DocumentCode
1546174
Title
Block and Sliding-Block Lossy Compression via MCMC
Author
Jalali, Shirin ; Weissman, Tsachy
Author_Institution
Center for Mathematics of Information at California Institute of Technology
Volume
60
Issue
8
fYear
2012
fDate
8/1/2012 12:00:00 AM
Firstpage
2187
Lastpage
2198
Abstract
We propose an approach to lossy compression of finite-alphabet sources that utilizes Markov chain Monte Carlo (MCMC) and simulated annealing methods. The idea is to define an energy function over the space of reconstruction sequences. The energy of a candidate reconstruction sequence is defined such that it incorporates its distortion relative to the source sequence, its compressibility, and the point sought on the rate-distortion curve. The proposed algorithm samples from the Boltzmann distribution associated with this energy function using the "heat-bath" algorithm. The complexity of each iteration is independent of the sequence length and is only linearly dependent on a certain context parameter, which grows sub-logarithmically with the sequence length. We show that the proposed algorithm achieves optimum rate-distortion performance in the limits of large number of iterations, and sequence length, when employed on any stationary ergodic source. Inspired by the proposed block-coding algorithm, we also propose an algorithm for constructing sliding-block (SB) codes using similar ideas.
Keywords
Compression algorithms; Encoding; Entropy; Markov processes; Rate-distortion; Simulated annealing; Vectors; Gibbs sampler; Markov chain Monte Carlo; Rate-distortion coding; simulated annealing; universal lossy compression;
fLanguage
English
Journal_Title
Communications, IEEE Transactions on
Publisher
ieee
ISSN
0090-6778
Type
jour
DOI
10.1109/TCOMM.2012.061412.110194
Filename
6222291
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