English

The Rate-Distortion Function and Excess-Distortion Exponent of Sparse Regression Codes with Optimal Encoding

Information Theory 2017-07-17 v6 math.IT Statistics Theory Statistics Theory

Abstract

This paper studies the performance of sparse regression codes for lossy compression with the squared-error distortion criterion. In a sparse regression code, codewords are linear combinations of subsets of columns of a design matrix. It is shown that with minimum-distance encoding, sparse regression codes achieve the Shannon rate-distortion function for i.i.d. Gaussian sources R(D)R^*(D) as well as the optimal excess-distortion exponent. This completes a previous result which showed that R(D)R^*(D) and the optimal exponent were achievable for distortions below a certain threshold. The proof of the rate-distortion result is based on the second moment method, a popular technique to show that a non-negative random variable XX is strictly positive with high probability. In our context, XX is the number of codewords within target distortion DD of the source sequence. We first identify the reason behind the failure of the standard second moment method for certain distortions, and illustrate the different failure modes via a stylized example. We then use a refinement of the second moment method to show that R(D)R^*(D) is achievable for all distortion values. Finally, the refinement technique is applied to Suen's correlation inequality to prove the achievability of the optimal Gaussian excess-distortion exponent.

Keywords

Cite

@article{arxiv.1401.5272,
  title  = {The Rate-Distortion Function and Excess-Distortion Exponent of Sparse Regression Codes with Optimal Encoding},
  author = {Ramji Venkataramanan and Sekhar Tatikonda},
  journal= {arXiv preprint arXiv:1401.5272},
  year   = {2017}
}

Comments

16 pages. IEEE Transactions on Information Theory

R2 v1 2026-06-22T02:51:00.996Z