Improving atomic force microscopy imaging by a direct inverse asymmetric PI hysteresis model

Dong Wang; Peng Yu; Feifei Wang; Ho-Yin Chan; Lei Zhou; Zaili Dong; Lianqing Liu; Wen Jung Li

doi:10.3390/s150203409

Improving atomic force microscopy imaging by a direct inverse asymmetric PI hysteresis model

Dong Wang, Peng Yu, Feifei Wang, Ho-Yin Chan, Lei Zhou, Zaili Dong, Lianqing Liu^*, Wen Jung Li^*

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

23 Citations (Scopus)

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Abstract

A modified Prandtl–Ishlinskii (PI) model, referred to as a direct inverse asymmetric PI (DIAPI) model in this paper, was implemented to reduce the displacement error between a predicted model and the actual trajectory of a piezoelectric actuator which is commonly found in AFM systems. Due to the nonlinearity of the piezoelectric actuator, the standard symmetric PI model cannot precisely describe the asymmetric motion of the actuator. In order to improve the accuracy of AFM scans, two series of slope parameters were introduced in the PI model to describe both the voltage-increase-loop (trace) and voltage-decrease-loop (retrace). A feedforward controller based on the DIAPI model was implemented to compensate hysteresis. Performance of the DIAPI model and the feedforward controller were validated by scanning micro-lenses and standard silicon grating using a custom-built AFM.

Original language	English
Pages (from-to)	3409-3425
Journal	Sensors (Switzerland)
Volume	15
Issue number	2
Online published	3 Feb 2015
DOIs	https://doi.org/10.3390/s150203409
Publication status	Published - Feb 2015

Research Keywords

Atomic force microscope
Direct inverse asymmetric PI model
Feedforward control
Hysteresis
Piezoelectric actuator

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This full text is made available under CC-BY 4.0. https://creativecommons.org/licenses/by/4.0/

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title = "Improving atomic force microscopy imaging by a direct inverse asymmetric PI hysteresis model",

abstract = "A modified Prandtl–Ishlinskii (PI) model, referred to as a direct inverse asymmetric PI (DIAPI) model in this paper, was implemented to reduce the displacement error between a predicted model and the actual trajectory of a piezoelectric actuator which is commonly found in AFM systems. Due to the nonlinearity of the piezoelectric actuator, the standard symmetric PI model cannot precisely describe the asymmetric motion of the actuator. In order to improve the accuracy of AFM scans, two series of slope parameters were introduced in the PI model to describe both the voltage-increase-loop (trace) and voltage-decrease-loop (retrace). A feedforward controller based on the DIAPI model was implemented to compensate hysteresis. Performance of the DIAPI model and the feedforward controller were validated by scanning micro-lenses and standard silicon grating using a custom-built AFM.",

keywords = "Atomic force microscope, Direct inverse asymmetric PI model, Feedforward control, Hysteresis, Piezoelectric actuator",

author = "Dong Wang and Peng Yu and Feifei Wang and Ho-Yin Chan and Lei Zhou and Zaili Dong and Lianqing Liu and Li, {Wen Jung}",

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AU - Wang, Dong

AU - Yu, Peng

AU - Wang, Feifei

AU - Chan, Ho-Yin

AU - Zhou, Lei

AU - Dong, Zaili

AU - Liu, Lianqing

AU - Li, Wen Jung

PY - 2015/2

Y1 - 2015/2

N2 - A modified Prandtl–Ishlinskii (PI) model, referred to as a direct inverse asymmetric PI (DIAPI) model in this paper, was implemented to reduce the displacement error between a predicted model and the actual trajectory of a piezoelectric actuator which is commonly found in AFM systems. Due to the nonlinearity of the piezoelectric actuator, the standard symmetric PI model cannot precisely describe the asymmetric motion of the actuator. In order to improve the accuracy of AFM scans, two series of slope parameters were introduced in the PI model to describe both the voltage-increase-loop (trace) and voltage-decrease-loop (retrace). A feedforward controller based on the DIAPI model was implemented to compensate hysteresis. Performance of the DIAPI model and the feedforward controller were validated by scanning micro-lenses and standard silicon grating using a custom-built AFM.

AB - A modified Prandtl–Ishlinskii (PI) model, referred to as a direct inverse asymmetric PI (DIAPI) model in this paper, was implemented to reduce the displacement error between a predicted model and the actual trajectory of a piezoelectric actuator which is commonly found in AFM systems. Due to the nonlinearity of the piezoelectric actuator, the standard symmetric PI model cannot precisely describe the asymmetric motion of the actuator. In order to improve the accuracy of AFM scans, two series of slope parameters were introduced in the PI model to describe both the voltage-increase-loop (trace) and voltage-decrease-loop (retrace). A feedforward controller based on the DIAPI model was implemented to compensate hysteresis. Performance of the DIAPI model and the feedforward controller were validated by scanning micro-lenses and standard silicon grating using a custom-built AFM.

KW - Atomic force microscope

KW - Direct inverse asymmetric PI model

KW - Feedforward control

KW - Hysteresis

KW - Piezoelectric actuator

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M3 - RGC 21 - Publication in refereed journal

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JO - Sensors (Switzerland)

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Improving atomic force microscopy imaging by a direct inverse asymmetric PI hysteresis model

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Research Keywords

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