从低阶建模到全域智能：分布式驱动车辆多物理场耦合机理、估计与控制综述

doi:10.3901/JME.260274

摘要/Abstract

摘要： 分布式驱动电动汽车(Distributed drive electric vehicle,DDEV)凭借轮端独立驱动的优势，在控制自由度和响应灵活性等方面展现出显著潜力。然而，DDEV高度耦合的机-电-路系统特性对建模精度、状态估计和控制策略提出更高要求。系统梳理了DDEV在建模、状态估计与控制方面的研究进展。在建模方面，重点分析机-电-路耦合系统中的关键问题，包括道路模型构建、轮毂电机不平衡电磁力建模、纵-横-垂耦合动力学建模及其机理。针对复杂系统的动力学响应估计问题，从模型驱动、数据驱动以及数据-模型融合驱动方法出发，重点总结了卡尔曼滤波、Transformer结构以及物理信息神经网络的研究应用。在控制策略方面，综述了不同控制架构下面向复杂模型的自适应控制方法、扰动抑制策略及多目标优化技术。最后，总结并探讨了当前研究面临的主要挑战与发展趋势，指出未来DDEV研究应进一步加强多物理场耦合作用下的系统行为预测、多源异构信息融合，以及基于人工智能与物理先验知识的端到端控制方法。

关键词: 分布式驱动, 多物理场耦合, 数据驱动, 模型驱动

Abstract: Distributed drive electric vehicles(DDEV), benefiting from their independently actuated wheel-end architecture, demonstrate significant potential in terms of control degrees of freedom and dynamic response flexibility. However, the highly coupled mechanical-electrical-road system inherent in DDEVs poses greater challenges for modeling accuracy, state estimation, and control strategy design. This paper presents a comprehensive review of recent advances in the modeling, state estimation, and control of DDEVs. Regarding modeling, the review focuses on key aspects of mechanical-electrical-road coupled systems, including road surface modeling, unbalanced magnetic force modeling of in-wheel motors, and longitudinal-lateral-vertical coupled dynamics modeling and mechanisms. For the problem of dynamic response estimation in complex systems, the paper summarizes approaches based on model-driven, data-driven, and hybrid model-data-driven methods, with particular attention to the applications of Kalman filtering, Transformer architectures, and physics-informed neural networks. In terms of control, various adaptive control strategies, disturbance rejection methods, and multi-objective optimization techniques under different control frameworks are reviewed. Finally, this paper summarizes and discusses the main challenges and future development trends in current research. It points out that future studies on DDEV should further enhance system behavior prediction under multi-physics coupling effects, multi-source heterogeneous information fusion, and end-to-end control methods based on artificial intelligence and physical prior knowledge.

Key words: distributed drive, muti-physics coupling, data-driven, model-driven

中图分类号:

U461

杨泽坤, 李韶华, 杨绍普. 从低阶建模到全域智能：分布式驱动车辆多物理场耦合机理、估计与控制综述[J]. 机械工程学报, 2026, 62(8): 221-245.

YANG Zekun, LI Shaohua, YANG Shaopu. From Reduced Model to Global Intelligence: Multi-physics Coupling, Estimation, and Control of Distributed Drive Electric Vehicles[J]. Journal of Mechanical Engineering, 2026, 62(8): 221-245.

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参考文献

[1] 国务院办公厅.国务院办公厅关于印发《新能源汽车产业发展规划(2021-2035年)》的通知:国办发[2020] 39号[EB/OL].(2020-10-20)[2025-05-08]. https://wap.miit.gov.cn/jgsj/ghs/zlygh/art/2022/art_158cc63ebe76470cbff2458c4328ea22.html.General Office of the State Council of the People's Republic of China. Notice of the general office of the state council on issuing the new energy vehicle industry development plan(2021–2035):no. 39[2020] of the general office of the state council of the people’s republic of china[EB/OL].(2020-10-20)[2025-05-08]. https://wap.miit.gov.cn/jgsj/ghs/zlygh/art/2022/art_158cc63ebe76470cbff2458c4328ea22.html.
