Research Area: Machine Learning
Ensemble reinforcement learning, which combines the decisions of a set of base agents, is proposed to enhance the decision making process and speed up training time. Many studies indicate that an ensemble model may achieve better results than a single agent because of the complement of base agents, in which the error of an agent may be corrected by others. However, the fusion method is a fundamental issue in ensemble. Currently, existing studies mainly focus on static fusion which either assumes all agents have the same ability or ignores the ones with poor average performance. This assumption causes current static fusion methods to overlook base agents with poor overall performance, but excellent results in select scenarios, which results in the ability of some agents not being fully utilized. This study aims to propose a dynamic fusion method which utilizes each base agent according to its local competence on test states. The performance of a base agent on the validation set is measured in terms of the rewards achieved by the agent in next n steps. The similarity between a validation state and a new state is quantified by Euclidian distance in the latent space and the weights of each base agent are updated according to its performance on validation states and their similarity to a new state. The experimental studies confirm that the proposed dynamic fusion method outperforms its base agents and also the static fusion methods. This is the first dynamic fusion method proposed for deep reinforcement learning, which extends the study on dynamic fusion from classification to reinforcement learning.
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Author(s) Name: Patrick P. K. Chan, Meng Xiao, Xinran Qin & Natasha Kees
Journal name: International Journal of Machine Learning and Cybernetics
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Publisher name: Springer
DOI: 10.1007/s13042-020-01218-z
Volume Information: volume 12, pages 1031–1040 (2021)
