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Grounded Action Transformation for Robot Learning in Simulation

Josiah P. Hanna, Peter Stone

Year
2017
Citations
79
Access
Open access

Abstract

Robot learning in simulation is a promising alternative to the prohibitive sample cost of learning in the physical world. Unfortunately, policies learned in simulation often perform worse than hand-coded policies when applied on the physical robot. Grounded simulation learning (GSL) promises to address this issue by altering the simulator to better match the real world. This paper proposes a new algorithm for GSL -- Grounded Action Transformation -- and applies it to learning of humanoid bipedal locomotion. Our approach results in a 43.27% improvement in forward walk velocity compared to a state-of-the art hand-coded walk. We further evaluate our methodology in controlled experiments using a second, higher-fidelity simulator in place of the real world. Our results contribute to a deeper understanding of grounded simulation learning and demonstrate its effectiveness for learning robot control policies.

Keywords

RobotFidelityComputer scienceAction (physics)Robot learningTransformation (genetics)Humanoid robotArtificial intelligenceGrounded theoryHuman–computer interaction

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