[2] 国家发展和改革委员会.关于印发《智能汽车创新发展战略》的通知:发改产业[2020] 202号[EB/OL].(2020-02-28)[2025-05-08]. https://www.ndrc.gov.cn/xwdt/tzgg/202002/t20200224_1235917.html.National Development And Reform Commission(NDRC).Notice on issuing the strategy for innovation and development of intelligent vehicles:no. 202[2020] of ndrc[EB/OL].(2020-02-28)[2025-05-08]. https://www.ndrc.gov.cn/xwdt/tzgg/202002/t20200224_1235917.html.
[3] 新华社.全国机动车达4.4亿辆驾驶人达5.32亿人[EB/OL].(2024-07-08)[2025-05-08]. https://www.gov.cn/lianbo/bumen/202407/content_6961935.html.Xinhua News Agency. China's motor vehicles reach 440million, licensed drivers total 532 million[EB/OL].(2024-07-08)[2025-05-08]. https://www.gov.cn/lianbo/bumen/202407/content_6961935.html.
[4] KHAN M A,SAYED H E,MALIK S,et al. Level-5autonomous driving-are we there yet? A review of research literature[J]. ACM Computing Surveys,2023,55(2):1-38.
[5] ZHAO K,FAN X,HUANG Z,et al. A review of drive torque distribution control for distributed drive electric vehicles[J]. Proceedings of the Institution of Mechanical Engineers,Part D:Journal of Automobile Engineering,2024:74545024.
[6] 吴建洋,王震坡,张雷,等.四轮轮毂电机驱动电动汽车纵侧向稳定性协调控制策略研究[J].机械工程学报,2023,59(4):163-172.WU Jianyang,WANG Zhenpo,ZHANG Lei,et al.Coordination stability control strategy for four-wheel-independent-actuated electric vehicles[J].Journal of Mechanical Engineering,2023,59(4):163-172.
[7] 赵明慧,郭浩然,张利鹏,等.四轮独立转向分布式驱动电动汽车单轮转向失效行驶稳定性控制[J].机械工程学报,2024,60(10):507-522.ZHAO Minghui,GUO Haoran,ZHANG Lipeng,et al.Driving stability control of four-wheel independent steering distributed drive electric vehicle with single wheel steering failure[J]. Journal of Mechanical Engineering,2024,60(10):507-522.
[8] 金贤建,王佳栋,徐利伟,等.轮毂电机驱动电动汽车主动悬架μ综合鲁棒控制研究[J].机械工程学报,2024,60(16):259-269.JIN Xianjian,WANG Jiadong,XU Liwei,et al.μsynthesis robust control for active suspension of in-wheel-motor-driven electric vehicles[J]. Journal of Mechanical Engineering. 2024,60(16):259-269.
[9] 余卓平,冯源,熊璐.分布式驱动电动汽车动力学控制发展现状综述[J].机械工程学报,2013,49(8):105-114.YU Zhuoping,FENG Yuan,XIONG Lu. Review on vehicle dynamics control of distributed drive electric vehicle[J]. Journal of Mechanical Engineering,2013,49(8):105-114.
[10] 邹渊,郭宁远,张旭东,等.分布式电驱动车辆力矩分配控制研究现状综述[J].中国公路学报,2021,34(9):1-25.ZOU Yuan,GUO Ningyuan,ZHANG Xudong,et al.Review of torque allocation control for distributed-drive electric vehicles[J]. China Journal of Highway and Transport,2021,34(9):1-25.
[11] WANG R,CHEN Y,FENG D,et al. Development and performance characterization of an electric ground vehicle with independently actuated in-wheel motors[J]. Journal of Power Sources,2011,196(8):3962-3971.
