Active Braking of an Electronic Brake Booster Facing Intelligent Automobile

doi:10.23940/ijpe.18.08.p10.17351744

Abstract

Abstract:

In this paper, a novel electronic brake booster and an accurate pressure control method for engineering are put forward and consider the shortcomings of the existing braking system in active braking for intelligent driving. Together with the hydraulic control unit, they are comprised of two working modes: active braking for automatic drive and passive braking for driver intervention. For wheel cylinder pressure control, we translate the control problem of pressure to position tracking. The strong nonlinearity and the load-dependent friction make the position tracking control of the electro-mechanical brake booster more challenging. Consequently, a modified PI control architecture is presented with techniques of cascaded three closed loop PI controller, friction compensation based on friction model, and gain scheduling. Finally, based on dSPACE, we carried out the rapid prototyping tests of active braking and hardware in the loop tests covering full speed ACC conditions. The results show that pressure control, acceleration control, and speed control achieve optimal performance.

Submitted on May 16, 2018; Revised on June 27, 2018; Accepted on July 22, 2018
References: 14

Jian Wu, Pengcheng Chen, Jian Zhao, and Rui He. Active Braking of an Electronic Brake Booster Facing Intelligent Automobile [J]. Int J Performability Eng, 2018, 14(8): 1735-1744.

Add to citation manager EndNote|Reference Manager|ProCite|BibTeX|RefWorks

References 0

	T. Lee, T. Kim, B. Kim, and K. Yi, “Advanced Braking Algorithm for Robust Longitudinal Risk Management,” in Proceedings of the Institution of Mechanical Engineers Part D-Journal of Automobile Engineering, Vol. 230, pp. 1488-1503, 2016
	A. Forth, “Electronic Braking Systems Intelligence Service,” Aroq-Just-Auto, 2013
	B. Eichhorn, S. K?nig, and T. Ullrich, “Electronic Brake Control for Greater Active Safety,” ATZ Worldwide, Vol. 116, pp. 50-53, 2014
	S. Qi, “Research on Hybrid Brake System and its EBD/ABS Control,” 2016
	N. Willi, G. Remy, “Transmission Device and Electromotive Brake Booster,” 2015
	Continental Focuses on Faster Braking with Electrohydraulic System - SAE International (http://articles.sae.org/10757/)
	T. Oshima, N. Fujiki, S. Nakao, T. Kimura, Y. Ohtani, and K. Ueno, “Development of an Electrically Driven Intelligent Brake System,” SAE International Journal of Passenger Cars - Mechanical Systems, Vol. 4, pp. 399-405, 2011
	H. Yeo, C. Koo, W. Jung, D. Kim, and J. S. Cheon, “Development of Smart Booster Brake Systems for Regenerative Brake Cooperative Control,” in Proceedings of Conference on SAE 2011 Annual Brake Colloquium and Engineering Display, September 2011
	C. Line, C. Manzie, and M. C. Good, “Electromechanical Brake Modeling and Control: From PI to MPC,” IEEE Transactions on Control Systems Technology, Vol. 16, pp. 446-457, 2008
	H. Liu, R. He, J. Wu, W. Sun, and B. Zhu, “Linear Electro-Magnetic Valve Characteristic Analysis and Precise Pressure Control of the Electro-Hydraulic Brake System,” in Proceedings of Conference on SAE 2016 World Congress and Exhibition, 2016
	F. Todeschini, M. Corno, G. Panzani, and S. M. Savaresi, “Adaptive Position-Pressure Control of a Brake by Wire Actuator for Sport Motorcycles,” European Journal of Control, Vol. 20, pp. 79-86, 2014
	X. Feng and M. Xu, “The Applied Research of the Electric Curtain Control System based on the Fuzzy Increment PID Control Algorithm,” in Proceedings of 2016 3rd International Conference on Informative and Cybernetics for Computational Social Systems, New York, 2016
	M. Marufuzzaman, M. B. I. Reaz, F. R. Labonnah, and T. G. Chang, “High-Speed Current dq PI Controller for Vector Controlled PMSM Drive,” The Scientific World Journal, 2014
	J. Moreno-Valenzuela, Y. Quevedo-Pillado, R. Pérez-Aboytes, and L. González-Hernández, “Lyapunov-based Adaptive Control for the Permanent Magnet Synchronous Motor Driving a Robotic Load,” Journal of Circuits Systems & Computers, Vol. 26, pp. 1750168, 2017