Trailer control through vehicle yaw moment control: Theoretical analysis and experimental assessment

This paper investigates a torque-vectoring formulation for the combined control of the yaw rate and hitch angle of an articulated vehicle through a direct yaw moment generated on the towing car. The formulation is based on a single-input single-output feedback control structure, in which the referen...

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Bibliographic Details
Published in:Mechatronics (Oxford) 2019-12, Vol.64, p.102282, Article 102282
Main Authors: Zanchetta, Mattia, Tavernini, Davide, Sorniotti, Aldo, Gruber, Patrick, Lenzo, Basilio, Ferrara, Antonella, Sannen, Koen, De Smet, Jasper, De Nijs, Wouter
Format: Article
Language:English
Subjects:
Articulated vehicle
Experimental tests
Hitch angle control
Performance comparison
Torque-vectoring
Yaw moment
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Summary:This paper investigates a torque-vectoring formulation for the combined control of the yaw rate and hitch angle of an articulated vehicle through a direct yaw moment generated on the towing car. The formulation is based on a single-input single-output feedback control structure, in which the reference yaw rate for the car is modified when the incipient instability of the trailer is detected with a hitch angle sensor. The design of the hitch angle controller is described, including the gain scheduling as a function of vehicle speed. The controller performance is assessed by means of frequency domain and phase plane analyses, and compared with that of an industrial trailer sway mitigation algorithm. In addition, the novel control strategy is implemented in a high-fidelity articulated vehicle model for robustness assessment, and experimentally tested on an electric vehicle demonstrator with four on-board drivetrains, towing two different conventional single-axle trailers. The results show that: (i) the torque-vectoring controller based only on the yaw rate of the car is not sufficient to mitigate trailer instability in extreme conditions; and (ii) the proposed controller provides safe trailer behaviour during the comprehensive set of manoeuvres, thus justifying the additional hardware complexity associated with the hitch angle measurement.
ISSN:0957-4158
1873-4006
DOI:10.1016/j.mechatronics.2019.102282