考虑时变参考和转向延迟的自动驾驶车辆轨迹跟踪控制方法

doi:10.19562/j.chinasae.qcgc.2025.01.005

Abstract

Abstract:

The optimal control method has become the mainstream research and industry deployment method for lateral motion control in autonomous driving. The LQR method is widely used due to its advantages of low online computational load and good real-time performance， but it cannot consider time-varying references and steering delay. The presence of delay can cause the LQR method to lose stability at high speed， so it is essential to solve this problem while maintaining the characteristic of small computational load of LQR. In this paper， under the premise of ensuring real-time performance， the problem of LQR's inability to consider time-varying references and steering delay is solved. By incorporating road curvature as time-varying references， steering delay characteristics as pure delay， and first-order inertial section into the tracking error state equation， and by looking up the KKT inverse matrix part corresponding to the control time domain into the real-time solver， the aim is to reduce computational load and ensure controller real-time performance. The simulation results demonstrate that the constructed EqLPV-MPC controller can effectively handle road curvature changes. Compared to the LQR method， under the condition of dual lane change at a speed of 72 km/h， the lateral error decreases by 39%， with the heading error decreasing by 52%， and the lateral deviation of the center of mass decreasing by 28%. The results from real vehicle tests show that under dual lane change conditions， the controller constructed in this paper can keep the maximum lateral error within 0.1 m.

Key words: trajectory tracking, model predictive control, road curvature, steering lag, inertial element

Zhengcai Yang,Huiquan Zhang,Linhe Ge,Tianjun Sun. Trajectory Tracking Control Method for Autonomous Vehicles Considering Time-Varying Reference and Steering Delay[J].Automotive Engineering, 2025, 47(1): 44-54.

Figures/Tables 15

参数	数值
整车质量 $m / k g$	1 412
质心到前轴距离 $l f / m$	1.015
质心到后轴距离 $l r / m$	1.895
绕轴转动惯量 $I z / (k g ? m 2)$	1 536.7
前轮侧偏刚度 $C a f / (N ? r a d - 1)$	81 910.295
后轮侧偏刚度 $C a r / (N ? r a d - 1)$	81 910.295
车轮滚动半径 $r e / m$	0.325
路面附着系数 $μ$	0.85
车辆转向延迟时间 $T l a g / m s$	300

