LEAD: Min-Max Optimization from a Physical Perspective
Abstract
Adversarial formulations such as generative adversarial networks (GANs) have rekindled interest in two-player min-max games. A central obstacle in the optimization of such games is the rotational dynamics that hinder their convergence. In this paper, we show that game optimization shares dynamic properties with particle systems subject to multiple forces, and one can leverage tools from physics to improve optimization dynamics. Inspired by the physical framework, we propose LEAD, an optimizer for min-max games. Next, using Lyapunov stability theory and spectral analysis, we study LEAD’s convergence properties in continuous and discrete time settings for a class of quadratic min-max games to demonstrate linear convergence to the Nash equilibrium. Finally, we empirically evaluate our method on synthetic setups and CIFAR-10 image generation to demonstrate improvements in GAN training.
Cite
Text
Hemmat et al. "LEAD: Min-Max Optimization from a Physical Perspective." Transactions on Machine Learning Research, 2023.Markdown
[Hemmat et al. "LEAD: Min-Max Optimization from a Physical Perspective." Transactions on Machine Learning Research, 2023.](https://mlanthology.org/tmlr/2023/hemmat2023tmlr-lead/)BibTeX
@article{hemmat2023tmlr-lead,
title = {{LEAD: Min-Max Optimization from a Physical Perspective}},
author = {Hemmat, Reyhane Askari and Mitra, Amartya and Lajoie, Guillaume and Mitliagkas, Ioannis},
journal = {Transactions on Machine Learning Research},
year = {2023},
url = {https://mlanthology.org/tmlr/2023/hemmat2023tmlr-lead/}
}