A Payoff-Based Policy Gradient Method in Stochastic Games with Long-Run Average Payoffs

Despite the significant potential for various applications, stochastic games with long-run average payoffs have received limited scholarly attention, particularly concerning the development of learning algorithms for them due to the challenges of mathematical analysis. In this paper, we study the stochastic games with long-run average payoffs and present an equivalent formulation for individual payoff gradients by defining advantage functions which will be proved to be bounded. This discovery allows us to demonstrate that the individual payoff gradient function is Lipschitz continuous with respect to the policy profile and that the value function of the games exhibits the gradient dominance property. Leveraging these insights, we devise a payoff-based gradient estimation approach and integrate it with the Regularized Robbins-Monro method from stochastic approximation theory to construct a bandit learning algorithm suited for stochastic games with long-run average payoffs. Additionally, we prove that if all players adopt our algorithm, the policy profile employed will asymptotically converge to a Nash equilibrium with probability one, provided that all Nash equilibria are globally neutrally stable and a globally variationally stable Nash equilibrium exists. This condition represents a wide class of games, including monotone games.