Gain-scheduled H Controller Synthesis for Actively-steered Longer and Heavier Commercial Vehicles
Journal article, 2020

This paper proposes a gain-scheduled controller synthesis for improving the lateral performance and stability of articulated heavy vehicles by active steering of the selected towed vehicle units. The longitudinal velocity is on-line measurable, and it is thus treated as a scheduling parameter in the gain-scheduled controller synthesis. The lateral performance of four articulated heavy vehicles, including existing Nordic heavy vehicles and prospective longer articulated heavy vehicles, are investigated with and without active steering and compared with a commonly used conventional tractor–semitrailer. The control problem is formulated as an ℋ∞H∞ static output feedback, which uses only information from articulation angles between the steered vehicle unit and the vehicle unit in front of it. The solution of the problem is obtained within the linear matrix inequality framework, while guaranteeing ℋ∞H∞ performance objectives. Effectiveness of the designed controller is verified through numerical simulations performed on high-fidelity vehicle models. The results confirm a significant reduction in yaw rate rearward amplification, lateral acceleration rearward amplification, and high-speed transient off-tracking, thereby improving the lateral stability and performance of all studied heavy vehicles at high speeds.

active steering

longer and heavier commercials vehicles

ℋ∞ static output feedback

Gain-scheduled controller

rearward amplification

Author

Maliheh Sadeghi Kati

Chalmers, Electrical Engineering, Systems and control

Jonas Fredriksson

Chalmers, Electrical Engineering, Systems and control

Bengt J H Jacobson

Chalmers, Mechanics and Maritime Sciences (M2), Vehicle Engineering and Autonomous Systems

Leo Laine

Chalmers, Mechanics and Maritime Sciences (M2)

Volvo Group

Proceedings of the Institution of Mechanical Engineers, Part D: Journal of Automobile Engineering

0954-4070 (ISSN) 2041-2991 (eISSN)

Vol. 234 7 2045-2065

Subject Categories

Tribology

Energy Engineering

Vehicle Engineering

DOI

10.1177/0954407019870352

More information

Latest update

9/15/2020