Towards a better compressed sensing
Abstract
In this paper we look at a well known linear inverse problem that is one of the mathematical cornerstones of the compressed sensing field. In seminal works \cite{CRT,DOnoho06CS} optimization and its success when used for recovering sparse solutions of linear inverse problems was considered. Moreover, \cite{CRT,DOnoho06CS} established for the first time in a statistical context that an unknown vector of linear sparsity can be recovered as a known existing solution of an under-determined linear system through optimization. In \cite{DonohoPol,DonohoUnsigned} (and later in \cite{StojnicCSetam09,StojnicUpper10}) the precise values of the linear proportionality were established as well. While the typical optimization behavior has been essentially settled through the work of \cite{DonohoPol,DonohoUnsigned,StojnicCSetam09,StojnicUpper10}, we in this paper look at possible upgrades of optimization. Namely, we look at a couple of algorithms that turn out to be capable of recovering a substantially higher sparsity than the . However, these algorithms assume a bit of "feedback" to be able to work at full strength. This in turn then translates the original problem of improving upon to designing algorithms that would be able to provide output needed to feed the upgrades considered in this papers.
Cite
@article{arxiv.1306.3801,
title = {Towards a better compressed sensing},
author = {Mihailo Stojnic},
journal= {arXiv preprint arXiv:1306.3801},
year = {2015}
}
Comments
acknowledgement footnote added