Title :
The Gaussian Many-Help-One Distributed Source Coding Problem
Author :
Tavildar, Saurabha ; Viswanath, Pramod ; Wagner, Aaron B.
Author_Institution :
Qualcomm Flarion Technol., Bridgewater, MA, USA
Abstract :
Jointly Gaussian memoryless sources are observed at N distinct terminals. The goal is to efficiently encode the observations in a distributed fashion so as to enable reconstruction of any one of the observations, say the first one, at the decoder subject to a quadratic fidelity criterion. Our main result is a precise characterization of the rate-distortion region when the covariance matrix of the sources satisfies a ¿tree-structure¿ condition. In this situation, a natural analog-digital separation scheme optimally trades off the distributed quantization rate tuples and the distortion in the reconstruction: each encoder consists of a point-to-point Gaussian vector quantizer followed by a Slepian-Wolf binning encoder. We also provide a partial converse that suggests that the tree-structure condition is fundamental.
Keywords :
Gaussian processes; covariance matrices; memoryless systems; source coding; trees (mathematics); vector quantisation; Gaussian many-help-one distributed source coding problem; Gaussian memoryless sources; Slepian-Wolf binning encoder; analog-digital separation scheme; covariance matrix; decoder subject; distributed fashion; distributed quantization rate tuples; point-to-point Gaussian vector quantizer; quadratic fidelity criterion; rate-distortion region; tree-structure condition; Covariance matrix; Decoding; Engineering profession; Gaussian distribution; Gaussian processes; Helium; Rate-distortion; Source coding; Statistics; Vector quantization; Entropy power inequality; Gaussian sources; many-help-one problem; network source coding; rate distortion; tree sources;
Journal_Title :
Information Theory, IEEE Transactions on
DOI :
10.1109/TIT.2009.2034791
