TY - GEN
T1 - Time-Optimal Learning-Based LTV-MPC for Autonomous Racing
AU - Guo, Zijun
AU - Yu, Huilong
AU - Xi, Junqiang
N1 - Publisher Copyright:
© The Author(s) 2024.
PY - 2024
Y1 - 2024
N2 - Autonomous racing is a time- and accuracy-critical application of vehicle motion planning and control techniques. Despite being promising for its ability to handle constraints, model predictive control (MPC) for autonomous racing is limited by the relatively low computational speed and the problem of model mismatch. In this work, we present a time-optimal linear-time-variant-MPC (LTV-MPC) that incorporates a min-time objective function, the friction ellipse constraint, and the successive linearization over the prediction horizon to improve computational speed and prediction accuracy. To tackle model mismatch, the proposed LTV-MPC is further combined with Gaussian process regression to learn the lateral tire force error. Compensation for the error is implemented over the prediction horizon and on the friction ellipse constraint. This work presents simulation validation on the racing track of Formula Student Autonomous China (FSAC) and experimental validation on a self-designed track. We show that compared with nonlinear MPC, the proposed LTV-MPC reduces the average computation time from 66 ms to 2.5 ms with a 0.6% increase in lap time. With learned tire force error, a 2% reduction in lap time can be achieved.
AB - Autonomous racing is a time- and accuracy-critical application of vehicle motion planning and control techniques. Despite being promising for its ability to handle constraints, model predictive control (MPC) for autonomous racing is limited by the relatively low computational speed and the problem of model mismatch. In this work, we present a time-optimal linear-time-variant-MPC (LTV-MPC) that incorporates a min-time objective function, the friction ellipse constraint, and the successive linearization over the prediction horizon to improve computational speed and prediction accuracy. To tackle model mismatch, the proposed LTV-MPC is further combined with Gaussian process regression to learn the lateral tire force error. Compensation for the error is implemented over the prediction horizon and on the friction ellipse constraint. This work presents simulation validation on the racing track of Formula Student Autonomous China (FSAC) and experimental validation on a self-designed track. We show that compared with nonlinear MPC, the proposed LTV-MPC reduces the average computation time from 66 ms to 2.5 ms with a 0.6% increase in lap time. With learned tire force error, a 2% reduction in lap time can be achieved.
KW - Autonomous driving
KW - Autonomous racing
KW - Gaussian process regression
KW - Model predictive control
UR - http://www.scopus.com/inward/record.url?scp=85206461822&partnerID=8YFLogxK
U2 - 10.1007/978-3-031-70392-8_33
DO - 10.1007/978-3-031-70392-8_33
M3 - Conference contribution
AN - SCOPUS:85206461822
SN - 9783031703911
T3 - Lecture Notes in Mechanical Engineering
SP - 228
EP - 234
BT - 16th International Symposium on Advanced Vehicle Control - Proceedings of AVEC 2024 – Society of Automotive Engineers of Japan
A2 - Mastinu, Giampiero
A2 - Braghin, Francesco
A2 - Cheli, Federico
A2 - Corno, Matteo
A2 - Savaresi, Sergio M.
PB - Springer Science and Business Media Deutschland GmbH
T2 - 16th International Symposium on Advanced Vehicle Control, AVEC 2024
Y2 - 2 September 2024 through 6 September 2024
ER -