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An Expectation-Maximization Approach to Tuning Generalized Vector Approximate Message Passing

Information Theory 2018-06-27 v1 math.IT

Abstract

Generalized Vector Approximate Message Passing (GVAMP) is an efficient iterative algorithm for approximately minimum-mean-squared-error estimation of a random vector xpx(x)\mathbf{x}\sim p_{\mathbf{x}}(\mathbf{x}) from generalized linear measurements, i.e., measurements of the form y=Q(z)\mathbf{y}=Q(\mathbf{z}) where z=Ax\mathbf{z}=\mathbf{Ax} with known A\mathbf{A}, and Q()Q(\cdot) is a noisy, potentially nonlinear, componentwise function. Problems of this form show up in numerous applications, including robust regression, binary classification, quantized compressive sensing, and phase retrieval. In some cases, the prior pxp_{\mathbf{x}} and/or channel Q()Q(\cdot) depend on unknown deterministic parameters θ\boldsymbol{\theta}, which prevents a direct application of GVAMP. In this paper we propose a way to combine expectation maximization (EM) with GVAMP to jointly estimate x\mathbf{x} and θ\boldsymbol{\theta}. We then demonstrate how EM-GVAMP can solve the phase retrieval problem with unknown measurement-noise variance.

Keywords

Cite

@article{arxiv.1806.10079,
  title  = {An Expectation-Maximization Approach to Tuning Generalized Vector Approximate Message Passing},
  author = {Christopher A. Metzler and Philip Schniter and Richard G. Baraniuk},
  journal= {arXiv preprint arXiv:1806.10079},
  year   = {2018}
}
R2 v1 2026-06-23T02:42:30.166Z