Extended Dissipative Output-Feedback Controller for Autonomous Vehicle Path-Following With Steering Delays

Designing robust controllers that follow a desired trajectory against unexpected internal/external disturbances presents a major challenge in the field of autonomous driving technology. In general, robust controller designs ensuring the {H}_{\infty } performance are a popular solution. However, th...

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Bibliographic Details
Published in:IEEE transactions on intelligent transportation systems 2024-09, Vol.25 (9), p.11143-11155
Main Authors: Lee, Yong Jun, Pae, Dong Sung, Choi, Hyun Duck, Lim, Myo Taeg
Format: Article
Language:English
Subjects:
Autonomous driving
Autonomous vehicle
Autonomous vehicles
Delays
dynamic output feedback control
extended dissipativity
extended reciprocally convex matrix inequality
Linear matrix inequalities
Sensors
steering delay
Steering systems
Symmetric matrices
Vehicle dynamics
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Summary:Designing robust controllers that follow a desired trajectory against unexpected internal/external disturbances presents a major challenge in the field of autonomous driving technology. In general, robust controller designs ensuring the {H}_{\infty } performance are a popular solution. However, the {H}_{\infty } performance only focuses on reducing the total energy of tracking errors. Sometimes, attenuating the peak value of the tracking error can be considered of equal or more importance in terms of safe driving, although this can only be achieved through the {L}_{2}-{L}_{\infty } performance. Accordingly, we propose a new controller synthesis for path-following systems in autonomous vehicles using the extended dissipativity that can consider both the maximum and total energies of the tracking error in a unified framework. In addition, autonomous vehicles usually suffer from an inevitable steering delay, which has a more adverse effect on driving stability at higher speeds. To mitigate the effect of these steering delays, we derive a new set of delay-dependent conditions for the proposed controller using the extended reciprocally convex matrix inequality. Finally, CarSim/Simulink joint-simulations under different road environments are conducted to demonstrate the effectiveness of the proposed design technique.
ISSN:1524-9050
1558-0016
DOI:10.1109/TITS.2024.3375885