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A Study on an Independent 6WD/6WS of Electric Vehicle using Optimum Tire Force Distribution

최적 타이어 힘 분배 방법을 통한 전기차의 독립 6WD/6WS에 관한 연구

  • Received : 2010.03.15
  • Accepted : 2010.04.30
  • Published : 2010.07.01

Abstract

This paper presents an optimum tire force distribution method for 6WD/6WS(6-Wheel-Drive and 6-Wheel-Steering) electric vehicles. Using an independent steering and driving system, the performance of 6WD/6WS vehicles can be improved, as, for example, with respect to their maneuverability under low speed and their stability at high speed. Therefore, there should be a control strategy for finding the optimum tire forces that satisfy the driver's command and minimize energy consumption. From the driver's commands (steering angle and accelerator/brake pedal stroke), the desired yaw moment, the desired lateral force, and the desired longitudinal force were obtained. These three values were distributed to each wheel as the torque and the steering angle, based on the optimum tire force distribution method. The optimum tire force distribution method finds the longitudinal/lateral tire forces of each wheel that minimize the cost function, which is the sum of the normalized tire forces. Next, the longitudinal/lateral tire forces of each wheel are converted into the reference torque inputs and the steering wheel angle inputs. The proposed method was tested through a simulation, and its effectiveness was verified.

Keywords

References

  1. Y. Hori, Y. Toyoda, and Y. Tsuruoka, "Traction control of electric vehicle: Basic experimental results using the test EV, UOT," IEEE Trans. Ind. Applicat., vol. 34, pp. 1131-1138, 1998. https://doi.org/10.1109/28.720454
  2. K. Watanabe, J. Yamakawa, M. Tanaka, and T. Sasaki, "Turning characteristics of multi-axle vehicles," Journal of Terramechanics, vol. 44, pp. 81-87, 2007. https://doi.org/10.1016/j.jterra.2006.01.007
  3. O. Mokhiamar and M. Abe, "Simultaneous optimal distribution of lateral and longitudinal tire forces for the model following control," Journal of Dynamic Systems, Measurement, and Control, vol. 126, pp. 753-763, 2004. https://doi.org/10.1115/1.1850533
  4. J. Kang, W. Kim, K. Yi, and S. Jung, "Skid steering based maneuvering of robotic vehicle with articulated suspension," SAE International Journal of Passenger Gars-Mechanical Systems, vol. 2, no. 1, pp. 645-652, Oct. 2009. https://doi.org/10.4271/2009-01-0437
  5. M. Young, The Technical Writer's Handbook, Mill Valley, Seoul, 1989.
  6. 미안 아시팍 알리, 김창준, 신현수, 장재호, 한창수, "Study on the Characteristics of Skid Steering for Six Wheel Drive Vehicle (6x6)," 한국자동차 공학회 추계 학술대회, pp. 325, 2008.
  7. T. D. Gillespie, Fundamentals of Vehicle Dynamics, SAE, 2009- 01-0437, 2009.
  8. H. Fujimoto, T. Saito, A. Tsumasaka, and T. Noguchi, "Motion control and road condition estimation of electric vehicles with two in-wheel motors," Proc. of IEEE Int. Conference on Control Applications, pp. 1266-1271, 2004.
  9. N. Ando and H. Fujimoto, "Fundamental study of integrated control for active front/rear steering and driving/braking force distribution based on least square solution of electric vehicle," Proc. of IEE of Japan, IIC-09-139, 2008 (in Japanese).

Cited by

  1. A Study on Independent Steering & Driving Control Algorithm for 6WS/6WD Vehicle vol.17, pp.4, 2011, https://doi.org/10.5302/J.ICROS.2011.17.4.313