English

Vector Approximate Message Passing for the Generalized Linear Model

Information Theory 2016-12-06 v1 math.IT

Abstract

The generalized linear model (GLM), where a random vector x\boldsymbol{x} is observed through a noisy, possibly nonlinear, function of a linear transform output z=Ax\boldsymbol{z}=\boldsymbol{Ax}, arises in a range of applications such as robust regression, binary classification, quantized compressed sensing, phase retrieval, photon-limited imaging, and inference from neural spike trains. When A\boldsymbol{A} is large and i.i.d. Gaussian, the generalized approximate message passing (GAMP) algorithm is an efficient means of MAP or marginal inference, and its performance can be rigorously characterized by a scalar state evolution. For general A\boldsymbol{A}, though, GAMP can misbehave. Damping and sequential-updating help to robustify GAMP, but their effects are limited. Recently, a "vector AMP" (VAMP) algorithm was proposed for additive white Gaussian noise channels. VAMP extends AMP's guarantees from i.i.d. Gaussian A\boldsymbol{A} to the larger class of rotationally invariant A\boldsymbol{A}. In this paper, we show how VAMP can be extended to the GLM. Numerical experiments show that the proposed GLM-VAMP is much more robust to ill-conditioning in A\boldsymbol{A} than damped GAMP.

Keywords

Cite

@article{arxiv.1612.01186,
  title  = {Vector Approximate Message Passing for the Generalized Linear Model},
  author = {Philip Schniter and Sundeep Rangan and Alyson K. Fletcher},
  journal= {arXiv preprint arXiv:1612.01186},
  year   = {2016}
}
R2 v1 2026-06-22T17:13:04.364Z