Revisiting Subgradient Method: Complexity and Convergence Beyond Lipschitz Continuity
Abstract
The subgradient method is one of the most fundamental algorithmic schemes for nonsmooth optimization. The existing complexity and convergence results for this method are mainly derived for Lipschitz continuous objective functions. In this work, we first extend the typical iteration complexity results for the subgradient method to cover non-Lipschitz convex and weakly convex minimization. Specifically, for the convex case, we can drive the suboptimality gap to below in iterations; for the weakly convex case, we can drive the gradient norm of the Moreau envelope of the objective function to below in iterations. Then, we provide convergence results for the subgradient method in the non-Lipschitz setting when proper diminishing rules on the step size are used. In particular, when is convex, we establish an rate of convergence in terms of the suboptimality gap, where represents the iteration count. With an additional quadratic growth property, the rate is improved to in terms of the squared distance to the optimal solution set. When is weakly convex, asymptotic convergence is established. Our results neither require any modification to the subgradient method nor impose any growth condition on the subgradients, while our analysis is surprisingly simple. To further illustrate the wide applicability of our framework, we extend the aforementioned iteration complexity results to cover the truncated subgradient, the stochastic subgradient, and the proximal subgradient methods for non-Lipschitz convex / weakly convex objective functions.
Cite
@article{arxiv.2305.14161,
title = {Revisiting Subgradient Method: Complexity and Convergence Beyond Lipschitz Continuity},
author = {Xiao Li and Lei Zhao and Daoli Zhu and Anthony Man-Cho So},
journal= {arXiv preprint arXiv:2305.14161},
year = {2024}
}
Comments
Vietnam J. Math. (2024)