[12] THORNTON S M,PAN S,ERLIEN S M,et al.Incorporating ethical considerations into automated vehicle control[J]. IEEE Transactions on Intelligent Transportation Systems,2017,18(6):1429-1439.
[13] WANNER D,WALLMARK O,JONASSON M,et al.Control allocation strategies for an electric vehicle with a wheel hub motor failure[J]. International Journal of Vehicle Systems Modelling&Testing,2015,10(3):263.
[14] YU Z,LU X,LENG B,et al. Reimagining new energy vehicles:Research innovations at Tongji University[J].Science,2017,358(6370):34-38.
[15] 李亮,王翔宇,程硕,等.汽车底盘线控与动力学域控制技术[J].汽车安全与节能学报,2020,11(2):143-160.LI Liang, WANG Xiangyu, CHENG Shuo, et al.Technologies of control-by-wire and dynamic domain control for automotive chassis[J]. Journal of Automotive Safety and Energy,2020,11(2):143-160.
[16] 仰望携“易四方”技术正式亮相比亚迪以颠覆性技术打造高端品牌[J].中国经济周刊,2023:92-93.Yangwang debuts with"e4"technology-BYD launches high-end brand with disruptive innovation[J]. China Economic Weekly,2023:92-93.
[17] 鲲鹏1号--陆空一体飞行汽车来了[J].国企管理.2025(1):21.Kunpeng-1:the integrated land-air flying car has arrived[J]. China State-owned Enterprise Management,2025(1):21.
[18] 张雷,赵宪华,王震坡.四轮轮毂电机独立驱动电动汽车轨迹跟踪与横摆稳定性协调控制研究[J].汽车工程,2020,42(11):1513-1521.ZHANG Lei,ZHAO Xianhua,WANG Zhenpo. Study on coordinated control of trajectory tracking and yaw stability for autonomous four-wheel-independent-driving electric vehicles[J]. Automotive Engineering,2020,42(11):1513-1521.
[19] 张利鹏,穆建华,王建涛,等.角模块架构智能电动汽车路径跟踪鲁棒预测控制[J].中国公路学报,2024,37(1):241-254.ZHANG Lipeng,MU Jianhua,WANG Jiantao,et al.Robust predictive control for path tracking of intelligent electric vehicle based on wheel corner module[J]. China Journal of Highway and Transport,2024,37(1):241-254.
[20] 殷国栋,金贤建,张云.分布式驱动电动汽车底盘动力学控制研究综述[J].重庆理工大学学报(自然科学版),2016,30(8):13-19,26.YIN Guodong,JIN Xianjian,ZHANG Yun. Overview for chassis vehicle dynamics control of distributed drive electric vehicle[J]. Journal of Chongqing Institute of Technology,2016,30(8):13-19,26.
[21] 殷国栋,金贤建.分布式驱动电动汽车底盘稳定性控制[M].武汉:华中科技大学出版社,2021.YIN Guodong,JIN Xianjian. Advanced control of chassis stability for distributed drive electric vehilces[M].Wuhan:Huazhong University of Science&Technology Press,2021.
[22] 赵轩,王姝,马建,等.分布式驱动电动汽车底盘集成控制技术综述[J].中国公路学报,2023,36(4):221-248.ZHAO Xuan,WANG Shu,MA Jian,et al. Review of chassis integrated control technology for distributed drive electric vehicles[J]. China Journal of Highway and Transport,2023,36(4):221-248.
[23] 张利鹏,刘一帆,刘帅帅,等.分布式驱动电动汽车回馈制动单侧电机失效的机电液复合控制[J].机械工程学报,2025,61(22):250-261.ZHANG Lipeng,LIU Yifan,LIU Shuaishuai,et al.Electromechanical hydraulic composite control for regenerative braking of single motor failure in distributed drive electric vehicles[J]. Journal of Mechanical Engineering,2025,61(22):250-261.
