Global Convergence of Localized Policy Iteration in Networked Multi-Agent Reinforcement Learning
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2023-06-19
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We study a multi-agent reinforcement learning (MARL) problem where the agents interact over a given network. The goal of the agents is to cooperatively maximize the average of their entropy-regularized long-term rewards. To overcome the curse of dimensionality and to reduce communication, we propose a Localized Policy Iteration (LPI) algorithm that provably learns a near-globally-optimal policy using only local information. In particular, we show that, despite restricting each agent's attention to only its κ-hop neighborhood, the agents are able to learn a policy with an optimality gap that decays polynomially in κ. In addition, we show the finite-sample convergence of LPI to the global optimal policy, which explicitly captures the trade-off between optimality and computational complexity in choosing κ. Numerical simulations demonstrate the effectiveness of LPI. This extended abstract is an abridged version of [12].
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Zhang, Y, G Qu, P Xu, Y Lin, Z Chen and A Wierman (2023). Global Convergence of Localized Policy Iteration in Networked Multi-Agent Reinforcement Learning. Performance Evaluation Review, 51(1). pp. 83–84. 10.1145/3606376.3593545 Retrieved from https://hdl.handle.net/10161/33469.
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Pan Xu
My research is centered around Machine Learning, with broad interests in the areas of Artificial Intelligence, Data Science, Optimization, Reinforcement Learning, High Dimensional Statistics, and their applications to real-world problems including Bioinformatics and Healthcare. My research goal is to develop computationally- and data-efficient machine learning algorithms with both strong empirical performance and theoretical guarantees.
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