English

The Sample Complexity of Online Reinforcement Learning: A Multi-model Perspective

Machine Learning 2026-03-02 v3 Systems and Control Systems and Control Optimization and Control Machine Learning

Abstract

We study the sample complexity of online reinforcement learning in the general \hzyrev{non-episodic} setting of nonlinear dynamical systems with continuous state and action spaces. Our analysis accommodates a large class of dynamical systems ranging from a finite set of nonlinear candidate models to models with bounded and Lipschitz continuous dynamics, to systems that are parametrized by a compact and real-valued set of parameters. In the most general setting, our algorithm achieves a policy regret of O(Nϵ2+duln(m(ϵ))/ϵ2)\mathcal{O}(N \epsilon^2 + d_\mathrm{u}\mathrm{ln}(m(\epsilon))/\epsilon^2), where NN is the time horizon, ϵ\epsilon is a user-specified discretization width, dud_\mathrm{u} the input dimension, and m(ϵ)m(\epsilon) measures the complexity of the function class under consideration via its packing number. In the special case where the dynamics are parametrized by a compact and real-valued set of parameters (such as neural networks, transformers, etc.), we prove a policy regret of O(duNp)\mathcal{O}(\sqrt{d_\mathrm{u}N p}), where pp denotes the number of parameters, recovering earlier sample-complexity results that were derived for linear time-invariant dynamical systems. While this article focuses on characterizing sample complexity, the proposed algorithms are likely to be useful in practice, due to their simplicity, their ability to incorporate prior knowledge, and their benign transient behaviors.

Keywords

Cite

@article{arxiv.2501.15910,
  title  = {The Sample Complexity of Online Reinforcement Learning: A Multi-model Perspective},
  author = {Michael Muehlebach and Zhiyu He and Michael I. Jordan},
  journal= {arXiv preprint arXiv:2501.15910},
  year   = {2026}
}

Comments

accepted at ICLR 2026; 37 pages, 6 figures

R2 v1 2026-06-28T21:19:14.888Z