Is Plug-in Solver Sample-Efficient for Feature-based Reinforcement Learning?
Abstract
It is believed that a model-based approach for reinforcement learning (RL) is the key to reduce sample complexity. However, the understanding of the sample optimality of model-based RL is still largely missing, even for the linear case. This work considers sample complexity of finding an -optimal policy in a Markov decision process (MDP) that admits a linear additive feature representation, given only access to a generative model. We solve this problem via a plug-in solver approach, which builds an empirical model and plans in this empirical model via an arbitrary plug-in solver. We prove that under the anchor-state assumption, which implies implicit non-negativity in the feature space, the minimax sample complexity of finding an -optimal policy in a -discounted MDP is , which only depends on the dimensionality of the feature space and has no dependence on the state or action space. We further extend our results to a relaxed setting where anchor-states may not exist and show that a plug-in approach can be sample efficient as well, providing a flexible approach to design model-based algorithms for RL.
Cite
@article{arxiv.2010.05673,
title = {Is Plug-in Solver Sample-Efficient for Feature-based Reinforcement Learning?},
author = {Qiwen Cui and Lin F. Yang},
journal= {arXiv preprint arXiv:2010.05673},
year = {2020}
}
Comments
30 pages, to appear in NeurIPS2020