Gap-Dependent Bounds for Nearly Minimax Optimal Reinforcement Learning with Linear Function Approximation
Abstract
We study gap-dependent performance guarantees for nearly minimax-optimal algorithms in reinforcement learning with linear function approximation. While prior works have established gap-dependent regret bounds in this setting, existing analyses do not apply to algorithms that achieve the nearly minimax-optimal worst-case regret bound , where is the feature dimension, is the horizon length, and is the number of episodes. We bridge this gap by providing the first gap-dependent regret bound for the nearly minimax-optimal algorithm LSVI-UCB++ (He et al., 2023). Our analysis yields improved dependencies on both and compared to previous gap-dependent results. Moreover, leveraging the low policy-switching property of LSVI-UCB++, we introduce a concurrent variant that enables efficient parallel exploration across multiple agents and establish the first gap-dependent sample complexity upper bound for online multi-agent RL with linear function approximation, achieving linear speedup with respect to the number of agents.
Cite
@article{arxiv.2602.20297,
title = {Gap-Dependent Bounds for Nearly Minimax Optimal Reinforcement Learning with Linear Function Approximation},
author = {Haochen Zhang and Zhong Zheng and Lingzhou Xue},
journal= {arXiv preprint arXiv:2602.20297},
year = {2026}
}