A new method based on the bundle idea and gradient sampling technique for minimizing nonsmooth convex functions

TL;DR

This paper introduces a novel optimization method that combines gradient sampling and bundle techniques to efficiently solve large-scale nonsmooth convex problems with fewer gradient evaluations and less sensitivity to gradient accuracy.

Contribution

The paper develops a new robust method integrating GS and bundle ideas, reducing gradient evaluations and relaxing differentiability requirements for convex optimization.

Findings

Requires fewer gradient evaluations than original GS methods.

Converges without full differentiability of the objective function.

Shows promising numerical results on large-scale problems.

Abstract

In this paper, we combine the positive aspects of the Gradient Sampling (GS) and bundle methods, as the most efficient methods in nonsmooth optimization, to develop a robust method for solving unconstrained nonsmooth convex optimization problems. The main aim of the proposed method is to take advantage of both GS and bundle methods, meanwhile avoiding their drawbacks. At each iteration of this method, to find an efficient descent direction, the GS technique is utilized for constructing a local polyhedral model for the objective function. If necessary, via an iterative improvement process, this initial polyhedral model is improved by some techniques inspired by the bundle and GS methods. The convergence of the method is studied, which reveals the following positive features (i) The convergence of our method is independent of the number of gradient evaluations required to establish and improve the initial polyhedral models. Thus, the presented method needs much fewer gradient evaluations in comparison to the original GS method. (ii) As opposed to GS type methods, the objective function need not be continuously differentiable on a full measure open set in $\mathbb R^n$ to ensure the convergence for the class of convex problems. Apart from the mentioned advantages, by means of numerical simulations, we show that the presented method provides promising results in comparison with GS methods, especially for large scale problems. Moreover, in contrast with bundle methods, our method is not very sensitive to the accuracy of supplied gradients.