Abstract

Policy search methods can allow robots to learn control policies for a wide range of tasks, but practical applications of policy search often require hand-engineered components for perception, state estimation, and low-level control. In this paper, we aim to answer the following question: does training the perception and control systems jointly end-to-end provide better performance than training each component separately? To this end, we develop a method that can be used to learn policies that map raw image observations directly to torques at the robot's motors. The policies are represented by deep convolutional neural networks (CNNs) with 92,000 parameters, and are trained using a guided policy search method, which transforms policy search into supervised learning, with supervision provided by a simple trajectory-centric reinforcement learning method. We evaluate our method on a range of real-world manipulation tasks that require close coordination between vision and control, such as screwing a cap onto a bottle, and present simulated comparisons to a range of prior policy search methods.

Keywords

Computer scienceConvolutional neural networkArtificial intelligenceReinforcement learningEnd-to-end principleTrajectoryRobotPerceptionDeep learningRange (aeronautics)Control (management)Machine learningTraining (meteorology)Engineering

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Publication Info

Year
2016
Type
article
Volume
17
Issue
1
Pages
1334-1373
Citations
1708
Access
Closed

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Sergey Levine, Chelsea Finn, Trevor Darrell et al. (2016). End-to-end training of deep visuomotor policies. Journal of Machine Learning Research , 17 (1) , 1334-1373.