An efficient sieving based secant method for sparse optimization problems with least-squares constraints
Abstract
In this paper, we propose an efficient sieving based secant method to address the computational challenges of solving sparse optimization problems with least-squares constraints. A level-set method has been introduced in [X. Li, D.F. Sun, and K.-C. Toh, SIAM J. Optim., 28 (2018), pp. 1842--1866] that solves these problems by using the bisection method to find a root of a univariate nonsmooth equation for some , where is the value function computed by a solution of the corresponding regularized least-squares optimization problem. When the objective function in the constrained problem is a polyhedral gauge function, we prove that (i) for any positive integer , is piecewise in an open interval containing the solution to the equation ; (ii) the Clarke Jacobian of is always positive. These results allow us to establish the essential ingredients of the fast convergence rates of the secant method. Moreover, an adaptive sieving technique is incorporated into the secant method to effectively reduce the dimension of the level-set subproblems for computing the value of . The high efficiency of the proposed algorithm is demonstrated by extensive numerical results.
Cite
@article{arxiv.2308.07812,
title = {An efficient sieving based secant method for sparse optimization problems with least-squares constraints},
author = {Qian Li and Defeng Sun and Yancheng Yuan},
journal= {arXiv preprint arXiv:2308.07812},
year = {2024}
}