Stochastic Hamiltonian Gradient Methods for Smooth Games
Abstract
The success of adversarial formulations in machine learning has brought renewed motivation for smooth games. In this work, we focus on the class of stochastic Hamiltonian methods and provide the first convergence guarantees for certain classes of stochastic smooth games. We propose a novel unbiased estimator for the stochastic Hamiltonian gradient descent (SHGD) and highlight its benefits. Using tools from the optimization literature we show that SHGD converges linearly to the neighbourhood of a stationary point. To guarantee convergence to the exact solution, we analyze SHGD with a decreasing step-size and we also present the first stochastic variance reduced Hamiltonian method. Our results provide the first global non-asymptotic last-iterate convergence guarantees for the class of stochastic unconstrained bilinear games and for the more general class of stochastic games that satisfy a "sufficiently bilinear" condition, notably including some non-convex non-concave problems. We supplement our analysis with experiments on stochastic bilinear and sufficiently bilinear games, where our theory is shown to be tight, and on simple adversarial machine learning formulations.
Cite
@article{arxiv.2007.04202,
title = {Stochastic Hamiltonian Gradient Methods for Smooth Games},
author = {Nicolas Loizou and Hugo Berard and Alexia Jolicoeur-Martineau and Pascal Vincent and Simon Lacoste-Julien and Ioannis Mitliagkas},
journal= {arXiv preprint arXiv:2007.04202},
year = {2020}
}
Comments
ICML 2020 - Proceedings of the 37th International Conference on Machine Learning