A path space approach to nonholonomic motion planning in the presence of obstacles

Author

Divelbiss, Adam W. ; Wen, John T.

Author_Institution

Reveo Corp., Hawthorne, NY, USA

Volume

13

Issue

3

fYear

1997

fDate

6/1/1997 12:00:00 AM

Firstpage

443

Lastpage

451

Abstract

This paper presents an algorithm for finding a kinematically feasible path for a nonholonomic system in the presence of obstacles. We first consider the path planning problem without obstacles by transforming it into a nonlinear least squares problem in an augmented space which is then iteratively solved. Obstacle avoidance is included as inequality constraints. Exterior penalty functions are used to convert the inequality constraints Into equality constraints. Then the same nonlinear least squares approach is applied. We demonstrate the efficacy of the approach by solving some challenging problems, including a tractor-trailer and a tractor with a steerable trailer backing in a loading dock. These examples demonstrate the performance of the algorithm in the presence of obstacles and steering and jackknife angle constraints

Keywords

least squares approximations; mobile robots; path planning; robot kinematics; equality constraints; exterior penalty functions; inequality constraints; jackknife angle constraints; kinematically feasible path; loading dock; nonholonomic motion planning; nonholonomic system; nonlinear least squares problem; obstacle avoidance; path space approach; steerable trailer; tractor-trailer; Control systems; Least squares methods; Manufacturing automation; Mobile robots; Motion planning; Orbital robotics; Path planning; Robotics and automation; Space technology; Vehicles;

fLanguage

English

Journal_Title

Robotics and Automation, IEEE Transactions on

Publisher

ieee

ISSN

1042-296X

Type

jour

DOI

10.1109/70.585905

Filename

585905