Averaging approach to nonholonomic motion planning

Author

Gurvits, Leonid

Author_Institution

Robotics Res. Lab., Courant Inst. of Math. Sci., New York, NY, USA

fYear

1992

fDate

12-14 May 1992

Firstpage

2541

Abstract

The author considers the problem of motion planning for a nonholonomic system with drift. Open-loop and feedback solutions for nonholonomic motion planning (NMP) are constructed by using the averaging technique that is well known in applied mathematics. An algorithm for open-loop and feedback solutions of NMP is introduced. The main step in the algorithm is the case of first order Lie brackets. This case, as is shown, is equivalent to NMP for Brockett´s system considered over functional commutative algebra. Feedback solutions are constructed in the same manner. From a robotics point of view, it is shown that NMP can be reduced to the holonomic problem. As linear algebra plays a crucial role in linear control theory, polylinear algebra is crucial for NMP. The rolling disk example is used to illustrate the feedback algorithm

Keywords

feedback; linear algebra; path planning; robots; averaging method; feedback; first order Lie brackets; nonholonomic motion planning; open-loop; polylinear algebra; robotics; rolling disk; Algebra; Control systems; Control theory; Feedback; Laboratories; Mathematics; Motion control; Motion planning; Open loop systems; Robots;

fLanguage

English

Publisher

ieee

Conference_Titel

Robotics and Automation, 1992. Proceedings., 1992 IEEE International Conference on

Conference_Location

Nice

Print_ISBN

0-8186-2720-4

Type

conf

DOI

10.1109/ROBOT.1992.220059

Filename

220059