[24] ZHAO Z,TAGHAVIFAR H,DU H,et al. In-wheel motor vibration control for distributed-driven electric vehicles:A review[J]. IEEE Transactions on Transportation Electrification,2021,7(4):2864-2880.
[25] 张永林.用谐波叠加法重构随机道路不平顺高程的时域模型[J].农业工程学报,2003,19(6):32-35.ZHANG Yonglin. Time domain model of road irregularities simulated using the harmony superposition method[J]. Transactions of the Chinese Society of Agricultural Engineering,2003,19(6):32-35.
[26] 殷珺,陈辛波,吴利鑫,等.滤波白噪声路面时域模拟方法与悬架性能仿真[J].同济大学学报(自然科学版),2017,45(3):398-407.YIN Jun,CHEN Xinbo,WU Lixin,et al. Simulation method of road excitation in time domain using filtered white noise and dynamic analysis of suspension[J].Journal of Tongji University(Natural Science),2017,45(3):398-407.
[27] 石晓辉,蒋欣,赵军,等.四轮随机路面激励下的七自由度车辆响应特性[J].科学技术与工程,2018,18(27):71-78.SHI Xiaohui,JIANG Xin,ZHAO Jun,et al. Seven degrees of freedom vehicle response characteristic under four-wheel random pavement excitation[J]. Science Technology and Engineering,2018,18(27):71-78.
[28] 黄大山,王炳奇,刘海亮,等.四轮车辆路面激励数学模型[J].兵器装备工程学报,2021,42(2):142-146.HUANG Dashan,WANG Bingqi,LIU Hailiang,et al.Research on assessment method of vibration control feature of suspension system of vehicle[J]. Journal of Sichuan Ordnance,2021,42(2):142-146.
[29] 赵珩,卢士富.路面对四轮汽车输入的时域模型[J].汽车工程,1999(2):112-117.ZHAO Heng,LU Shifu. A vehicle’s time domain model with road input on four wheels[J]. Automotive Engineering,1999(2):112-117.
[30] WANG Z,DONG M,GU L,et al. Influence of road excitation and steering wheel input on vehicle system dynamic responses[J]. Applied Sciences,2017,7(6):570.
[31] International Organization for Standardization. ISO 8608:2016 Mechanical vibration-road surface profilesreporting of measured data[S]. Geneva:ISO,2016.
[32] 李韶华,冯桂珍,丁虎.考虑胎路多点接触的电动汽车-路面耦合系统振动分析[J].力学学报,2021,53(9):2555-2568.LI Shaohua, FENG Guizhen, DING Hu. Vibration analysis of electric vehicle-road coupling system considering tire-road muti-point contact[J]. Chinese Journal of Theoretical and Applied Mechanics,2021,53(9):2555-2568.
[33] ESEN I. Dynamic response of a functionally graded Timoshenko beam on two-parameter elastic foundations due to a variable velocity moving mass[J]. International Journal of Mechanical Sciences,2019,153-154:21-35.
[34] WANG Y,CAO J,HUANG W,et al. Dynamic response analysis of vehicle–pavement-coupled system based on RIOHtrack full-size accelerated loading test[J].Construction and Building Materials,2023,402:132744.
[35] YANG S,CHEN L,LI S. Dynamics of vehicle-road coupled system[M]. Berlin,Heidelberg:Springer Berlin/Heidelberg,2015.
[36] SINGH S J,HARSHA S P. Nonlinear dynamic analysis of sandwich S-FGM plate resting on pasternak foundation under thermal environment[J]. European Journal of Mechanics-A/Solids,2019,76:155-179.
[37] 冯桂珍,李韶华,赵文忠.电动汽车-路面系统机电耦合建模及非线性振动分析[J].振动与冲击,2021,40(14):18-76.FENG Guizhen, LI Shaohua, ZHAO Wenzhong.Electromechanical coupling modelling and nonlinear vibration analysis of an electric vehicle-road system[J].Journal of Vibration and Shock,2021,40(14):18-76.
