An Inexact Modified Quasi-Newton Method for Nonsmooth Regularized Optimization
Abstract
We introduce iR2N, a modified proximal quasi-Newton method for minimizing the sum of a smooth function and a lower semi-continuous prox-bounded function , allowing inexact evaluations of , its gradient, and the associated proximal operators. Both and may be nonconvex. iR2N is particularly suited to settings where proximal operators are computed via iterative procedures that can be stopped early, or where the accuracy of and can be controlled, leading to significant computational savings. At each iteration, the method approximately minimizes the sum of a quadratic model of , a model of , and an adaptive quadratic regularization term ensuring global convergence. Under standard accuracy assumptions, we prove global convergence in the sense that a first-order stationarity measure converges to zero, with worst-case evaluation complexity . Numerical experiments with norms, total variation, and the indicator of the nonconvex pseudo -norm ball illustrate the effectiveness and flexibility of the approach, and show how controlled inexactness can substantially reduce computational effort.
Cite
@article{arxiv.2512.14507,
title = {An Inexact Modified Quasi-Newton Method for Nonsmooth Regularized Optimization},
author = {Nathan Allaire and Sébastien Le Digabel and Dominique Orban},
journal= {arXiv preprint arXiv:2512.14507},
year = {2025}
}