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引用次数: 0
摘要
具有线性函数近似的 Greedy-GQ 算法最初是由 Maei 等人提出的(Proceedings of international conference of machine learning (ICML, 2010)):国际机器学习会议(ICML)论文集,2010 年)中提出的,是一种基于值的非策略算法,用于强化学习中的最优控制,它具有非线性双时标结构和非凸目标函数。本文开发了其最严格的有限时间误差边界。我们证明,在 i.i.d. 设定下,Greedy-GQ 算法的收敛速度可达 \(\mathcal {O}({1}/{\sqrt{T}})\) ;在马尔可夫设定下,收敛速度可达 \(\mathcal {O}({\log T}/{\sqrt{T}})\) 。我们使用嵌套循环方法进一步设计了vanilla Greedy-GQ算法的变体,并证明其采样复杂度为(\mathcal {O}({\log (1/\epsilon )\epsilon ^{-2}})),与vanilla Greedy-GQ算法的采样复杂度相匹配。我们的有限时间误差边界与随机梯度下降算法的有限时间误差边界相匹配,该算法适用于一般平滑非凸优化问题,尽管它在两个时间尺度的更新中面临额外的挑战。我们的有限样本分析为在实践中选择更快收敛的步长提供了理论指导,并提出了收敛速度与所获策略质量之间的权衡。我们的技术为基于值的非凸双时间尺度强化学习算法的有限样本分析提供了一种通用方法。
Greedy-GQ with linear function approximation, originally proposed in Maei et al. (in: Proceedings of the international conference on machine learning (ICML), 2010), is a value-based off-policy algorithm for optimal control in reinforcement learning, and it has a non-linear two timescale structure with non-convex objective function. This paper develops its tightest finite-time error bounds. We show that the Greedy-GQ algorithm converges as fast as \(\mathcal {O}({1}/{\sqrt{T}})\) under the i.i.d. setting and \(\mathcal {O}({\log T}/{\sqrt{T}})\) under the Markovian setting. We further design variant of the vanilla Greedy-GQ algorithm using the nested-loop approach, and show that its sample complexity is \(\mathcal {O}({\log (1/\epsilon )\epsilon ^{-2}})\), which matches with the one of the vanilla Greedy-GQ. Our finite-time error bounds match with the one of the stochastic gradient descent algorithm for general smooth non-convex optimization problems, despite of its additonal challenge in the two time-scale updates. Our finite-sample analysis provides theoretical guidance on choosing step-sizes for faster convergence in practice, and suggests the trade-off between the convergence rate and the quality of the obtained policy. Our techniques provide a general approach for finite-sample analysis of non-convex two timescale value-based reinforcement learning algorithms.
期刊介绍:
Machine Learning serves as a global platform dedicated to computational approaches in learning. The journal reports substantial findings on diverse learning methods applied to various problems, offering support through empirical studies, theoretical analysis, or connections to psychological phenomena. It demonstrates the application of learning methods to solve significant problems and aims to enhance the conduct of machine learning research with a focus on verifiable and replicable evidence in published papers.
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