English

Strong Data Processing Inequalities for Input Constrained Additive Noise Channels

Information Theory 2017-11-21 v2 math.IT

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 WXYW\to X\to Y forming a Markov chain, where Y=X+ZY=X+Z with XX and ZZ real-valued, independent and XX bounded in LpL_p-norm. It is shown that I(W;Y)FI(I(W;X))I(W;Y) \le F_I(I(W;X)) with FI(t)<tF_I(t)<t whenever t>0t>0, if and only if ZZ has a density whose support is not disjoint from any translate of itself. A related question is to characterize for what couplings (W,X)(W,X) the mutual information I(W;Y)I(W;Y) is close to maximum possible. To that end we show that in order to saturate the channel, i.e. for I(W;Y)I(W;Y) to approach capacity, it is mandatory that I(W;X)I(W;X)\to\infty (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.

Keywords

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}
}
R2 v1 2026-06-22T12:14:28.883Z