Plug-in Estimation in High-Dimensional Linear Inverse Problems: A Rigorous Analysis
Abstract
Estimating a vector from noisy linear measurements often requires use of prior knowledge or structural constraints on for accurate reconstruction. Several recent works have considered combining linear least-squares estimation with a generic or "plug-in" denoiser function that can be designed in a modular manner based on the prior knowledge about . While these methods have shown excellent performance, it has been difficult to obtain rigorous performance guarantees. This work considers plug-in denoising combined with the recently-developed Vector Approximate Message Passing (VAMP) algorithm, which is itself derived via Expectation Propagation techniques. It shown that the mean squared error of this "plug-and-play" VAMP can be exactly predicted for high-dimensional right-rotationally invariant random and Lipschitz denoisers. The method is demonstrated on applications in image recovery and parametric bilinear estimation.
Cite
@article{arxiv.1806.10466,
title = {Plug-in Estimation in High-Dimensional Linear Inverse Problems: A Rigorous Analysis},
author = {Alyson K. Fletcher and Sundeep Rangan and Subrata Sarkar and Philip Schniter},
journal= {arXiv preprint arXiv:1806.10466},
year = {2020}
}