Optimal Control for Geometric Motion Planning of a Robot Diver
Abstract
Inertial reorientation of airborne articulated bodies has been an active area of research in the robotics community, as this behavior can help guide dynamic robots to a safe landing with minimal damage. The main objective of this work is emulating the aggressive and large angle correction maneuvers, like somersaults, that are performed by human divers. To this end, a planar three link robot, called DiverBot, is proposed. By considering a gravity-free scenario, a local connection is obtained between joint angles and the body orientation, resulting in a reduction in the system dynamics. An optimal control policy applied on this reduced configuration space yielded diving maneuvers that are dynamically feasible. Numerical results show that the DiverBot can execute one somersault without drift and multiple somersaults with minimal drift.
BibTeX
@conference{Shu-2016-121401,author = {R. Shu and A. Siravuru and A. Rai and T. Dear and K. Sreenath and H. Choset},
title = {Optimal Control for Geometric Motion Planning of a Robot Diver},
booktitle = {Proceedings of (IROS) IEEE/RSJ International Conference on Intelligent Robots and Systems},
year = {2016},
month = {October},
pages = {4780 - 4785},
}