Linear-Quadratic Mean-Field Reinforcement Learning: Convergence of Policy Gradient Methods

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Oct 09, 2019
René Carmona, Mathieu Laurière, Zongjun Tan
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We investigate reinforcement learning for mean field control problems in discrete time, which can be viewed as Markov decision processes for a large number of exchangeable agents interacting in a mean field manner. Such problems arise, for instance when a large number of robots communicate through a central unit dispatching the optimal policy computed by minimizing the overall social cost. An approximate solution is obtained by learning the optimal policy of a generic agent interacting with the statistical distribution of the states of the other agents. We prove rigorously the convergence of exact and model-free policy gradient methods in a mean-field linear-quadratic setting. We also provide graphical evidence of the convergence based on implementations of our algorithms.

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