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Design of an Optimal Fuzzy Controller for Antilock Braking Systems

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4 Author(s)
Mirzaei, A. ; Dept. of Electr. & Comput. Eng., Isfahan Univ. of Technol. ; Moallem, M. ; Dehkordi, B.M. ; Fahimi, B.

Antilock braking systems (ABSs) have been developed to improve vehicle control during sudden braking, especially on slippery road surfaces. The objective of such control is to increase wheel traction force in the desired direction while maintaining adequate vehicle stability and steerability and reducing the vehicle stopping distance. In this paper, an optimized fuzzy controller is proposed for ABSs. The objective function is defined to maintain the wheel slip to a desired level so that maximum wheel traction force and maximum vehicle deceleration are obtained. All the components of a fuzzy system are optimized using genetic algorithms. The error-based global optimization approach is used for fast convergence near the optimum point. Simulation results show fast convergence and good performance of the controller for different road conditions

Published in:

Vehicular Technology, IEEE Transactions on  (Volume:55 ,  Issue: 6 )