[38] LI S,YANG S,LU Y. Investigation of the interaction between a vehicle and the road using the second road excitation on the vehicle[J]. Proceedings of the Institution of Mechanical Engineers,Part D:Journal of Automobile Engineering,2009,223(7):855-863.
[39] YANG S,LI S,LU Y. Investigation on dynamical interaction between a heavy vehicle and road pavement[J].Vehicle System Dynamics,2010,48(8):923-944.
[40] FENG G,LI S,YANG S. Coupling vibration analysis of hub motor driving electric vehicle and sandwich plate road[J]. Applied Mathematical Modelling,2025,137:115668.
[41] ZHANG J,YANG S,LI S,et al. Influence of vehicle-road coupled vibration on tire adhesion based on nonlinear foundation[J]. Applied Mathematics and Mechanics,2021,42(5):607-624.
[42] WANG T, YANG S, ZHANG J, et al. Vibration characteristics of vehicle-pavement coupled system with non-uniform dynamic tire model based on nonlinear Timoshenko foundation beam[J]. Acta Mechanica Sinica,2025,41(9):524219.
[43] XU Y,YANG C J,ZHU W D,et al. A reduced-plate model transmission method for fast dynamic analysis of vehicle–pavement interaction[J]. Journal of Sound and Vibration,2023,548:117554.
[44] KIM N,KIM C,JI T,et al. Axial flux permanent magnet FSCW machine decoupling unbalance magnetic force[C] //202124th International Conference on Electrical Machines and Systems(ICEMS). Gyeongju:IEEE,2021:1317-1321.
[45] KIM H,POSA A,NERG J,et al. Vibration effect by unbalanced magnetic pull in a centrifugal pump with integrated permanent magnet synchronous motor[C] //International Conference on Rotor Dynamics.Rio de Janeiro:Springer,2018:221-233.
[46] GIERAS J F,SHEN J. Modern permanent magnet electric machines theory and control[M]. Florida:CRC Press,2023.
[47] 李天成,邓兆祥,张河山,等.轮毂电机驱动电动汽车机电耦合垂向动力学特性[J].重庆大学学报,2024,47(1):69-83.LI Tiancheng,DENG Zhaoxiang,ZHANG Heshan,et al.Vertical dynamic characteristics of electromechanical coupling of in-wheel motor drive system for electric vehicle[J]. Journal of Chongqing University(Natural Science Edition),2024,47(1):69-83.
[48] LE BESNERAIS J. Vibroacoustic analysis of radial and tangential air-gap magnetic forces in permanent magnet synchronous machines[J]. IEEE Transactions on Magnetics,2015,51(6):1-9.
[49] 马琮淦,左曙光,孟姝,等.考虑开槽和高次谐波的永磁同步电机解析模型[J].振动、测试与诊断,2015,35(2):231-237.MA Conggan,ZUO Shuguang,MENG Shu,et al.Analytical model of permanent magnet synchronous motors considering slotting and high harmonics[J].Journal of Vibration,Measurement&Diagnosis,2015,35(2):231-237.
[50] 胡胜龙,左曙光,刘明田.开关磁阻电机非线性径向电磁力解析建模[J].电工技术学报,2020,35(6):1189-1197.HU Shenglong,ZUO Shuguang,LIU Mingtian. Analytical modeling of nonlinear radial electromagnetic force in switched reluctance motors[J]. Transactions of China Electrotechnical Society,2020,35(6):1189-1197.
[51] 庞古才,邓智泉,张忠明.基于改进广义磁路法的表贴式永磁电机空载气隙磁场解析计算[J].电工技术学报,2019,34(22):4623-4633.PANG Gucai,DENG Zhiquan,ZHANG Zhongming.Analytical calculation of no-load air gap magnetic field in surface-mounted permanent magnet motor based on improved generalized magnetic circuit method[J].Transactions of China Electrotechnical Society,2019,34(22):4623-4633.
