Experimental Validation of Contact Dynamics for In-Hand Manipulation

Author(s)

Kolbert, Roman; Chavan Dafle, Nikhil Narsingh; Rodriguez Garcia, Alberto

Abstract

This paper evaluates state-of-the-art contact models at predicting the motions and forces involved in simple in-hand robotic manipulations. In particular it focuses on three primitive actions—linear sliding, pivoting, and rolling—that involve contacts between a gripper, a rigid object, and their environment. The evaluation is done through thousands of controlled experiments designed to capture the motion of object and gripper, and all contact forces and torques at 250 Hz. We demonstrate that a contact modeling approach based on Coulomb’s friction law and maximum energy principle is effective at reasoning about interaction to first order, but limited for making accurate predictions. We attribute the major limitations to (1) the non-uniqueness of force resolution inherent to grasps with multiple hard contacts of complex geometries, (2) unmodeled dynamics due to contact compliance, and (3) unmodeled geometries due to manufacturing defects. Keywords: Contact Force, Contact Model, Grasp Object, Contact Compliance, Grip Force Increase

Date issued

2017-03

URI

http://hdl.handle.net/1721.1/119890

Department

Massachusetts Institute of Technology. Department of Mechanical Engineering

Journal

2016 International Symposium on Experimental Robotics

Publisher

Springer Nature America, Inc

Citation

Kolbert, Roman, Nikhil Chavan-Dafle, and Alberto Rodriguez. “Experimental Validation of Contact Dynamics for In-Hand Manipulation.” 2016 International Symposium on Experimental Robotics (2017): 633–645.

Version: Author's final manuscript

ISBN

978-3-319-50114-7

978-3-319-50115-4

ISSN

2511-1256

2511-1264