ICRA 2011 Paper Abstract

Close

Paper ThP105.1

Reimann, Hendrik (Ruhr-University Bochum), Iossifidis, Ioannis (Ruhr West University of Applied Science), Schöner, Gregor (Ruhr University Bochum)

Autonomous Movement Generation for Manipulators with Multiple Simultaneous Constraints Using the Attractor Dynamics Approach

Scheduled for presentation during the Regular Sessions "Manipulation Planning III" (ThP105), Thursday, May 12, 2011, 13:40−13:55, Room 3G

2011 IEEE International Conference on Robotics and Automation, May 9-13, 2011, Shanghai International Conference Center, Shanghai, China

This information is tentative and subject to change. Compiled on May 23, 2019

Keywords Manipulation Planning, Behaviour-Based Systems, Autonomous Agents

Abstract

The movement of autonomous agents in natural environments is restricted by potentially large numbers of constraints. To generate behavior that fulfills all given constraints simultaneously, the attractor dynamics approach to movement generation represents each constraint by a dynamical system with attractors or repellors at desired or undesired values of a relevant variable. These dynamical systems are transformed into vector fields over the control variables of a robotic agent that force the state of the whole system in directions beneficial to the satisfaction of the behavioral constraint. The attractor dynamics approach was recently successfully applied to the generation of manipulator motion trajectories avoiding collision with obstacles cite{ReimannIossifidisSchoner2010a} and constraints on gripper orientation during reaching and grasping movements cite{ReimannIossifidisSchoner2010b}. Continuing that body of work, this paper proposes a system which generates movements satisfying both obstacle avoidance and gripper orientation constraints simultaneously. As an extension, the additional constraint of avoiding hardware limits for joint angles is included. Properties of the resulting system are demonstrated by a systematic study generating movements with a large number of constraints in different scene setups. Specific characteristics are highlighted by several showcase example movements.

 

 

Technical Content © IEEE Robotics & Automation Society

This site is protected by copyright and trademark laws under US and International law.
All rights reserved. © 2002-2019 PaperCept, Inc.
Page generated 2019-05-23  00:15:56 PST  Terms of use