[52] CHUAN H,SHEK J K H. Calculation of unbalanced magnetic pull in induction machines through empirical method[J]. IET Electric Power Applications,2018,12(9):1233-1239.
[53] LI Y,LU Q,ZHU Z Q. Unbalanced magnetic force prediction in permanent magnet machines with rotor eccentricity by improved superposition method[J]. IET Electric Power Applications,2017,11(6):1095-1104.
[54] MA C,LI Q,LU H,et al. Analytical model for armature reaction of outer rotor brushless permanent magnet DC motor[J]. IET Electric Power Applications,2018,12(5):651-657.
[55] KIM H,NERG J,CHOUDHURY T,et al. Rotor dynamic simulation method of induction motors including the effects of unbalanced magnetic pull[J]. IEEE Access,2020(8):21631-21643.
[56] CHEN X,YUAN S,PENG Z. Nonlinear vibration for PMSM used in HEV considering mechanical and magnetic coupling effects[J]. Nonlinear Dynamics,2015,80(1-2):541-552.
[57] KIM H, POSA A, NERG J, et al. Analysis of electromagnetic excitations in an integrated centrifugal pump and permanent magnet synchronous motor[J]. IEEE Transactions on Energy Conversion, 2019, 34(4):1759-1768.
[58] 钟银辉,李以农,杨超,等.基于主动悬架控制轮边驱动电动车垂向振动研究[J].振动与冲击,2017,36(11):242-247.ZHONG Yinhui,LI Yinong,YANG Chao,et al. Vertical vibration of in-wheel motor electric vehicles based on active suspension control[J]. Journal of Vibration and Shock,2017,36(11):242-247.
[59] 李韶华,罗海涵,冯桂珍,等.电动汽车机-电-路耦合系统建模及动力学分析[J].机械工程学报,2021,57(12):51-61.LI Shaohua,LUO Haihan,FENG Guizhen,et al.Modeling and dynamic analysis of mechanic-electro-road coupling system of electric vehicles[J]. Journal of Mechanical Engineering,2021,57(12):51-61.
[60] HOSSEINPOUR A,RAHIDEH A,ABBAS A,et al.Calculating torque, back-EMF, inductance, and unbalanced magnetic force for a hybrid electrical vehicle by in-wheel drive application[J]. Scientific Reports,2024,14(1):12912.
[61] 韩雪岩,王勇,高俊.低速永磁同步电机转子偏心的抑制措施[J].电机与控制学报,2023,27:58-65.HAN Xueyan,WANG Yong,GAO Jun. Suppression of rotor eccentricity of low-speed permanent magnet synchronous motor[J]. Electric Machines and Control,2023,27:58-65.
[62] DENG Z,QIN H,CHEN T,et al. Integrated optimization of the in-wheel motor driving system considering the ride comfort of the electric vehicle under multiple operating conditions[J]. Proceedings of the Institution of Mechanical Engineers,Part D:Journal of Automobile Engineering,2024,238(14):4283-4303.
[63] HUANG F,WANG Z,CHEN C,et al. Dynamic behavior of permanent magnet synchronous motor rotor radial eccentricity[J]. Measurement Science&Technology,2025,36(1):161.
[64] MO S,CHEN K,ZHANG Y,et al. Vertical dynamics analysis and multi-objective optimization of electric vehicle considering the integrated powertrain system[J].Applied Mathematical Modelling,2024,131:33-48.
[65] LAI F,HUANG C,YE X. Analysis of vehicle driving stability based on longitudinal-lateral and vertical unified dynamics model[J]. International Journal of Automotive Technology,2022,23(1):73-87.
[66] QIN Y,WANG Z,XIANG C,et al. A novel global sensitivity analysis on the observation accuracy of the coupled vehicle model[J]. Vehicle System Dynamics,2019,57(10):1445-1466.
[67] LAI F,JIANG C. Establishment and simulation analysis of 18 DOF unified dynamics model of automobile chassis[J]. International Journal of Control,Automation,and Systems,2021,19(7):2323-2342.
