Inference with Deep Generative Priors in High Dimensions
Abstract
Deep generative priors offer powerful models for complex-structured data, such as images, audio, and text. Using these priors in inverse problems typically requires estimating the input and/or hidden signals in a multi-layer deep neural network from observation of its output. While these approaches have been successful in practice, rigorous performance analysis is complicated by the non-convex nature of the underlying optimization problems. This paper presents a novel algorithm, Multi-Layer Vector Approximate Message Passing (ML-VAMP), for inference in multi-layer stochastic neural networks. ML-VAMP can be configured to compute maximum a priori (MAP) or approximate minimum mean-squared error (MMSE) estimates for these networks. We show that the performance of ML-VAMP can be exactly predicted in a certain high-dimensional random limit. Furthermore, under certain conditions, ML-VAMP yields estimates that achieve the minimum (i.e., Bayes-optimal) MSE as predicted by the replica method. In this way, ML-VAMP provides a computationally efficient method for multi-layer inference with an exact performance characterization and testable conditions for optimality in the large-system limit.
Cite
@article{arxiv.1911.03409,
title = {Inference with Deep Generative Priors in High Dimensions},
author = {Parthe Pandit and Mojtaba Sahraee-Ardakan and Sundeep Rangan and Philip Schniter and Alyson K. Fletcher},
journal= {arXiv preprint arXiv:1911.03409},
year = {2019}
}
Comments
50 pages, double-spaced