论文信息 - Robust prevention of limit cycles for robustly decoupled car steering dynamics

Robust prevention of limit cycles for robustly decoupled car steering dynamics

Considerable safety benefits are achieved by robustly decoupling the lateral and yaw motions of a car with active steering. Robust unilateral decoupling requires an actuator to generate an additional front wheel steering angle. However, introducing actuators to closed loop systems may cause limit cycles due to actuator saturation and rate limits. Such limit cycles are intolerable w.r.t. safety and comfort. By introducing a simple nonlinear modification of the control law, this paper proposes a remedy to significantly reduce the susceptibility to limit cycles for robustly decoupled car steering dynamics. The robustness of the resulting system w.r.t. the avoidance of limit cycles is investigated for varying operating conditions by combining the parameter space approach and the theory of describing functions.

Jürgen Ackermann | Tilman Bünte

[1] Tilman Bünte,et al. Design and Analysis of Robust Control Systems in PARADISE , 1997 .

[2] Manfred Mitschke,et al. Dynamik der Kraftfahrzeuge , 1972 .

[3] Arthur Gelb,et al. Multiple-Input Describing Functions and Nonlinear System Design , 1968 .

[4] P. Riekert,et al. Zur Fahrmechanik des gummibereiften Kraftfahrzeugs , 1940 .

[5] J. Ackermann,et al. Design and Analysis of Robust Control Systems , 1996 .

[6] Jürgen Ackermann,et al. Driving Safety by Robust Steering Control , 1996 .

[7] Jürgen Ackermann,et al. Automatic car steering control bridges over the driver reaction time , 1997, Kybernetika.

[8] Andrew Bartlett,et al. Robust Control: Systems with Uncertain Physical Parameters , 1993 .

[9] Holger Duda. Effects of Rate Limiting Elements in Flight Control Systems - A New PIO-Criterion. , 1995 .