Turbocharging Solution Concepts: Solving NEs, CEs and CCEs with Neural Equilibrium Solvers
Abstract
Solution concepts such as Nash Equilibria, Correlated Equilibria, and Coarse Correlated Equilibria are useful components for many multiagent machine learning algorithms. Unfortunately, solving a normal-form game could take prohibitive or non-deterministic time to converge, and could fail. We introduce the Neural Equilibrium Solver which utilizes a special equivariant neural network architecture to approximately solve the space of all games of fixed shape, buying speed and determinism. We define a flexible equilibrium selection framework, that is capable of uniquely selecting an equilibrium that minimizes relative entropy, or maximizes welfare. The network is trained without needing to generate any supervised training data. We show remarkable zero-shot generalization to larger games. We argue that such a network is a powerful component for many possible multiagent algorithms.
Cite
Text
Marris et al. "Turbocharging Solution Concepts: Solving NEs, CEs and CCEs with Neural Equilibrium Solvers." Neural Information Processing Systems, 2022.Markdown
[Marris et al. "Turbocharging Solution Concepts: Solving NEs, CEs and CCEs with Neural Equilibrium Solvers." Neural Information Processing Systems, 2022.](https://mlanthology.org/neurips/2022/marris2022neurips-turbocharging/)BibTeX
@inproceedings{marris2022neurips-turbocharging,
title = {{Turbocharging Solution Concepts: Solving NEs, CEs and CCEs with Neural Equilibrium Solvers}},
author = {Marris, Luke and Gemp, Ian and Anthony, Thomas and Tacchetti, Andrea and Liu, Siqi and Tuyls, Karl},
booktitle = {Neural Information Processing Systems},
year = {2022},
url = {https://mlanthology.org/neurips/2022/marris2022neurips-turbocharging/}
}