Approximate Dynamic Programming Using Bellman Residual Elimination and Gaussian Process Regression
Author(s)
Bethke, Brett M.; How, Jonathan P.
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This paper presents an approximate policy iteration algorithm for solving infinite-horizon, discounted Markov decision processes (MDPs) for which a model of the system is available. The algorithm is similar in spirit to Bellman residual minimization methods. However, by using Gaussian process regression with nondegenerate kernel functions as the underlying cost-to-go function approximation architecture, the algorithm is able to explicitly construct cost-to-go solutions for which the Bellman residuals are identically zero at a set of chosen sample states. For this reason, we have named our approach Bellman residual elimination (BRE). Since the Bellman residuals are zero at the sample states, our BRE algorithm can be proven to reduce to exact policy iteration in the limit of sampling the entire state space. Furthermore, the algorithm can automatically optimize the choice of any free kernel parameters and provide error bounds on the resulting cost-to-go solution. Computational results on a classic reinforcement learning problem indicate that the algorithm yields a high-quality policy and cost approximation.
Date issued
2009-07Department
Massachusetts Institute of Technology. Department of Aeronautics and AstronauticsJournal
Proceedings of the 2009 conference on American Control Conference
Publisher
Institute of Electrical and Electronics Engineers
Citation
Bethke, B., and J.P. How. “Approximate dynamic programming using Bellman residual elimination and Gaussian process regression.” American Control Conference, 2009. ACC '09. 2009. 745-750. © Copyright 2010
Version: Final published version
Other identifiers
INSPEC Accession Number: 10775650
ISBN
978-1-4244-4523-3
ISSN
0743-1619