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Exploration via Planning for Information about the Optimal Trajectory
Viraj Mehta · Ian Char · Joseph Abbate · Rory Conlin · Mark Boyer · Stefano Ermon · Jeff Schneider · Willie Neiswanger

Tue Nov 29 09:00 AM -- 11:00 AM (PST) @ Hall J #713

Many potential applications of reinforcement learning (RL) are stymied by the large numbers of samples required to learn an effective policy. This is especially true when applying RL to real-world control tasks, e.g. in the sciences or robotics, where executing a policy in the environment is costly. In popular RL algorithms, agents typically explore either by adding stochasticity to a reward-maximizing policy or by attempting to gather maximal information about environment dynamics without taking the given task into account. In this work, we develop a method that allows us to plan for exploration while taking both the task and the current knowledge about the dynamics into account. The key insight to our approach is to plan an action sequence that maximizes the expected information gain about the optimal trajectory for the task at hand. We demonstrate that our method learns strong policies with 2x fewer samples than strong exploration baselines and 200x fewer samples than model free methods on a diverse set of low-to-medium dimensional control tasks in both the open-loop and closed-loop control settings.

Author Information

Viraj Mehta (Carnegie Mellon University)
Ian Char (Carnegie Mellon University)
Joseph Abbate
Rory Conlin (Princeton University)
Mark Boyer (Princeton Plasma Physics Lab)
Stefano Ermon (Stanford)
Jeff Schneider (CMU)
Willie Neiswanger (Stanford University)

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