References 19

1	XU S， PENG H. Design， analysis， and experiments of preview path tracking control for autonomous vehicles［J］. IEEE Transactions on Intelligent Transportation Systems， 2019， 21（1）： 48-58.
2	QIN Z， CHEN L， HU M， et al. A lateral and longitudinal dynamics control framework of autonomous vehicles based on multi-parameter joint estimation［J］. IEEE Transactions on Vehicular Technology， 2022， 71（6）： 5837-5852.
3	陈亮，秦兆博，孔伟伟，等.基于最优前轮侧偏力的智能汽车LQR横向控制［J］.清华大学学报（自然科学版），2021，61（9）：906-912.
	CHEN Liang， QIN Zhaobo， KONG Weiwei， et al. Lateral control using LQR for intelligent vehicles based on the optimal front-tire lateral force［J］. Journal of Tsinghua University （Science and Technology）， 2021， 61（9）： 906-912.
4	胡杰，钟鑫凯，陈瑞楠，等.基于模糊LQR的智能汽车路径跟踪控制［J］.汽车工程，2022，44（1）：17-25，43.
	HU J， ZHONG X， CHEN R， et al. Path tracking control of intelligent vehicles based on fuzzy LQR［J］. Automotive Engineering， 2022， 44（1）： 17-25，43.
5	孟宇，汪钰，顾青，等.基于预见位姿信息的铰接式车辆LQR-GA路径跟踪控制［J］.农业机械学报，2018，49（6）：375-384.
	MENG Y， WANG Y， GU Q， et al. LQR-GA path tracking control of articulated vehicle based on predictive information［J］. Transactions of the Chinese Society for Agricultural Machinery， 2018， 49（6）： 375-384.
6	LEE K， JEON S， KIM H， et al. Optimal path tracking control of autonomous vehicle： adaptive full-state linear quadratic Gaussian （LQG） control［J］. IEEE Access， 2019， 7： 109120-109133.
7	ZAKARIA M I， HUSAIN A R， MOHAMED Z， et al. Lyapunov-Krasovskii stability condition for system with bounded delay-an application to steer-by-wire system［C］.2015 IEEE International Conference on Control System， Computing and Engineering （ICCSCE）. IEEE， 2015： 543-547.
8	EL FEZAZI N， TISSIR E H， EL HAOUSSI F， et al. Controller synthesis for steer-by-wire system performance in vehicle［J］. Iranian Journal of Science and Technology， Transactions of Electrical Engineering， 2019， 43（4）： 813-825.
9	XU L， GE S Q， GUO J Y. Application of self-adaptive TDF-IMC in grinding classification process［C］.2018 Chinese Control And Decision Conference （CCDC）. IEEE， 2018： 2982-2984.
10	刘文通，陈俐，陈峻. 考虑延迟的汽车线控转向系统自适应内模控制［J］. 上海交通大学学报， 2021， 55（10）： 1210-1218.
	LIU Wentong， CHEN Li， CHEN Jun. Adaptive internal model control for automotive steer-by-wire system with time delay［J］. Journal of Shanghai Jiao Tong University， 2021， 55（10）： 1210-1218.
11	吕颖，祁旭，刘秋铮，等.考虑转向延迟特性的自动驾驶车辆路径跟踪控制方法［J］.汽车工程，2023，45（12）：2234-2241.
	LÜ Ying， QI Xu， LIU Qiuzheng，et al. Path tracking control method with steering lag for autonomous vehicles［J］. Automotive Engineering， 2023， 45（12）： 2234-2241.
12	LEI Z， MA X， YUAN X， et al. Research on automatic driving path tracking control of open-pit mine transportation vehicles with delay compensation［J］. World Electric Vehicle Journal， 2022， 13（8）： 134.
13	王威，陈慧岩，马建昊，等.基于Frenet坐标系和控制延时补偿的智能车辆路径跟踪［J］.兵工学报，2019，40（11）：2336-2351.
	WANG Wei， CHEN Huiyan， MA Jianhao， et al. Path tracking for intelligent vehicles based on frenet coordinates and delayed control［J］. Acta Armamentarii， 2019， 40（11）： 2336-2351.
14	GAO F， HAN Y， LI S E， et al. Accurate pseudospectral optimization of nonlinear model predictive control for high-performance motion planning［J］. IEEE Transactions on Intelligent Vehicles， 2022， 8（2）： 1034-1045.
15	XU S， PENG H， SONG Z， et al. Accurate and smooth speed control for an autonomous vehicle［C］.2018 IEEE Intelligent Vehicles Symposium （IV）. IEEE， 2018： 1976-1982.
16	XU S， PENG H， TANG Y. Preview path tracking control with delay compensation for autonomous vehicles［J］. IEEE Transactions on Intelligent Transportation Systems， 2020， 22（5）： 2979-2989.
17	GE L， ZHAO Y， ZHONG S， et al. Motion control of autonomous vehicles based on offset free model predictive control methods［J］. Journal of Dynamic Systems， Measurement， and Control， 2022， 144（11）： 111003.
18	GE L， ZHAO Y， MA F， et al. Towards longitudinal and lateral coupling control of autonomous vehicles using offset free MPC［J］. Control Engineering Practice， 2022， 121： 105074.
19	STANO P， MONTANARO U， TAVERNINI D， et al. Model predictive path tracking control for automated road vehicles： a review［J］. Annual Reviews in Control， 2023， 55： 194-236.

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Trajectory Tracking Control Method for Autonomous Vehicles Considering Time-Varying Reference and Steering Delay

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