Learned layered coding for Successive Refinement in the Wyner-Ziv Problem
Abstract
We propose a data-driven approach to explicitly learn the progressive encoding of a continuous source, which is successively decoded with increasing levels of quality and with the aid of correlated side information. This setup refers to the successive refinement of the Wyner-Ziv coding problem. Assuming ideal Slepian-Wolf coding, our approach employs recurrent neural networks (RNNs) to learn layered encoders and decoders for the quadratic Gaussian case. The models are trained by minimizing a variational bound on the rate-distortion function of the successively refined Wyner-Ziv coding problem. We demonstrate that RNNs can explicitly retrieve layered binning solutions akin to scalable nested quantization. Moreover, the rate-distortion performance of the scheme is on par with the corresponding monolithic Wyner-Ziv coding approach and is close to the rate-distortion bound.
Cite
@article{arxiv.2311.03061,
title = {Learned layered coding for Successive Refinement in the Wyner-Ziv Problem},
author = {Boris Joukovsky and Brent De Weerdt and Nikos Deligiannis},
journal= {arXiv preprint arXiv:2311.03061},
year = {2023}
}
Comments
5 pages, submitted to ICASSP 2024