Sharp MSE Bounds for Proximal Denoising
Abstract
Denoising has to do with estimating a signal from its noisy observations . In this paper, we focus on the "structured denoising problem", where the signal possesses a certain structure and has independent normally distributed entries with mean zero and variance . We employ a structure-inducing convex function and solve to estimate , for some . Common choices for include the norm for sparse vectors, the norm for block-sparse signals and the nuclear norm for low-rank matrices. The metric we use to evaluate the performance of an estimate is the normalized mean-squared-error . We show that NMSE is maximized as and we find the \emph{exact} worst case NMSE, which has a simple geometric interpretation: the mean-squared-distance of a standard normal vector to the -scaled subdifferential . When is optimally tuned to minimize the worst-case NMSE, our results can be related to the constrained denoising problem . The paper also connects these results to the generalized LASSO problem, in which, one solves to estimate from noisy linear observations . We show that certain properties of the LASSO problem are closely related to the denoising problem. In particular, we characterize the normalized LASSO cost and show that it exhibits a "phase transition" as a function of number of observations. Our results are significant in two ways. First, we find a simple formula for the performance of a general convex estimator. Secondly, we establish a connection between the denoising and linear inverse problems.
Cite
@article{arxiv.1305.2714,
title = {Sharp MSE Bounds for Proximal Denoising},
author = {Samet Oymak and Babak Hassibi},
journal= {arXiv preprint arXiv:1305.2714},
year = {2013}
}
Comments
37 pages