Scalable spectral representations for multi-agent reinforcement learning in network MDPs
Abstract
Network Markov Decision Processes (MDPs), a popular model for multi-agent control, pose a significant challenge to efficient learning due to the exponential growth of the global state-action space with the number of agents. In this work, utilizing the exponential decay property of network dynamics, we first derive scalable spectral local representations for network MDPs, which induces a network linear subspace for the local -function of each agent. Building on these local spectral representations, we design a scalable algorithmic framework for continuous state-action network MDPs, and provide end-to-end guarantees for the convergence of our algorithm. Empirically, we validate the effectiveness of our scalable representation-based approach on two benchmark problems, and demonstrate the advantages of our approach over generic function approximation approaches to representing the local -functions.
Cite
@article{arxiv.2410.17221,
title = {Scalable spectral representations for multi-agent reinforcement learning in network MDPs},
author = {Zhaolin Ren and Runyu Zhang and Bo Dai and Na Li},
journal= {arXiv preprint arXiv:2410.17221},
year = {2024}
}
Comments
Updated title, corrected an issue with an author's name