Homotopy based algorithms for 0-regularized least-squares

Abstract

Sparse signal restoration is usually formulated as the minimization of a quadratic cost function \|y-Ax\|22, where A is a dictionary and x is an unknown sparse vector. It is well-known that imposing an 0 constraint leads to an NP-hard minimization problem. The convex relaxation approach has received considerable attention, where the 0-norm is replaced by the 1-norm. Among the many efficient 1 solvers, the homotopy algorithm minimizes \|y-Ax\|22+λ\|x\|1 with respect to x for a continuum of λ's. It is inspired by the piecewise regularity of the 1-regularization path, also referred to as the homotopy path. In this paper, we address the minimization problem \|y-Ax\|22+λ\|x\|0 for a continuum of λ's and propose two heuristic search algorithms for 0-homotopy. Continuation Single Best Replacement is a forward-backward greedy strategy extending the Single Best Replacement algorithm, previously proposed for 0-minimization at a given λ. The adaptive search of the λ-values is inspired by 1-homotopy. 0 Regularization Path Descent is a more complex algorithm exploiting the structural properties of the 0-regularization path, which is piecewise constant with respect to λ. Both algorithms are empirically evaluated for difficult inverse problems involving ill-conditioned dictionaries. Finally, we show that they can be easily coupled with usual methods of model order selection.