Decentralized Gradient-Free Methods for Stochastic Non-Smooth Non-Convex Optimization
Abstract
We consider decentralized gradient-free optimization of minimizing Lipschitz continuous functions that satisfy neither smoothness nor convexity assumption. We propose two novel gradient-free algorithms, the Decentralized Gradient-Free Method (DGFM) and its variant, the Decentralized Gradient-Free Method (DGFM). Based on the techniques of randomized smoothing and gradient tracking, DGFM requires the computation of the zeroth-order oracle of a single sample in each iteration, making it less demanding in terms of computational resources for individual computing nodes. Theoretically, DGFM achieves a complexity of for obtaining an -Goldstein stationary point. DGFM, an advanced version of DGFM, incorporates variance reduction to further improve the convergence behavior. It samples a mini-batch at each iteration and periodically draws a larger batch of data, which improves the complexity to . Moreover, experimental results underscore the empirical advantages of our proposed algorithms when applied to real-world datasets.
Cite
@article{arxiv.2310.11973,
title = {Decentralized Gradient-Free Methods for Stochastic Non-Smooth Non-Convex Optimization},
author = {Zhenwei Lin and Jingfan Xia and Qi Deng and Luo Luo},
journal= {arXiv preprint arXiv:2310.11973},
year = {2025}
}