DocumentCode
1096816
Title
Input–Output Decoupling Control by Measurement Feedback in Four-Wheel-Steering Vehicles
Author
Marino, Riccardo ; Cinili, Fabio
Author_Institution
Dipt. di Ing. Elettron., Univ. degli Studi di Roma Tor Vergata, Rome, Italy
Volume
17
Issue
5
fYear
2009
Firstpage
1163
Lastpage
1172
Abstract
The well-known single-track linearized model for four-wheel-steering vehicle dynamics is used to design a second-order dynamic decoupling controller. Yaw rate and lateral speed are the outputs to be decoupled, while the rear steering angle and an additive steering angle with respect to the driver command are the control inputs. It is shown that the lateral speed dynamics and the yaw rate dynamics can be decoupled by feeding back longitudinal speed, yaw rate, and lateral acceleration measurements, while the effect of sensor disturbances on yaw rate is attenuated. Lateral speed measurements or observers are not required. The yaw rate controlled dynamics are independent from lateral speed and are described by a third-order input-output model, depending on the driver steering wheel command and sensor disturbances; the lateral speed dynamics are autonomous and tend exponentially to zero with a vehicle-dependent time constant while the lateral acceleration tends to be proportional to the yaw rate. The nonlinear analysis on a single-track model shows the suppression of the unstable equilibrium points of the uncontrolled system, the generation of new stable equilibrium points as the critical driver step input increases, and the enlargement of the stability regions. Simulations of typical maneuvers and disturbances on a nonlinear third-order single-track model and on a higher order model provided by CarSim show robustness with respect to unmodeled dynamics, vehicle parameter uncertainty, and sensor disturbances; moreover, significant dynamic decoupling, larger bandwidth, overshoot suppression, and improved maneuverability even at high speed are confirmed.
Keywords
acceleration control; acceleration measurement; automobiles; control system analysis; control system synthesis; feedback; input-output stability; linear systems; nonlinear control systems; nonlinear dynamical systems; steering systems; uncertain systems; vehicle dynamics; velocity control; velocity measurement; CarSim; driver steering wheel command; four-wheel-steering road vehicle dynamics; higher order model; lateral acceleration measurement; lateral speed dynamics; lateral speed measurement; measurement feedback; nonlinear analysis; nonlinear third-order single-track input-output model; observer; overshoot suppression; second-order dynamic input-output decoupling controller design; sensor disturbance; single-track linearized model; stability region; unstable equilibrium point suppression; vehicle maneuverability; vehicle parameter uncertainty; yaw rate dynamics; Active steering; decoupling control; four-wheel-steering; vehicle dynamics;
fLanguage
English
Journal_Title
Control Systems Technology, IEEE Transactions on
Publisher
ieee
ISSN
1063-6536
Type
jour
DOI
10.1109/TCST.2008.2004441
Filename
5109470
Link To Document