Computational Complexity of Certifying Restricted Isometry Property
Abstract
Given a matrix with rows, a number , and , is -RIP (Restricted Isometry Property) if, for any vector , with at most non-zero co-ordinates, In many applications, such as compressed sensing and sparse recovery, it is desirable to construct RIP matrices with a large and a small . Given the efficacy of random constructions in generating useful RIP matrices, the problem of certifying the RIP parameters of a matrix has become important. In this paper, we prove that it is hard to approximate the RIP parameters of a matrix assuming the Small-Set-Expansion-Hypothesis. Specifically, we prove that for any arbitrarily large constant and any arbitrarily small constant , there exists some such that given a matrix , it is SSE-Hard to distinguish the following two cases: - (Highly RIP) is -RIP. - (Far away from RIP) is not -RIP. Most of the previous results on the topic of hardness of RIP certification only hold for certification when . In practice, it is of interest to understand the complexity of certifying a matrix with being close to , as it suffices for many real applications to have matrices with . Our hardness result holds for any constant . Specifically, our result proves that even if is indeed very small, i.e. the matrix is in fact \emph{strongly RIP}, certifying that the matrix exhibits \emph{weak RIP} itself is SSE-Hard. In order to prove the hardness result, we prove a variant of the Cheeger's Inequality for sparse vectors.
Cite
@article{arxiv.1406.5791,
title = {Computational Complexity of Certifying Restricted Isometry Property},
author = {Abhiram Natarajan and Yi Wu},
journal= {arXiv preprint arXiv:1406.5791},
year = {2014}
}