Efficient and Robust Recovery of Signal and Image in Impulsive Noise via 1-α 2 Minimization

Abstract

In this paper, we consider the efficient and robust reconstruction of signals and images via 1-α 2~(0<α≤ 1) minimization in impulsive noise case. To achieve this goal, we introduce two new models: the 1-α2 minimization with 1 constraint, which is called 1-α2-LAD, the 1-α2 minimization with Dantzig selector constraint, which is called 1-α2-DS. We first show that sparse signals or nearly sparse signals can be exactly or stably recovered via 1-α2 minimization under some conditions based on the restricted 1-isometry property (1-RIP). Second, for 1-α2-LAD model, we introduce unconstrained 1-α2 minimization model denoting 1-α2-PLAD and propose 1-α2LA algorithm to solve the 1-α2-PLAD. Last, numerical experiments %on success rates of sparse signal recovery demonstrate that when the sensing matrix is ill-conditioned (i.e., the coherence of the matrix is larger than 0.99), the 1-α2LA method is better than the existing convex and non-convex compressed sensing solvers for the recovery of sparse signals. And for the magnetic resonance imaging (MRI) reconstruction with impulsive noise, we show that the 1-α2LA method has better performance than state-of-the-art methods via numerical experiments.