Strong Data Processing Inequalities for Input Constrained Additive Noise Channels
Abstract
This paper quantifies the intuitive observation that adding noise reduces available information by means of non-linear strong data processing inequalities. Consider the random variables forming a Markov chain, where with and real-valued, independent and bounded in -norm. It is shown that with whenever , if and only if has a density whose support is not disjoint from any translate of itself. A related question is to characterize for what couplings the mutual information is close to maximum possible. To that end we show that in order to saturate the channel, i.e. for to approach capacity, it is mandatory that (under suitable conditions on the channel). A key ingredient for this result is a deconvolution lemma which shows that post-convolution total variation distance bounds the pre-convolution Kolmogorov-Smirnov distance. Explicit bounds are provided for the special case of the additive Gaussian noise channel with quadratic cost constraint. These bounds are shown to be order-optimal. For this case simplified proofs are provided leveraging Gaussian-specific tools such as the connection between information and estimation (I-MMSE) and Talagrand's information-transportation inequality.
Cite
@article{arxiv.1512.06429,
title = {Strong Data Processing Inequalities for Input Constrained Additive Noise Channels},
author = {Flavio P. Calmon and Yury Polyanskiy and Yihong Wu},
journal= {arXiv preprint arXiv:1512.06429},
year = {2017}
}