Generalized Gaussian Multiterminal Source Coding: The Symmetric Case

Abstract

Consider a generalized multiterminal source coding system, where m encoders, each observing a distinct size-m subset of (≥ 2) zero-mean unit-variance symmetrically correlated Gaussian sources with correlation coefficient , compress their observations in such a way that a joint decoder can reconstruct the sources within a prescribed mean squared error distortion based on the compressed data. The optimal rate-distortion performance of this system was previously known only for the two extreme cases m= (the centralized case) and m=1 (the distributed case), and except when =0, the centralized system can achieve strictly lower compression rates than the distributed system under all non-trivial distortion constraints. Somewhat surprisingly, it is established in the present paper that the optimal rate-distortion performance of the afore-described generalized multiterminal source coding system with m≥ 2 coincides with that of the centralized system for all distortions when ≤ 0 and for distortions below an explicit positive threshold (depending on m) when >0. Moreover, when >0, the minimum achievable rate of generalized multiterminal source coding subject to an arbitrary positive distortion constraint d is shown to be within a finite gap (depending on m and d) from its centralized counterpart in the large limit except for possibly the critical distortion d=1-.