Enhanced Fuzzy-MFC-based Traction Control System for Electric Vehicles

被引:0
|
作者
Nguyen, Nam T. [1 ]
Ta, Minh C. [1 ,2 ]
Thanh Vo-Duy [1 ]
Ivanov, Valentin [3 ]
机构
[1] Hanoi Univ Sci & Technol, Control Tech & Innovat Lab Elect Vehicles, Sch Elect & Elect Engn, Hanoi, Vietnam
[2] Univ Sherbrooke, E TESC Lab, Sherbrooke, PQ, Canada
[3] Tech Univ Ilmenau, Ilmenau, Germany
来源
2023 IEEE VEHICLE POWER AND PROPULSION CONFERENCE, VPPC | 2023年
关键词
Electric vehicle; traction control system; antislip; controller; fuzzy controller; LOCK BRAKING SYSTEM; DESIGN; MODEL;
D O I
10.1109/VPPC60535.2023.10403162
中图分类号
TM [电工技术]; TN [电子技术、通信技术];
学科分类号
0808 ; 0809 ;
摘要
Modern vehicles require the installation of motion control systems to ensure driving safety. In electric vehicles, these systems are convenient to be developed and applied due to the better response of the electric motor compared to the internal combustion engine. Therefore, the development of traction control systems for electric vehicles is of great interest to many researchers. In this study, a wheel slip control algorithm for electric vehicles is proposed by considering the vehicle as an equivalent inertial system. Based on the monotonicity of the algorithm, a fuzzy controller is also incorporated in the study so that the wheel slip control can adapt to the actual road conditions. Its performance is verified by comparative simulations with baseline anti-slip methods for different road conditions and vehicle velocities.
引用
收藏
页数:6
相关论文
共 50 条
  • [31] Rational control system of a traction electric drive for hybrid cars and electric vehicles with increased fault tolerance
    Klyukin P.N.
    Thieu N.Q.
    Russian Electrical Engineering, 2012, 83 (7) : 362 - 364
  • [32] Traction System for Electric Vehicles Based on Synchronous Reluctance Permanent Magnet Machine
    Sousa, Joao D. C.
    Sousa, Tiago J. C.
    Monteiro, Vitor
    Afonso, Joao L.
    ELECTRONICS, 2023, 12 (03)
  • [33] DYNAMIC PROCESSES IN THE DRIVE SYSTEM OF ELECTRIC TRACTION VEHICLES
    ZOBORY, I
    BENEDEK, T
    GYORIK, A
    SZABO, A
    VEHICLE SYSTEM DYNAMICS, 1988, 17 : 559 - 570
  • [34] Nonlinear optimal control for the five-phase induction motor-based traction system of electric vehicles
    Rigatos, Gerasimos G.
    Siano, Pierluigi
    Al-Numay, Mohammed S.
    Sari, Bilal
    Abbaszadeh, Masoud
    COMPEL-THE INTERNATIONAL JOURNAL FOR COMPUTATION AND MATHEMATICS IN ELECTRICAL AND ELECTRONIC ENGINEERING, 2024, 43 (01) : 167 - 191
  • [35] Design of traction control system for electric scooter using self-organising fuzzy control
    Chen, Bo-Chiuan
    Chu, Chia-Hsing
    Huang, Shiuh-Jer
    INTERNATIONAL JOURNAL OF VEHICLE DESIGN, 2013, 62 (01) : 87 - 100
  • [36] Control system for electric traction drive
    Lehtla, M
    Laugis, J
    BEC 2004: Proceeding of the 9th Biennial Baltic Electronics Conference, 2004, : 331 - 332
  • [37] Fuzzy logic based control for electric vehicle with four separate traction drives
    Pusca, R
    Ait-Amirat, Y
    Berthon, A
    Kauffmann, JM
    IEEE 55TH VEHICULAR TECHNOLOGY CONFERENCE, VTC SPRING 2002, VOLS 1-4, PROCEEDINGS, 2002, : 2089 - 2096
  • [38] Fuzzy Logic Strategy for Traction Control in Parallel Hybrid Vehicles
    Gomez-Barroso, Alvaro
    Otaola, Eneko
    Onieva, Enrique
    Arteta, Benat
    Perez, Joshue
    Prieto, Pablo
    2023 IEEE 26TH INTERNATIONAL CONFERENCE ON INTELLIGENT TRANSPORTATION SYSTEMS, ITSC, 2023, : 3686 - 3691
  • [39] Traction and braking of hybrid electric vehicles using control allocation
    Laine, Leo
    Fredriksson, Jonas
    INTERNATIONAL JOURNAL OF VEHICLE DESIGN, 2008, 48 (3-4) : 271 - 298
  • [40] A novel traction control without chassis velocity for electric vehicles
    Yin, Dejun
    Hori, Yoichi
    World Electric Vehicle Journal, 2009, 3 (02): : 282 - 288
12345