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Knowledge Transfer in Multi-Task Deep Reinforcement Learning for Continuous Control

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arxiv 2010.07494 v2 pith:IPY3B3PS submitted 2020-10-15 cs.LG cs.AI

Knowledge Transfer in Multi-Task Deep Reinforcement Learning for Continuous Control

classification cs.LG cs.AI
keywords learningcontrolcontinuousknowledgetransferagentdeepktm-drl
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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While Deep Reinforcement Learning (DRL) has emerged as a promising approach to many complex tasks, it remains challenging to train a single DRL agent that is capable of undertaking multiple different continuous control tasks. In this paper, we present a Knowledge Transfer based Multi-task Deep Reinforcement Learning framework (KTM-DRL) for continuous control, which enables a single DRL agent to achieve expert-level performance in multiple different tasks by learning from task-specific teachers. In KTM-DRL, the multi-task agent first leverages an offline knowledge transfer algorithm designed particularly for the actor-critic architecture to quickly learn a control policy from the experience of task-specific teachers, and then it employs an online learning algorithm to further improve itself by learning from new online transition samples under the guidance of those teachers. We perform a comprehensive empirical study with two commonly-used benchmarks in the MuJoCo continuous control task suite. The experimental results well justify the effectiveness of KTM-DRL and its knowledge transfer and online learning algorithms, as well as its superiority over the state-of-the-art by a large margin.

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