On the Performance of Amplitude-Based Models for Low-Rank Matrix Recovery

Abstract

In this paper, we focus on low-rank phase retrieval, which aims to reconstruct a matrix X0∈ Rn× m with rank(X0) r from noise-corrupted amplitude measurements y=|A(X0)|+η, where A:Rn× m→ Rp is a linear map and η∈ Rp is the noise vector. We first examine the rank-constrained nonlinear least-squares model X∈ argminX∈ Rn× m,rank(X) r\||A(X)|-y\|22 to estimate X0, and demonstrate that the reconstruction error satisfies \\|X-X0\|F, \|X+X0\|F\ \|η\|2p with high probability, provided A is a Gaussian measurement ensemble and p (m+n)r. We also prove that the error bound \|η\|2p is tight up to a constant. Furthermore, we relax the rank constraint to a nuclear-norm constraint. Hence, we propose the Lasso model for low-rank phase retrieval, i.e., the constrained nuclear-norm model and the unconstrained version. We also establish comparable theoretical guarantees for these models. To achieve this, we introduce a strong restricted isometry property (SRIP) for the linear map A, analogous to the strong RIP in phase retrieval. This work provides a unified treatment that extends existing results in both phase retrieval and low-rank matrix recovery from rank-one measurements.