A VMiPG method for composite optimization with nonsmooth term having no closed-form proximal mapping
Abstract
This paper concerns the minimization of the sum of a twice continuously differentiable function and a nonsmooth convex function without closed-form proximal mapping. For this class of nonconvex and nonsmooth problems, we propose a line-search based variable metric inexact proximal gradient (VMiPG) method with uniformly bounded positive definite variable metric linear operators. This method computes in each step an inexact minimizer of a strongly convex model such that the difference between its objective value and the optimal value is controlled by its squared distance from the current iterate, and then seeks an appropriate step-size along the obtained direction with an armijo line-search criterion. We prove that the iterate sequence converges to a stationary point when and are definable in the same o-minimal structure over the real field , and if addition the objective function is a KL function of exponent , the convergence has a local R-linear rate. The proposed VMiPG method with the variable metric linear operator constructed by the Hessian of the function is applied to the scenario that and have common composite structure, and numerical comparison with a state-of-art variable metric line-search algorithm indicates that the Hessian-based VMiPG method has a remarkable advantage in terms of the quality of objective values and the running time for those difficult problems such as high-dimensional fused weighted-lasso regressions.
Cite
@article{arxiv.2308.13776,
title = {A VMiPG method for composite optimization with nonsmooth term having no closed-form proximal mapping},
author = {Taiwei Zhang and Shaohua Pan and Ruyu Liu},
journal= {arXiv preprint arXiv:2308.13776},
year = {2024}
}