Electronic Differential with Direct Torque Fuzzy Control for Vehicle Propulsion System

We model an electronic differential that will offer the best vehicle stability on a curved road. The proposed traction system consists of two permanent magnet synchronous (PMS) machines that ensure the drive of two back-driving wheels. The contribution of each wheel to the advance of the vehicle is represented by an element conveying the accumulation of mechanical coupling. The proposed control structure is based on the direct torque fuzzy control for each wheel-motor. Different simulations have been carried out: vehicle driven ons straight road, vehicle driven on straight road with slope, and vehicle driven over a road curved left and right. The simulation results show good vehicle stability on a curved road.

Electronic Differential with Direct Torque Fuzzy Control for Vehicle Propulsion System

We model an electronic differential that will offer the best vehicle stability on a curved road. The proposed traction system consists of two permanent magnet synchronous (PMS) machines that ensure the drive of two back-driving wheels. The contribution of each wheel to the advance of the vehicle is represented by an element conveying the accumulation of mechanical coupling. The proposed control structure is based on the direct torque fuzzy control for each wheel-motor. Different simulations have been carried out: vehicle driven ons straight road, vehicle driven on straight road with slope, and vehicle driven over a road curved left and right. The simulation results show good vehicle stability on a curved road.

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  • A. Bouscaylor, B. Davat, B. de Fornel, B. Fra¸cois, “Multimachine Multiconverter System : application for elec- tromechanical drives,” European Physic Journal – Applied Physics, vol. 10, no. 2, pp. 131-147, 2000.
  • E., Benkhoris F., “Control structures for multi-machine multi-converter systems with upstream coupling,” Elsevier, Mathematics and computers in simulation, vol. 63, pp. 261-270, 2003.
  • I. Takahachi and T. Noguchi, “A new quick-response and high-efficiency control strategy of an induction motor,” IEEE Trans. Ind. Applicat., vol. 22, no. 5, pp. 820-827, 1986.
  • T. J. Vyncke, J. A. Melkebeek, and R. K. Boel, “Direct torque control of permanent magnet synchronous motors an overview,” in conf.Proc. 3rdIEEE Benelux Young Research Symposium in Electrical Power Engineering, no. , Ghent, Begium, Apr. 27-28, p.5, 2006.
  • Y. Hori, senior member IEEE, “Future vehicles driver by electricity and control research on four wheel motored UOT electric march II,” IEEE Transactions on Industrial Electronics, vol. 51, no. 5, pp. 954 – 962, 2004.
  • A. Bouscaylor, B. Davat, B. de Fornel, B. Fra¸cois, “Multimachine Multiconverter System for drives: analysis of coupling by a global modeling,” Proc. Of IEEE-IAS, vol.3, pp.1474-1481, 2000.
  • P. Pragasen, R. Krishnan. “Modeling, Simulation, and Analysis of Permanent Magnets Motor Drives, Part I: The Permanent Magnets Synchronous Motor Drive,” IEEE Transactions on Industry Applications. Vol.25, no.2, 265-273, D.A.J. Rand, R. Woods, R.M. DELL. “Batteries for electric vehicles,” Research Studies. Press Ltd. 1997.
  • L.T. Lam, N.P. High, C.G. Phyland, A.J. Urban, Elservier, power sources, vol. 144, pp. 552-555, 2005.
  • L.T. Lam, R. Lovey, “Developpement of ultra-battery for hybrid-electric vehicle applications,” Elservier, power sources, vol. 158, pp. 1140-1148, 2006.
  • S. Kandler, C.Y. Wang, “Power and thermal characterization of Lithium-Ion battery pack for hybrid- electric vehicles,” Elservier, Power Sources, vol. 160, pp. 662-673, 2006.
  • T. Gillespice. “Fundamentals of vehicle dynamics,” Society of Automotive Engineers, ISBN 1-56091-199-9.
  • Cao, Xianqing, Zang, Chunhua, Fan, Liping, “Direct Torque Controlled Drive for Permanent Magnet Synchronous Motor Based on Neural Networks and Multi Fuzzy Controllers, ” IEEE International Conference on Robotics and Biomimetics, 2006. ROBIO ’06. pp. 197 – 201, 2006.
  • T. Chapuis, D. Roy, S. Courtine. “Commande directe du couple d’une machine asynchrone par le contrˆole direct de son flux statorique,” Journal de physique III n˚6, France, Juin 1995.
  • M. Vasudevan, R. Arumugam, “New direct torque control scheme of induction motor for electric vehicles, ” 5th Asian Control Conference, vol. 2, 20-23, pp. 1377 – 1383, 2004.