Analyzing Weighted $\ell_1$ Minimization for Sparse Recovery With Nonuniform Sparse Models

Abstract

In this paper, we introduce a nonuniform sparsity model and analyze the performance of an optimized weighted l1 minimization over that sparsity model. In particular, we focus on a model where the entries of the unknown vector fall into two sets, with entries of each set having a specific probability of being nonzero. We propose a weighted l1 minimization recovery algorithm and analyze its performance using a Grassmann angle approach. We compute explicitly the relationship between the system parameters-the weights, the number of measurements, the size of the two sets, the probabilities of being nonzero-so that when i.i.d. random Gaussian measurement matrices are used, the weighted l1 minimization recovers a randomly selected signal drawn from the considered sparsity model with overwhelming probability as the problem dimension increases. This allows us to compute the optimal weights. We demonstrate through rigorous analysis and simulations that for the case when the support of the signal can be divided into two different subclasses with unequal sparsity fractions, the weighted l1 minimization outperforms the regular l1 minimization substantially. We also generalize our results to signal vectors with an arbitrary number of subclasses for sparsity.