Abstract
Wheel slip control bases its effectiveness on operating in the maximum adherence zone, guaranteeing the correct handling of the vehicle. The use of brake-by-wire systems and electromechanical actuators, make possible the control of each wheel slip independently, improving the performance of braking systems. Several controllers are proposed to enhance the overall effectiveness of the braking maneuver. To do this, several reset strategies are compared: reset control with zero crossing, fixed reset band and variable reset band. The improvements achieved proceed from the betterment of the outputs of the system such as the transient time and the overshooting. The robustness of the system to changes in the friction conditions is also improved by reset control and reset bands.
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Bibliography
Johansen, T.A., Petersen, I., Kalkkuhl, J., Lüdemann, J.: Gain-scheduled wheel slip control in automotive brake systems. IEEE Trans. Control Syst. Technol. 11(6), 799–811 (2003)
De Castro, R., Araujo, R.E., Freitas, D.: Wheel slip control of EVs based on sliding mode technique with conditional integrators. IEEE Trans. Ind. Electron. 60(8), 3256–3271 (2013)
Freeman, R.: Robust Slip Control for a Single Wheel. University of California, Santa Barbara (1995)
Yu, J.: A robust adaptive wheel-slip controller for antilock brake system. In: Proceedings of the 36th IEEE Conference on Decision and Control (1997)
Yi, J., Álvarez, L., Horowitz, R., De Wit, C.C.: Adaptive emergency braking control using a dynamic tire/road friction model. In: Proceedings of the 39th IEEE Conference on Decision and Control (2000)
Lüdemann, J.: Heterogeneous and Hybrid Control with Application in Automotive Systems, University of Glasgow (2002)
Liu, Y., Sun, J.: Target slip tracking using gain-scheduling for antilock braking systems. In: Proceedings of the 1995 American Control Conference (1995)
Clegg, J.: A nonlinear integrator for servomechanisms. Trans. Am. Inst. Electr. Eng. Part II: Appl. Ind. 77(1), 41–42 (1958)
Horowitz, I.: Quantitative feedback theory. In: IEE Proceedings D Control Theory and Applications (1982)
Horowitz, I., Rosembaum, P.: Non-linear design for cost of feedback reduction in systems with large parameter uncertainty. Int. J. Control 21(6), 977–1001 (1975)
Seron, M.M., Braslavsky, J.H., Goodwin, G.C.: Fundamental Limitations in Filtering and Control. Springer Science & Business Media (2012)
Aström, K.J.: Limitations on control system performance. Eur. J. Control 6(1), 2–20 (2000)
Baños, A., Vidal, A.: Definition and tuning of a PI+CI reset controller. In: Control Conference (ECC), 2007 European (2007)
Baños, A., Barreiro, A.: Reset Control Systems. Springer Science & Business Media (2011)
Vidal, A., Baños, A.: QFT-based design of PI+CI reset compensators: application in process control. In: 16th Mediterranean Conference on Control and Automation (2008)
Vidal, A., Baños, A.: Reset compensation for temperature control: experimental application on heat exchangers. Chem. Eng. J. 159(1), 170–181 (2010)
Delgado, E., Barreiro, A., Díaz-Cacho, M., Falcón, P.: Wheel slip reset controller in automotive brake systems. In: International Electric Vehicle Conference (IEVC). IEEE, Florence, Italy (2014)
Lee, C., Hedrick, K., Yi, K.: Real-time slip-based estimation of maximum tire-road friction coefficient. IEEE/ASME Trans. Mechatron. 9(2), 454–458 (2004)
Rajamani, R., Phanomchoeng, G., Piyabongkarn, D., Lew, J.Y.: Algorithms for real-time estimation of individual wheel tire-road friction coefficients. IEEE/ASME Trans. Mechatron. 17(6), 1183–1195 (2012)
Solyom, S., Rantzer, A., Lüdemann, J.: Synthesis of a model-based tire slip controller. Veh. Syst. Dyn. 41(6), 475–499 (2004)
Pacejka, H.B., Bakker, E.: The magic formula tyre model. Veh. Syst. Dyn. 1–18 (1992)
Pacejka, H.B.: Tire and Vehicle Dynamics. Elsevier (2005)
Aström, K.J., Hägglund, T.: The future of PID control. Control Eng. Pract. 9(11), 1163–1175 (2001)
Baños, A., Vidal, A.: Design of PI+CI Reset Compensators for second order plants. In: IEEE International Symposium on Industrial Electronics (2007)
Mercader, P., Baños, A.: Robust PI compensators design for FOPDT systems with large uncertainty. In: 14th International Conference on Control, Automation and Systems (ICCAS) (2014)
Davó Navarro, M.: Analysis and Design of Reset Control Systems (2015)
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This work is supported by MINECO, Spain, under Project DPI2013-47100-C2-P.
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Cerdeira-Corujo, M., Costas, A., Delgado, E., Barreiro, A. (2017). Comparative Analysis of Gain-Scheduled Wheel Slip Reset Controllers with Different Reset Strategies in Automotive Brake Systems. In: Garrido, P., Soares, F., Moreira, A. (eds) CONTROLO 2016. Lecture Notes in Electrical Engineering, vol 402. Springer, Cham. https://doi.org/10.1007/978-3-319-43671-5_63
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DOI: https://doi.org/10.1007/978-3-319-43671-5_63
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