Parametric Bilinear Generalized Approximate Message Passing

Abstract

We propose a scheme to estimate the parameters bi and cj of the bilinear form zm=Σi,j bi zm(i,j) cj from noisy measurements \ym\m=1M, where ym and zm are related through an arbitrary likelihood function and zm(i,j) are known. Our scheme is based on generalized approximate message passing (G-AMP): it treats bi and cj as random variables and zm(i,j) as an i.i.d.\ Gaussian 3-way tensor in order to derive a tractable simplification of the sum-product algorithm in the large-system limit. It generalizes previous instances of bilinear G-AMP, such as those that estimate matrices B and C from a noisy measurement of Z=BC, allowing the application of AMP methods to problems such as self-calibration, blind deconvolution, and matrix compressive sensing. Numerical experiments confirm the accuracy and computational efficiency of the proposed approach.