Control Design of Variable-Geometry Suspension Considering the Construction System

Author

Nemeth, Balazs ; Gaspar, Peter

Author_Institution

Syst. & Control Lab., Inst. for Comput. Sci. & Control, Budapest, Hungary

Volume

62

Issue

8

fYear

2013

fDate

Oct. 2013

Firstpage

4104

Lastpage

4109

Abstract

This paper proposes a method in which the construction of a variable-geometry suspension and the design of a robust suspension control are simultaneously performed to enhance vehicle stability. The control system guarantees various crucial performances that are related to the chassis roll angle and half-track change. Moreover, by changing the camber angles of the front wheels, the yaw rate of the vehicle is modified, which can be used to reduce the tracking error from the reference yaw rate. The design of a suspension control system is based on robust linear parameter varying (LPV) methods, which meet performance specifications and guarantee robustness against model uncertainties. Since there is an interaction between the construction design and the control design, a balance must be achieved between them.

Keywords

control system synthesis; linear systems; robust control; suspensions (mechanical components); variable structure systems; vehicles; wheels; LPV methods; camber angles; chassis roll angle; control design; half-track change; reference yaw rate; robust linear parameter varying methods; robust suspension control; tracking error reduction; variable geometry suspension; vehicle stability; Control design; Suspensions; Tires; Vehicle dynamics; Vehicles; Wheels; Linear parameter varying (LPV) modeling and control; variable-geometry suspension systems; vehicle dynamics;

fLanguage

English

Journal_Title

Vehicular Technology, IEEE Transactions on

Publisher

ieee

ISSN

0018-9545

Type

jour

DOI

10.1109/TVT.2013.2263156

Filename

6516590