A biomimetic approach to inverse kinematics for a redundant robot arm

Author(s)

Artemiadis, Panagiotis; Katsiaris, Pantelis T.; Kyriakopoulos, Kostas J.

Abstract

Redundant robots have received increased attention during the last decades, since they provide solutions to problems investigated for years in the robotic community, e.g. task-space tracking, obstacle avoidance etc. However, robot redundancy may arise problems of kinematic control, since robot joint motion is not uniquely determined. In this paper, a biomimetic approach is proposed for solving the problem of redundancy resolution. First, the kinematics of the human upper limb while performing random arm motion are investigated and modeled. The dependencies among the human joint angles are described using a Bayesian network. Then, an objective function, built using this model, is used in a closed-loop inverse kinematic algorithm for a redundant robot arm. Using this algorithm, the robot arm end-effector can be positioned in the three dimensional (3D) space using human-like joint configurations. Through real experiments using an anthropomorphic robot arm, it is proved that the proposed algorithm is computationally fast, while it results to human-like configurations compared to previously proposed inverse kinematics algorithms. The latter makes the proposed algorithm a strong candidate for applications where anthropomorphism is required, e.g. in humanoids or generally in cases where robotic arms interact with humans.

Date issued

2010-06

URI

http://hdl.handle.net/1721.1/65149

Department

Massachusetts Institute of Technology. Department of Mechanical Engineering

Journal

Autonomous Robots

Publisher

Springer Science + Business Media B.V.

Citation

Artemiadis, Panagiotis K., Pantelis T. Katsiaris, and Kostas J. Kyriakopoulos. “A Biomimetic Approach to Inverse Kinematics for a Redundant Robot Arm.” Autonomous Robots 29.3-4 (2010) : 293-308.

Version: Author's final manuscript

ISSN

0929-5593

1573-7527