[68] WANG Y,LIAN R,HE H,et al. Auto-tuning dynamics parameters of intelligent electric vehicles via Bayesian optimization[J]. IEEE Transactions on Transportation Electrification,2024,10(3):6915-6927.
[69] ZHOU X,ZHAO W,WANG C,et al. Multidisciplinary optimization design of electric vehicle X-by-wire chassis integrating parameter coupling and uncertainties[J]. IEEE Transactions on Transportation Electrification,2025,11(1):4765-4777.
[70] CHENG S,WANG Z,YANG B,et al. Quantitative evaluation methodology for chassis-domain dynamics performance of automated vehicles[J]. IEEE Transactions on Cybernetics,2023,53(9):5938-5948.
[71] SUN C,WANG C,DENG Z,et al. Dimensionless model-based system tracking via augmented kalman filter for multiscale unmanned ground vehicles[J]. IEEE/ASME Transactions on Mechatronics,2021,26(2):600-610.
[72] LI B,ZHANG L,ZHAO C,et al. Capturing rapid vehicle dynamics:A refined adaptive kalman filter for enhanced tire–road friction estimation[J]. IEEE Transactions on Industrial Electronics,2024,71(11):14813-14822.
[73] ZHANG Q,JING H,LIU Z,et al. A novel PWA lateral dynamics modeling method and switched T-S observer design for vehicle sideslip angle estimation[J]. IEEE Transactions on Industrial Electronics,2022,69(2):1847-1857.
[74] NGUYEN A, DINH T Q, GUERRA T, et al.Takagi–Sugeno fuzzy unknown input observers to estimate nonlinear dynamics of autonomous ground vehicles:theory and real-time verification[J].IEEE/ASME Transactions on Mechatronics,2021,26(3):1328-1338.
[75] XIA X,HASHEMI E,XIONG L,et al. Autonomous vehicle kinematics and dynamics synthesis for sideslip angle estimation based on consensus Kalman filter[J].IEEE Transactions on Control Systems Technology,2023,31(1):179-192.
[76] GAO L,XIA X,ZHENG Z,et al. GNSS/IMU/Lidar fusion for vehicle localization in urban driving environments within a consensus framework[J].Mechanical Systems and Signal Processing,2023,205:11862-11877.
[77] LIU H,WANG P,LIN J,et al. Real-time longitudinal and lateral state estimation of preceding vehicle based on moving horizon estimation[J]. IEEE Transactions on Vehicular Technology,2021,70(9):8755-8768.
[78] WU X,SHI W,ZHANG H,et al. Adaptive suspension state estimation based on IMMAKF on variable vehicle speed,road roughness grade and sprung mass condition[J].Scientific Reports,2024,14(1):1740.
[79] XIAO Z,XIAO D,HAVYARIMANA V,et al. Toward accurate vehicle state estimation under non-gaussian noises[J]. IEEE Internet of Things Journal,2019,6(6):10652-10664.
[80] HU J,RONG F,ZHANG P,et al. Sideslip angle estimation for distributed drive electric vehicles based on robust unscented particle filter[J]. Mathematics,2024,12(9):1350.
[81] YUAN H, SONG X. Adaptive adjustment of noise covariance for vehicle state estimation under packet dropping[J]. International Journal of Control,Automation and Systems,2023,21(11):3642-3649.
[82] PING X,CHENG S,YUE W,et al. Adaptive estimations of tyre road friction coefficient and body sideslip angle based on strong tracking and interactive multiple model theories[J]. Proceedings of the Institution of Mechanical Engineers,Part D:Journal of Automobile Engineering,2020,234(14):3224-3238.
[83] CHENG S,LI C,CHEN X,et al. A hierarchical estimation scheme of tire-force based on random-walk SCKF for vehicle dynamics control[J]. Journal of the Franklin Institute,2020,357(18):13964-13985.