Optimal Rates of Convergence for Noisy Sparse Phase Retrieval via Thresholded Wirtinger Flow

Abstract

This paper considers the noisy sparse phase retrieval problem: recovering a sparse signal x ∈ Rp from noisy quadratic measurements yj = (aj' x )2 + εj, j=1, …, m, with independent sub-exponential noise εj. The goals are to understand the effect of the sparsity of x on the estimation precision and to construct a computationally feasible estimator to achieve the optimal rates. Inspired by the Wirtinger Flow [12] proposed for noiseless and non-sparse phase retrieval, a novel thresholded gradient descent algorithm is proposed and it is shown to adaptively achieve the minimax optimal rates of convergence over a wide range of sparsity levels when the aj's are independent standard Gaussian random vectors, provided that the sample size is sufficiently large compared to the sparsity of x.