Christian Beck, Arnulf Jentzen, Konrad Kleinberg, Thomas Kruse
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引用次数: 0
Abstract
Discrete time stochastic optimal control problems and Markov decision processes (MDPs), respectively, serve as fundamental models for problems that involve sequential decision making under uncertainty and as such constitute the theoretical foundation of reinforcement learning. In this article we study the numerical approximation of MDPs with infinite time horizon, finite control set, and general state spaces. Our set-up in particular covers infinite-horizon optimal stopping problems of discrete time Markov processes. A key tool to solve MDPs are Bellman equations which characterize the value functions of the MDPs and determine the optimal control strategies. By combining ideas from the full-history recursive multilevel Picard approximation method, which was recently introduced to solve certain nonlinear partial differential equations, and ideas from Q-learning we introduce a class of suitable nonlinear Monte Carlo methods and prove that the proposed methods do not suffer from the curse of dimensionality in the numerical approximation of the solutions of Bellman equations and the associated discrete time stochastic optimal control problems.
离散时间随机最优控制问题(Discrete time stochastic optimal control problem)和马尔可夫决策过程(Markov decision processes, mdp)分别是不确定条件下序列决策问题的基本模型,也是强化学习的理论基础。本文研究了具有无限时间范围、有限控制集和一般状态空间的mdp的数值逼近问题。我们的设置特别涵盖了离散时间马尔可夫过程的无限视界最优停止问题。求解mdp的关键工具是Bellman方程,它描述了mdp的值函数并确定了最优控制策略。结合最近被引入求解某些非线性偏微分方程的全历史递归多阶皮卡德近似方法的思想和q -学习的思想,我们引入了一类合适的非线性蒙特卡罗方法,并证明了所提出的方法在Bellman方程解的数值近似和相关的离散时间随机最优控制问题中不受维数的困扰。
期刊介绍:
The Applied Mathematics and Optimization Journal covers a broad range of mathematical methods in particular those that bridge with optimization and have some connection with applications. Core topics include calculus of variations, partial differential equations, stochastic control, optimization of deterministic or stochastic systems in discrete or continuous time, homogenization, control theory, mean field games, dynamic games and optimal transport. Algorithmic, data analytic, machine learning and numerical methods which support the modeling and analysis of optimization problems are encouraged. Of great interest are papers which show some novel idea in either the theory or model which include some connection with potential applications in science and engineering.
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