Adaptive Discretization for Episodic Reinforcement Learning in Metric Spaces

Abstracts of the 2020 SIGMETRICS/Performance Joint International Conference on Measurement and Modeling of Computer Systems Pub Date : 2020-06-08 DOI:10.1145/3393691.3394176

Sean R. Sinclair, Siddhartha Banerjee, C. Yu

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Abstract

We present an efficient algorithm for model-free episodic reinforcement learning on large (potentially continuous) state-action spaces. Our algorithm is based on a novel Q-learning policy with adaptive data-driven discretization. The central idea is to maintain a finer partition of the state-action space in regions which are frequently visited in historical trajectories, and have higher payoff estimates. We demonstrate how our adaptive partitions take advantage of the shape of the optimal Q-function and the joint space, without sacrificing the worst-case performance. In particular, we recover the regret guarantees of prior algorithms for continuous state-action spaces, which additionally require either an optimal discretization as input, and/or access to a simulation oracle. Moreover, experiments demonstrate how our algorithm automatically adapts to the underlying structure of the problem, resulting in much better performance compared both to heuristics and Q-learning with uniform discretization.

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度量空间中情景强化学习的自适应离散化

我们提出了一种在大型(可能连续的)状态-动作空间上进行无模型情景强化学习的有效算法。我们的算法基于一种新颖的q学习策略，具有自适应数据驱动离散化。其核心思想是在历史轨迹中经常访问的区域中保持更精细的状态-行动空间划分，并且具有更高的收益估计。我们演示了我们的自适应分区如何利用最优q函数的形状和关节空间，而不牺牲最坏情况的性能。特别是，我们恢复了连续状态-动作空间的先前算法的遗憾保证，这额外需要最优离散化作为输入，和/或访问模拟oracle。此外，实验证明了我们的算法如何自动适应问题的底层结构，与启发式和均匀离散化的q学习相比，产生了更好的性能。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Abstracts of the 2020 SIGMETRICS/Performance Joint International Conference on Measurement and Modeling of Computer Systems

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