Ferromagnetic shape memory alloy actuator enabled for nanometric position control using hysteresis compensation

► A commercial FSMA actuator is enabled for nano-positioning using feedback control. ► The characterization of actuator's response highlights the challenges of the work. ► Position accuracies down to ±25nm are achieved. ► A hysteresis compensation strategy improves reliability and performance....

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Published inSensors and actuators. A. Physical. Vol. 182; pp. 122 - 129
Main Authors Sadeghzadeh, Atefeh, Asua, Estibalitz, Feuchtwanger, Jorge, Etxebarria, Victor, García-Arribas, Alfredo
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.08.2012
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Summary:► A commercial FSMA actuator is enabled for nano-positioning using feedback control. ► The characterization of actuator's response highlights the challenges of the work. ► Position accuracies down to ±25nm are achieved. ► A hysteresis compensation strategy improves reliability and performance. Ferromagnetic shape memory alloys (FSMA) are a special type of smart materials that change their shape under an applied magnetic field. They present attractive properties for precise positioning systems because the magnetic-induced response is fast and can produce large movements, with the additional advantage of non-contact operation. Their usability is limited by the poor reproducibility of their response to a given stimulus. This is a consequence of the stochastic microscopic processes that produce their macroscopic deformation and, most of all, of the great hysteresis displayed in cyclic operation. Suitable feedback control can overcome that limitation. In this work we show how a commercial FSMA actuator, manufactured by AdaptaMat Ltd., can be enabled for accurate and efficient nanopositioning by adequate control of the drive signal. First, an exhaustive series of tests are described that thoroughly characterize the open-loop response of the actuator: maximum displacement range, hysteresis and repeatability under different drive current amplitudes and frequencies. Second, different feedback control schemes are tested, based on an ordinary Proportional–Integral–Derivative (PID) controller modified with a gain scheduling strategy that helps accounting for the nonlinearity of the system, adjusting the operation of the controller according to the actuation requirements. The positioning accuracy achieved at this stage is about 25nm, which is close to the detection limit of the capacitive sensor used for measurement and feedback. Finally, a method to compensate the intrinsic hysteresis of the system is implemented and included in the control strategy. The partial cancellation of the system nonlinearities allows for the best performance, considerably reducing the control effort, and improving the transient time and overshoot.
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ISSN:0924-4247
1873-3069
DOI:10.1016/j.sna.2012.05.029