SwingBot: Learning Physical Features from In-hand Tactile Exploration for Dynamic Swing-up Manipulation

Author(s)

Wang, Chen; Wang, Shaoxiong; Romero, Branden; Veiga, Filipe; Adelson, Edward

Abstract

© 2020 IEEE. Several robot manipulation tasks are extremely sensitive to variations of the physical properties of the manipulated objects. One such task is manipulating objects by using gravity or arm accelerations, increasing the importance of mass, center of mass, and friction information. We present SwingBot, a robot that is able to learn the physical features of an held object through tactile exploration. Two exploration actions (tilting and shaking) provide the tactile information used to create a physical feature embedding space. With this embedding, SwingBot is able to predict the swing angle achieved by a robot performing dynamic swing-up manipulations on a previously unseen object. Using these predictions, it is able to search for the optimal control parameters for a desired swing-up angle. We show that with the learned physical features our end-to-end self-supervised learning pipeline is able to substantially improve the accuracy of swinging up unseen objects. We also show that objects with similar dynamics are closer to each other on the embedding space and that the embedding can be disentangled into values of specific physical properties.

Date issued

2020

URI

https://hdl.handle.net/1721.1/138159

Department

Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory

Journal

IEEE International Conference on Intelligent Robots and Systems

Publisher

Institute of Electrical and Electronics Engineers (IEEE)

Citation

Wang, Chen, Wang, Shaoxiong, Romero, Branden, Veiga, Filipe and Adelson, Edward. 2020. "SwingBot: Learning Physical Features from In-hand Tactile Exploration for Dynamic Swing-up Manipulation." IEEE International Conference on Intelligent Robots and Systems.

Version: Author's final manuscript