State Evolution for Approximate Message Passing with Non-Separable Functions

Abstract

Given a high-dimensional data matrix A∈ Rm× n, Approximate Message Passing (AMP) algorithms construct sequences of vectors ut∈ Rn, vt∈ Rm, indexed by t∈\0,1,2…\ by iteratively applying A or A T, and suitable non-linear functions, which depend on the specific application. Special instances of this approach have been developed --among other applications-- for compressed sensing reconstruction, robust regression, Bayesian estimation, low-rank matrix recovery, phase retrieval, and community detection in graphs. For certain classes of random matrices A, AMP admits an asymptotically exact description in the high-dimensional limit m,n∞, which goes under the name of `state evolution.' Earlier work established state evolution for separable non-linearities (under certain regularity conditions). Nevertheless, empirical work demonstrated several important applications that require non-separable functions. In this paper we generalize state evolution to Lipschitz continuous non-separable nonlinearities, for Gaussian matrices A. Our proof makes use of Bolthausen's conditioning technique along with several approximation arguments. In particular, we introduce a modified algorithm (called LAMP for Long AMP) which is of independent interest.