Monte-Carlo Planning: Theoretically Fast Convergence Meets Practical Efficiency
Abstract
Popular Monte-Carlo tree search (MCTS) algorithms for online planning, such as e-greedy tree search and UCT, aim at rapidly identifying a reasonably good action, but provide rather poor worst-case guarantees on performance improvement over time. In contrast, a recently introduced MCTS algorithm BRUE guarantees exponential-rate improvement over time, yet it is not geared towards identifying reasonably good choices right at the go. We take a stand on the individual strengths of these two classes of algorithms, and show how they can be effectively connected. We then rationalize a principle of "selective tree expansion", and suggest a concrete implementation of this principle within MCTS. The resulting algorithms favorably compete with other MCTS algorithms under short planning times, while preserving the attractive convergence properties of BRUE.
Cite
Text
Feldman and Domshlak. "Monte-Carlo Planning: Theoretically Fast Convergence Meets Practical Efficiency." Conference on Uncertainty in Artificial Intelligence, 2013.Markdown
[Feldman and Domshlak. "Monte-Carlo Planning: Theoretically Fast Convergence Meets Practical Efficiency." Conference on Uncertainty in Artificial Intelligence, 2013.](https://mlanthology.org/uai/2013/feldman2013uai-monte/)BibTeX
@inproceedings{feldman2013uai-monte,
title = {{Monte-Carlo Planning: Theoretically Fast Convergence Meets Practical Efficiency}},
author = {Feldman, Zohar and Domshlak, Carmel},
booktitle = {Conference on Uncertainty in Artificial Intelligence},
year = {2013},
url = {https://mlanthology.org/uai/2013/feldman2013uai-monte/}
}