Compensating hysteresis and mechanical misalignment in piezo-stepper actuators

Max van Meer; Tim van Meijel; Emile van Halsema; Edwin Verschueren; Gert Witvoet; Tom Oomen

doi:10.1016/j.mechatronics.2025.103394

Compensating hysteresis and mechanical misalignment in piezo-stepper actuators

Max van Meer (Corresponding author)
, Tim van Meijel
, Emile van Halsema
, Edwin Verschueren
, Gert Witvoet
, Tom Oomen

Research output: Contribution to journal › Article › Academic › peer-review

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Abstract

Piezo-stepper actuators enable accurate positioning through the sequential contraction and expansion of piezoelectric elements, generating a walking motion. The aim of this paper is to reduce velocity ripples caused by parasitic effects, due to hysteresis in the piezoelectric material and mechanical misalignments, through suitable feedforward control. The presented approach involves the integration of a rate-dependent hysteresis model with a position-dependent feedforward learning scheme to compensate for these effects. Experimental results show that this approach leads to a significant reduction in the velocity ripples, even when the target velocity is changed. These results enable the use of piezo-stepper actuators in applications requiring high positioning accuracy and stiffness over a long stroke, without requiring expensive position sensors for high-gain feedback.

Original language	English
Article number	103394
Number of pages	13
Journal	Mechatronics
Volume	111
Early online date	13 Aug 2025
DOIs	https://doi.org/10.1016/j.mechatronics.2025.103394
Publication status	Published - Nov 2025

Bibliographical note

Publisher Copyright:
© 2025 The Authors

Keywords

Feedforward control
Hysteresis
Iterative learning control
Piezo actuators

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10.1016/j.mechatronics.2025.103394

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title = "Compensating hysteresis and mechanical misalignment in piezo-stepper actuators",

abstract = "Piezo-stepper actuators enable accurate positioning through the sequential contraction and expansion of piezoelectric elements, generating a walking motion. The aim of this paper is to reduce velocity ripples caused by parasitic effects, due to hysteresis in the piezoelectric material and mechanical misalignments, through suitable feedforward control. The presented approach involves the integration of a rate-dependent hysteresis model with a position-dependent feedforward learning scheme to compensate for these effects. Experimental results show that this approach leads to a significant reduction in the velocity ripples, even when the target velocity is changed. These results enable the use of piezo-stepper actuators in applications requiring high positioning accuracy and stiffness over a long stroke, without requiring expensive position sensors for high-gain feedback.",

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AU - van Meer, Max

AU - van Meijel, Tim

AU - van Halsema, Emile

AU - Verschueren, Edwin

AU - Witvoet, Gert

AU - Oomen, Tom

PY - 2025/11

Y1 - 2025/11

N2 - Piezo-stepper actuators enable accurate positioning through the sequential contraction and expansion of piezoelectric elements, generating a walking motion. The aim of this paper is to reduce velocity ripples caused by parasitic effects, due to hysteresis in the piezoelectric material and mechanical misalignments, through suitable feedforward control. The presented approach involves the integration of a rate-dependent hysteresis model with a position-dependent feedforward learning scheme to compensate for these effects. Experimental results show that this approach leads to a significant reduction in the velocity ripples, even when the target velocity is changed. These results enable the use of piezo-stepper actuators in applications requiring high positioning accuracy and stiffness over a long stroke, without requiring expensive position sensors for high-gain feedback.

AB - Piezo-stepper actuators enable accurate positioning through the sequential contraction and expansion of piezoelectric elements, generating a walking motion. The aim of this paper is to reduce velocity ripples caused by parasitic effects, due to hysteresis in the piezoelectric material and mechanical misalignments, through suitable feedforward control. The presented approach involves the integration of a rate-dependent hysteresis model with a position-dependent feedforward learning scheme to compensate for these effects. Experimental results show that this approach leads to a significant reduction in the velocity ripples, even when the target velocity is changed. These results enable the use of piezo-stepper actuators in applications requiring high positioning accuracy and stiffness over a long stroke, without requiring expensive position sensors for high-gain feedback.

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JO - Mechatronics

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Compensating hysteresis and mechanical misalignment in piezo-stepper actuators

Abstract

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