English

Reinforcement Learning with General Value Function Approximation: Provably Efficient Approach via Bounded Eluder Dimension

Machine Learning 2020-06-22 v3 Optimization and Control Machine Learning

Abstract

Value function approximation has demonstrated phenomenal empirical success in reinforcement learning (RL). Nevertheless, despite a handful of recent progress on developing theory for RL with linear function approximation, the understanding of general function approximation schemes largely remains missing. In this paper, we establish a provably efficient RL algorithm with general value function approximation. We show that if the value functions admit an approximation with a function class F\mathcal{F}, our algorithm achieves a regret bound of O~(poly(dH)T)\widetilde{O}(\mathrm{poly}(dH)\sqrt{T}) where dd is a complexity measure of F\mathcal{F} that depends on the eluder dimension [Russo and Van Roy, 2013] and log-covering numbers, HH is the planning horizon, and TT is the number interactions with the environment. Our theory generalizes recent progress on RL with linear value function approximation and does not make explicit assumptions on the model of the environment. Moreover, our algorithm is model-free and provides a framework to justify the effectiveness of algorithms used in practice.

Keywords

Cite

@article{arxiv.2005.10804,
  title  = {Reinforcement Learning with General Value Function Approximation: Provably Efficient Approach via Bounded Eluder Dimension},
  author = {Ruosong Wang and Ruslan Salakhutdinov and Lin F. Yang},
  journal= {arXiv preprint arXiv:2005.10804},
  year   = {2020}
}
R2 v1 2026-06-23T15:43:25.120Z