A complete study of the development of a nonlinear backstepping controller for an electrohydraulic servo system is shown in this paper. The authors present an optimized nonlinear mathematical model used as fundamental for computer simulation. A proposed nonlinear controller is suitable for research of behavior of the complete system in control. Special attention is paid to the selection of tuning parameters. Using the experience of earlier studies of the state-space controller where the additional feedback signals such as velocity and acceleration signal increase the frequency and damping factor of the system, the results were proved by computer simulation. The results show that by appropriate selection of tuning parameters the system can achieve the best reference signal tracking performance with a small tracking error. The proposed approach seems to be adequate not only for step reference signals but also for ramp and sinusoidal reference signals. However, the parameters of the backstepping controller can be optimized manually to achieve the best results required.

Khalil, H.K., 2009, Interactive analysis of closed-loop electro-hydraulic control systems, 13th International Conference on Aerospace Scienties & Aviation Technology, ASAT-13-HC-01.

Kovari, A., 2015, Effect of Leakage in Electrohydraulic Servo Systems Based on Complex Nonlinear Mathematical Model and Experimental Results, Acta Polytechnica Hungarica, 12(3), pp. 129-146.

Rozali, S.Md., Rahmat, M.F., Rashid Husain, A., 2012, Backstepping design for position tracking control of nonlinear System, IEEE International Conference on Control System, Computing and Engineering, pp. 77-82.

Kadissi, C., Kenne, J.P., Saad, M., 2007, Identification and Real-Time Control of an Electrohydraulic Servo System Based on Nonlinear Backstepping, IEEE/ASME Transactions on Mechatronics , 12(1), pp. 12-22.

Lovrec, D., Tašner, T., Tič, V., 2017, Dynamic behaviour of different hydraulic drive concepts - comparison and limits, International journal of simulation modelling, 16(3), pp. 448-457.

Tič, V., Rotovnik, A., Lovrec, D., 2021, Impact of proportional valves´ differences to ensure uniform motion of hydraulic motors, International journal of simulation modelling, 20(1), pp. 52-63.

Detiček, E., Gubeljak, N., Kastrevc, M., 2017, Design of Lyapunov based nonlinear velocity control of electrohydraulic velocity servo systems, Technical Gazette, 24(3), pp. 745-751.

Lovrec, D., Tic, V., Tasner, T., 2015, Simulation-aided determination of an efficiency field as a basis for maximum efficiency controller design, International Journal of Simulation Modelling, 14(4), pp. 669-682.

Detiček, E., Kastrevc, M., 2016, Design of Lyapunov based nonlinear position control of electrohydraulic servo systems. Strojniški vestnik, 62(3), pp. 163-170.

Kastrevc, M., Detiček, E., 2017, The nonlinear mathematical model of electrohydraulic position servo system, Conference proceedings, 1st ed. Maribor, University of Maribor Press, pp. 163-173.

Detiček, E., Kastrevc, M., 2017, Nonlinear position control of electrohydraulic servo system, Conference proceedings, 1st ed. Maribor, University of Maribor Press, pp. 73-83.

Kristic, M., Kanellakopouls, I., Kokotovic, P.V., 1995, Nonlinear and Adaptive Control Design, John Wiley and Sons Hoboken.

Khalil, H. K., 2002, Nonlinear Systems, 3rd ed., Prentice Hall, Upper Saddle River.

Lee, S. J., Tsao, T.-C., 2002, Nonlinear backstepping control of an electrohydraulic material testing system, Proceedings of the American Control Conference, vol. 6, pp. 4852-4830.

Ursu, I., Ursu, F., Popescu, F., 2006,. Backstepping design for controlling electrohydraulic servos, Journal of the Franklin Institute, 343(1), pp. 94-110.

Bonchis, A., Corke, P.I., Rye, D.C., Ha, Q.P., 2001, Variable structure methods in hydraulic servo systems control, Automatica, 37(4), pp. 589–595.

Nakkarat, P., Kuntanapreeda, S., 2009, Observer-based backstepping force control of an electrohydraulic actuator, Control Engineering Practice, 17(8), pp. 895-902.

Sun, W., Gao, H., Kaynak, O., 2013, Adaptive Backstepping Control for Active Suspension Systems With Hard Constraints, IEEE/ASME Transactions on Mechatronics, 18(3), pp. 1072-1079.

Wonohadidjojo, D.M., Kothapalli, G., Hassan, M.Y., 2013, Position Control of Electro-hydraulic Actuator System Using Fuzzy Logic Controller Optimized by Particle Swarm Optimization, International Journal of Automation and Computing, 10(3), pp. 181-193.

Wright, H., Alleyne, A., Liu, R., 1997, On the stability and performance of two-state hydraulic servovalves, Proceedings of the ASME Dynamic Systems and Control Division, 63, pp. 215-222.

Jelali, M., Kroll, A., 2003, Hydraulic Servo-systems:modelling, identification and control, Springer –Verlag, London, Berlin, Heidelberg.

MOOG. Servovalves with Integrated Electronics D769 Series. Rapport technique, MOOG Inc.

Mavrinac, M., Lorencin, I., Car, Z., Šercer, M., 2022, Genetic Algorithm-Based Parametrization of a PI Controller for DC Motor Control, Technical Gazette, 16(1), pp.16-22.

Pingale, R., Shinde, S.N., 2021, Fuzzy Logic Approach for Routing in Internet of Things Network, Technical Gazette, 15(1), pp. 18-24.