Active Extrinsic Contact Sensing: Application to General Peg-in-Hole Insertion

Author(s)

Kim, Sangwoon; Rodriguez, Alberto

Abstract

We propose a method that actively estimates contact location between a grasped rigid object and its environment and uses this as input to a peg-in-hole insertion policy. An estimation model and an active tactile feedback controller work collaboratively to estimate the external contacts accurately. The controller helps the estimation model get a better estimate by regulating a consistent contact mode. The better estimation makes it easier for the controller to regulate the contact. We then train an object-agnostic insertion policy that learns to use the series of contact estimates to guide the insertion of an unseen peg into a hole. In contrast with previous works that learn a policy directly from tactile signals, since this policy is in contact configuration space, it can be learned directly in simulation. Lastly, we demonstrate and evaluate the active extrinsic contact line estimation and the trained insertion policy together in a real experiment. We show that the proposed method inserts various-shaped test objects with higher success rates and fewer insertion attempts than previous work with end-to-end approaches. See supplementary video and results at https://sites.google.com/view/active-extrinsic-contact.

Description

2022 IEEE International Conference on Robotics and Automation (ICRA) May 23-27, 2022. Philadelphia, PA, USA

Date issued

2022-05-23

URI

https://hdl.handle.net/1721.1/155741

Department

Massachusetts Institute of Technology. Department of Mechanical Engineering

Publisher

IEEE|2022 International Conference on Robotics and Automation (ICRA)

Citation

Kim, Sangwoon and Rodriguez, Alberto. 2022. "Active Extrinsic Contact Sensing: Application to General Peg-in-Hole Insertion." 00.

Version: Author's final manuscript