from Y)
    to recover Di.

19
Encoding with a Fidelity Criterion
  • Trellis-Based Quantization and Trellis-Based
    Coset Coset Construction (C4)
  • Trellis coded quantizer
  • Trellis coded coset partition

Comparison between C3 and C4.
20
Encoding with a Fidelity Criterion
  • Distance Property
  • Given a uniform partition, four cases of coset
    constructions have same distance property.
  • Non-uniform quantizer, analyze performance by
    simulations.

21
Outline
  • Introduction
  • Preliminaries
  • Encoding with a Fidelity Criterion
  • Problem Formulation
  • Design Algorithm
  • Four Constructions
  • Simulation Results
  • Conclusion

22
Simulation Results
Correlation -SNR ratio of Xs variance and Ns
variance.
  • Quantization levels decrease distortion. (C1)

23
Simulation Results
Correlation -SNR ratio of Xs variance and Ns
variance.
Quantization levels increase prob. Of error. (C1)
24
Simulation Results
Correlation -SNR ratio of Xs variance and Ns
variance.
Error probability comparison of C1 and C2 (3-4dB
gain)
25
Simulation Results
Correlation -SNR ratio of Xs variance and Ns
variance.
Error probability of C4 codes.
26
Conclusions
  • Constructive practical framework based on
    algebraic trellis codes.
  • Promising performance.
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