@inproceedings{9c5b90aaa0f34aaab7a993c7405e6c50,
title = "Robust vehicle longitudinal motion control subject to in-wheel-motor driving torque variations",
abstract = "Driving torque variation which introduces external yaw moment greatly impacts vehicle motion particularly for distributed powertrain vehicles such as in-wheel motor electric vehicles. This paper proposes a weighted gain-scheduling H∞ controller to compensate for torque variation and track desired vehicle motions. The weighted H∞ performance is adopted to attenuate the effect of torque variation. A weighting factor is designed to tune the relative importance of external input and torque variation. An eigenvalue placement technique is used to confine the feedback control gain in certain region. The state feedback control gain is calculated by solving a minimization problem. Furthermore, a gain-scheduling scheme is used to incorporate time-varying signals in the system. Simulation studies were conducted on a high-fidelity vehicle model developed in CarSim{\textregistered}. Results indicate that the designed controller is able to compensate for driving torque variation and track the desired vehicle trajectory simultaneously.",
keywords = "electric vehicle, in-wheel-motor, robust control, torque variation",
author = "Yimin Chen and Hai Yu and Roger Graaf and Xiaoyong Wang and Junmin Wang",
note = "Publisher Copyright: {\textcopyright} 2017 American Automatic Control Council (AACC).; 2017 American Control Conference, ACC 2017 ; Conference date: 24-05-2017 Through 26-05-2017",
year = "2017",
month = jun,
day = "29",
doi = "10.23919/ACC.2017.7963619",
language = "英语",
series = "Proceedings of the American Control Conference",
publisher = "Institute of Electrical and Electronics Engineers Inc.",
pages = "4316--4321",
booktitle = "2017 American Control Conference, ACC 2017",
}