Solving Complex Quadratic Systems with Full-Rank Random Matrices
Abstract
We tackle the problem of recovering a complex signal from quadratic measurements of the form , where is a full-rank, complex random measurement matrix whose entries are generated from a rotation-invariant sub-Gaussian distribution. We formulate it as the minimization of a nonconvex loss. This problem is related to the well understood phase retrieval problem where the measurement matrix is a rank-1 positive semidefinite matrix. Here we study the general full-rank case which models a number of key applications such as molecular geometry recovery from distance distributions and compound measurements in phaseless diffractive imaging. Most prior works either address the rank-1 case or focus on real measurements. The several papers that address the full-rank complex case adopt the computationally-demanding semidefinite relaxation approach. In this paper we prove that the general class of problems with rotation-invariant sub-Gaussian measurement models can be efficiently solved with high probability via the standard framework comprising a spectral initialization followed by iterative Wirtinger flow updates on a nonconvex loss. Numerical experiments on simulated data corroborate our theoretical analysis.
Cite
@article{arxiv.1902.05612,
title = {Solving Complex Quadratic Systems with Full-Rank Random Matrices},
author = {Shuai Huang and Sidharth Gupta and Ivan Dokmanić},
journal= {arXiv preprint arXiv:1902.05612},
year = {2021}
}
Comments
This updated version of the manuscript addresses several important issues in the initial arXiv submission