Games played by Exponential Weights Algorithms
Abstract
This paper studies the last-iterate convergence properties of the exponential weights algorithm with constant learning rates. We consider a repeated interaction in discrete time, where each player uses an exponential weights algorithm characterized by an initial mixed action and a fixed learning rate, so that the mixed action profile played at stage follows an homogeneous Markov chain. At first, we show that whenever a strict Nash equilibrium exists, the probability to play a strict Nash equilibrium at the next stage converges almost surely to 0 or 1. Secondly, we show that the limit of , whenever it exists, belongs to the set of ``Nash Equilibria with Equalizing Payoffs''. Thirdly, we show that in strong coordination games, where the payoff of a player is positive on the diagonal and 0 elsewhere, converges almost surely to one of the strict Nash equilibria. We conclude with open questions.
Keywords
Cite
@article{arxiv.2407.06676,
title = {Games played by Exponential Weights Algorithms},
author = {Maurizio d'Andrea and Fabien Gensbittel and Jérôme Renault},
journal= {arXiv preprint arXiv:2407.06676},
year = {2024}
}