On the Complexity of Deterministic Nonsmooth and Nonconvex Optimization
Abstract
In this paper, we present several new results on minimizing a nonsmooth and nonconvex function under a Lipschitz condition. Recent work shows that while the classical notion of Clarke stationarity is computationally intractable up to some sufficiently small constant tolerance, the randomized first-order algorithms find a -Goldstein stationary point with the complexity bound of , which is independent of dimension ~\citep{Zhang-2020-Complexity, Davis-2022-Gradient, Tian-2022-Finite}. However, the deterministic algorithms have not been fully explored, leaving open several problems in nonsmooth nonconvex optimization. Our first contribution is to demonstrate that the randomization is \textit{necessary} to obtain a dimension-independent guarantee, by proving a lower bound of for any deterministic algorithm that has access to both and oracles. Furthermore, we show that the oracle is \textit{essential} to obtain a finite-time convergence guarantee, by showing that any deterministic algorithm with only the oracle is not able to find an approximate Goldstein stationary point within a finite number of iterations up to sufficiently small constant parameter and tolerance. Finally, we propose a deterministic smoothing approach under the \textit{arithmetic circuit} model where the resulting smoothness parameter is exponential in a certain parameter (e.g., the number of nodes in the representation of the function), and design a new deterministic first-order algorithm that achieves a dimension-independent complexity bound of .
Cite
@article{arxiv.2209.12463,
title = {On the Complexity of Deterministic Nonsmooth and Nonconvex Optimization},
author = {Michael I. Jordan and Tianyi Lin and Manolis Zampetakis},
journal= {arXiv preprint arXiv:2209.12463},
year = {2022}
}
Comments
28 Pages; Fix an error and add relevant references