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Bellman Unbiasedness: Toward Provably Efficient Distributional Reinforcement Learning with General Value Function Approximation

Machine Learning 2025-05-14 v3 Artificial Intelligence Machine Learning

Abstract

Distributional reinforcement learning improves performance by capturing environmental stochasticity, but a comprehensive theoretical understanding of its effectiveness remains elusive. In addition, the intractable element of the infinite dimensionality of distributions has been overlooked. In this paper, we present a regret analysis of distributional reinforcement learning with general value function approximation in a finite episodic Markov decision process setting. We first introduce a key notion of Bellman unbiasedness\textit{Bellman unbiasedness} which is essential for exactly learnable and provably efficient distributional updates in an online manner. Among all types of statistical functionals for representing infinite-dimensional return distributions, our theoretical results demonstrate that only moment functionals can exactly capture the statistical information. Secondly, we propose a provably efficient algorithm, SF-LSVI\texttt{SF-LSVI}, that achieves a tight regret bound of O~(dEH32K)\tilde{O}(d_E H^{\frac{3}{2}}\sqrt{K}) where HH is the horizon, KK is the number of episodes, and dEd_E is the eluder dimension of a function class.

Keywords

Cite

@article{arxiv.2407.21260,
  title  = {Bellman Unbiasedness: Toward Provably Efficient Distributional Reinforcement Learning with General Value Function Approximation},
  author = {Taehyun Cho and Seungyub Han and Seokhun Ju and Dohyeong Kim and Kyungjae Lee and Jungwoo Lee},
  journal= {arXiv preprint arXiv:2407.21260},
  year   = {2025}
}
R2 v1 2026-06-28T17:58:49.436Z