An Optimal Traction Control Scheme for Off-Road Operation of Robotic Vehicles

Author

Waldron, Kenneth J. ; Abdallah, Muhammad E.

Author_Institution

Robotic Locomotion Lab., Stanford Univ., CA

Volume

12

Issue

2

fYear

2007

fDate

4/1/2007 12:00:00 AM

Firstpage

126

Lastpage

133

Abstract

Active degrees of freedom provide a robotic vehicle the ability to enhance its performance in all terrain conditions. While active suspension systems are now commonplace in on-road vehicles, their application to off-road terrains has been little investigated. A fundamental component of such an application is a need to translate desired body motion commands into actuator values through the use of proprioceptive algorithms. The diverse nature of the terrains that might be encountered places variable demands upon the operation of the vehicle. This entails the potential use of a diverse set of algorithms designed to optimize mobility and performance. This paper presents a cohesive control scheme designed for the operation of an autonomous vehicle under all conditions. The ideas presented have been tested in simulation, and some have been used extensively in the field

Keywords

mobile robots; optimal control; suspensions (mechanical components); traction; active suspension systems; autonomous vehicle; body motion commands; cohesive control scheme; on-road vehicles; optimal traction control; proprioceptive algorithms; robotic vehicles; Actuators; Algorithm design and analysis; Design optimization; Force control; Mobile robots; Navigation; Optimal control; Remotely operated vehicles; Vehicle driving; Wheels; Active suspension; force allocation; proprioceptive control; robotic vehicle; traction control;

fLanguage

English

Journal_Title

Mechatronics, IEEE/ASME Transactions on

Publisher

ieee

ISSN

1083-4435

Type

jour

DOI

10.1109/TMECH.2007.892819

Filename

4154713