English

Infinite-Horizon Reinforcement Learning with Multinomial Logistic Function Approximation

Machine Learning 2024-10-15 v3 Optimization and Control

Abstract

We study model-based reinforcement learning with non-linear function approximation where the transition function of the underlying Markov decision process (MDP) is given by a multinomial logistic (MNL) model. We develop a provably efficient discounted value iteration-based algorithm that works for both infinite-horizon average-reward and discounted-reward settings. For average-reward communicating MDPs, the algorithm guarantees a regret upper bound of O~(dDT)\tilde{\mathcal{O}}(dD\sqrt{T}) where dd is the dimension of feature mapping, DD is the diameter of the underlying MDP, and TT is the horizon. For discounted-reward MDPs, our algorithm achieves O~(d(1γ)2T)\tilde{\mathcal{O}}(d(1-\gamma)^{-2}\sqrt{T}) regret where γ\gamma is the discount factor. Then we complement these upper bounds by providing several regret lower bounds. We prove a lower bound of Ω(dDT)\Omega(d\sqrt{DT}) for learning communicating MDPs of diameter DD and a lower bound of Ω(d(1γ)3/2T)\Omega(d(1-\gamma)^{3/2}\sqrt{T}) for learning discounted-reward MDPs with discount factor γ\gamma. Lastly, we show a regret lower bound of Ω(dH3/2K)\Omega(dH^{3/2}\sqrt{K}) for learning HH-horizon episodic MDPs with MNL function approximation where KK is the number of episodes, which improves upon the best-known lower bound for the finite-horizon setting.

Keywords

Cite

@article{arxiv.2406.13633,
  title  = {Infinite-Horizon Reinforcement Learning with Multinomial Logistic Function Approximation},
  author = {Jaehyun Park and Junyeop Kwon and Dabeen Lee},
  journal= {arXiv preprint arXiv:2406.13633},
  year   = {2024}
}
R2 v1 2026-06-28T17:12:21.152Z