Performance analysis of tail-minimization and the linear rate of convergence of a proximal algorithm for sparse signal recovery

Abstract

Recovery error bounds of tail-minimization and the rate of convergence of an efficient proximal alternating algorithm for sparse signal recovery are considered in this article. Tail-minimization focuses on minimizing the energy in the complement Tc of an estimated support T. Under the restricted isometry property (RIP) condition, we prove that tail-1 minimization can exactly recover sparse signals in the noiseless case for a given T. In the noisy case, two recovery results for the tail-1 minimization and the tail-lasso models are established. Error bounds are improved over existing results. Additionally, we show that the RIP condition becomes surprisingly relaxed, allowing the RIP constant to approach 1 as the estimation T closely approximates the true support S. Finally, an efficient proximal alternating minimization algorithm is introduced for solving the tail-lasso problem using Hadamard product parametrization. The linear rate of convergence is established using the Kurdyka-ojasiewicz inequality. Numerical results demonstrate that the proposed algorithm significantly improves signal recovery performance compared to state-of-the-art techniques.