Abstract
The purpose of this study is to achieve high-precision and high-bandwidth reference tracking control for an electric hydrostatic actuator (EHA). First, the pole placement method and the zero placement method were used to design a reference input tracking controller consisting of a PI-D controller and a feed-forward controller for the EHA-driven system. The feed-forward controller exhibited a high gain symptom in the frequency response as the actuation frequency of the system increased. An input shaping filter (ISF) with the style of a lag compensator was incorporated into the control system to suppress the increase in the control gain in the high-frequency range. The effectiveness of the proposed control system was evaluated by conducting experiments. The results indicate that the application of the proposed control system, including the ISF, can greatly improve the reference tracking control performance of the EHA-driven system. In addition, the proposed control system using the ISF is stable with a sufficient margin for a broad frequency range.
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References
Habibi, S., Goldenberg, A.: Design of a new high performance electrohydraulic actuator. In: International Conference on Advanced Intelligent Mechatronics Proceedings, vol. 9, pp. 227–232 (1999)
Habibi, S., Singh, G.: Derivation of design requirements for optimization of a high performance hydrostatic actuation system. Int. J. Fluid Power 1(2), 11–27 (2000)
Sampson, E., Habibi, S., Burton, R., Chinniah, Y.: Effect of controller in reducing steady-state error due to flow and force disturbances in the electrohydraulic actuator system. Int. J. Fluid Power 5(2), 57–66 (2004)
Nakkarat, P., Kuntanapreeda, S.: Obser-based backstepping force control of an electrohydraulic actuator. Control Eng. Pract. 17(8), 895–902 (2009)
Truong, D.Q., Ahn, K.K.: Force control for press machines using an online smart tuning fuzzy PID based on a robust extended Kalman filter. Exp. Syst. Appl. 38(5), 5879–5894 (2011)
Cho, S.H., Burton, R.: Position control of high performance hydrostatic actuation system using a simple adaptive control (SAC) method. Mechatronics 21(1), 109–115 (2011)
Lin, Y., Shi, Y., Burton, R.: Modeling and robust discrete-time sliding-mode control design for a fluid power electrohydraulic actuator (EHA) system. Mechatronics 18(1), 1–10 (2013)
Choi, J.J.: Robust position control of electro-hydrostatic actuator systems with radial basis function neural networks. J. Adv. Mech. Des. Syst. Manufact. 7(2), 257–267 (2013)
Gadsden, S.A., Song, Y., Habibi, S.: Novel model-based estimators for the purposes of fault detection and diagnosis. Mechatronics 18(4), 1237–1249 (2013)
Ogata, K.: Modern Control Engineering, 4th edn, pp. 706–724. Prentice Hall, Englewood Cliffs (2002)
Suda, N.: PID Control, pp. 88–93. Asakurashoten, Tokyo (2000). (in Japanese)
Lee, I., Oh, D., Ji, S., Yun, S.: Control of an overlap-type proportional directional control valve using input shaping filter. Mechatronics 29, 87–95 (2015)
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Kim, Hh., Lee, Iy., Huh, Jy. (2017). High-Bandwidth Tracking Control of Electric Hydrostatic Actuator (EHA) Using an Input Shaping Filter. In: Duy, V., Dao, T., Kim, S., Tien, N., Zelinka, I. (eds) AETA 2016: Recent Advances in Electrical Engineering and Related Sciences. AETA 2016. Lecture Notes in Electrical Engineering, vol 415. Springer, Cham. https://doi.org/10.1007/978-3-319-50904-4_10
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DOI: https://doi.org/10.1007/978-3-319-50904-4_10
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