Task-priority motion planning of underactuated systems: An endogenous configuration space approach

Authors:
Adam Ratajczak;Joanna Karpińska;Krzysztof Tchoń
Affiliations:
Institute of computer engineering, control and robotics, wrocław university of technology, ul. janiszewskiego 11/17, 50–372 wrocław, poland. e-mails: joanna.karpinska@pwr.wroc.pl, ...;Institute of computer engineering, control and robotics, wrocław university of technology, ul. janiszewskiego 11/17, 50–372 wrocław, poland. e-mails: joanna.karpinska@pwr.wroc.pl, ...;Institute of computer engineering, control and robotics, wrocław university of technology, ul. janiszewskiego 11/17, 50–372 wrocław, poland. e-mails: joanna.karpinska@pwr.wroc.pl, ...
Venue:
Robotica
Year:
2010

Citing 3
Cited 1

Optimization by Vector Space Methods

Optimization by Vector Space Methods
Advanced Robotics: Redundancy and Optimization

Advanced Robotics: Redundancy and Optimization
Underwater Robots: Motion and Force Control of Vehicle-Manipulator Systems (Springer Tracts in Advanced Robotics)

Underwater Robots: Motion and Force Control of Vehicle-Manipulator Systems (Springer Tracts in Advanced Robotics)

Task-priority motion planning of underactuated systems: An endogenous configuration space approach – erratum

Robotica

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Abstract

This paper presents a task-priority motion planning algorithm for underactuated robotic systems. The motion planning algorithm combines two features: the idea of the task-priority control of redundant manipulators and the endogenous configuration space approach. This combination results in the algorithm which solves the primary motion planning task simultaneously with one or more secondary tasks ordered in accordance with decreasing priorities. The performance of the task-priority motion planning algorithm has been illustrated with computer simulations of the motion planning problem for a container ship.