Hysteresis compensation in GMA actuators using Duhem model

Giant magnetostrictive material (GMM) is gathering more interests due to its superior electromechanical properties. Though the strain of GMM is almost larger than PZT, it still needs to be amplified to match practical demands. A press-bend amplification based giant magnetostrictive actuator (GMA) is...

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Hauptverfasser:	Xingsong Wang, Xiangjiang Wang, Yan Mao
Format:	Tagungsbericht
Sprache:	eng
Schlagworte:	Actuators Adaptation model Compensation Duhem Model Equations GMA Hyateresis Hysteresis Magnetic hysteresis Mathematical model Robustness
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creator	Xingsong Wang Xiangjiang Wang Yan Mao
description	Giant magnetostrictive material (GMM) is gathering more interests due to its superior electromechanical properties. Though the strain of GMM is almost larger than PZT, it still needs to be amplified to match practical demands. A press-bend amplification based giant magnetostrictive actuator (GMA) is designed and the electromechanical system model is presented. The dynamic model consists of two subsystems, one is a rate-independent hysteretic model and the other is a linear transfer function. The Duhem hysteresis model was employed for analyzing of the hysteresis phenomena in the GMA. Based on thoroughly discussion of the properties of Duhem model, an adaptive variable structure controller was designed, which guaranteed global stability of the control system with certain accuracy of tracking desired trajectories. Both simulation and experiment results verified the effectiveness of the proposed electromechanical model and the applicable of the extracted control method.
doi_str_mv	10.1109/WCICA.2008.4594431
format	Conference Proceeding
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Though the strain of GMM is almost larger than PZT, it still needs to be amplified to match practical demands. A press-bend amplification based giant magnetostrictive actuator (GMA) is designed and the electromechanical system model is presented. The dynamic model consists of two subsystems, one is a rate-independent hysteretic model and the other is a linear transfer function. The Duhem hysteresis model was employed for analyzing of the hysteresis phenomena in the GMA. Based on thoroughly discussion of the properties of Duhem model, an adaptive variable structure controller was designed, which guaranteed global stability of the control system with certain accuracy of tracking desired trajectories. 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Though the strain of GMM is almost larger than PZT, it still needs to be amplified to match practical demands. A press-bend amplification based giant magnetostrictive actuator (GMA) is designed and the electromechanical system model is presented. The dynamic model consists of two subsystems, one is a rate-independent hysteretic model and the other is a linear transfer function. The Duhem hysteresis model was employed for analyzing of the hysteresis phenomena in the GMA. Based on thoroughly discussion of the properties of Duhem model, an adaptive variable structure controller was designed, which guaranteed global stability of the control system with certain accuracy of tracking desired trajectories. 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Though the strain of GMM is almost larger than PZT, it still needs to be amplified to match practical demands. A press-bend amplification based giant magnetostrictive actuator (GMA) is designed and the electromechanical system model is presented. The dynamic model consists of two subsystems, one is a rate-independent hysteretic model and the other is a linear transfer function. The Duhem hysteresis model was employed for analyzing of the hysteresis phenomena in the GMA. Based on thoroughly discussion of the properties of Duhem model, an adaptive variable structure controller was designed, which guaranteed global stability of the control system with certain accuracy of tracking desired trajectories. Both simulation and experiment results verified the effectiveness of the proposed electromechanical model and the applicable of the extracted control method.</abstract><pub>IEEE</pub><doi>10.1109/WCICA.2008.4594431</doi><tpages>6</tpages></addata></record>
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subjects	Actuators Adaptation model Compensation Duhem Model Equations GMA Hyateresis Hysteresis Magnetic hysteresis Mathematical model Robustness
title	Hysteresis compensation in GMA actuators using Duhem model
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