Lower Bounds for Compressed Sensing with Generative Models
Abstract
The goal of compressed sensing is to learn a structured signal from a limited number of noisy linear measurements . In traditional compressed sensing, "structure" is represented by sparsity in some known basis. Inspired by the success of deep learning in modeling images, recent work starting with~\cite{BJPD17} has instead considered structure to come from a generative model . We present two results establishing the difficulty of this latter task, showing that existing bounds are tight. First, we provide a lower bound matching the~\cite{BJPD17} upper bound for compressed sensing from -Lipschitz generative models . In particular, there exists such a function that requires roughly linear measurements for sparse recovery to be possible. This holds even for the more relaxed goal of \emph{nonuniform} recovery. Second, we show that generative models generalize sparsity as a representation of structure. In particular, we construct a ReLU-based neural network with layers and activations per layer, such that the range of contains all -sparse vectors.
Cite
@article{arxiv.1912.02938,
title = {Lower Bounds for Compressed Sensing with Generative Models},
author = {Akshay Kamath and Sushrut Karmalkar and Eric Price},
journal= {arXiv preprint arXiv:1912.02938},
year = {2019}
}