A Pole-Placement-Based Variable-Gain Observer for Precision Motion Stages: Addressing the Disturbance-Noise Trade-Off

Aichen Wu; Xipeng Wu; Fazhi Song; Pengyu Sun; Jiubin Tan

doi:10.3390/act15020100

A Pole-Placement-Based Variable-Gain Observer for Precision Motion Stages: Addressing the Disturbance-Noise Trade-Off

Aichen Wu
, Xipeng Wu
, Fazhi Song^*
, Pengyu Sun
, Jiubin Tan

^*Corresponding author for this work

School of Instrumentation Science and Engineering

Harbin Institute of Technology
Ministry of Industry and Information Technology

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

Abstract

Accurate pattern transfer in the lithography process demands extreme positioning accuracy. However, various external disturbances acting on the wafer stage can lead to positioning errors. To address this issue, this paper proposes a pole-placement-based Variable-Gain Extended State Observer (VGESO). First, the trade-off between disturbance rejection and noise attenuation faced by conventional Extended State Observers (ESOs) in precision motion systems is analyzed. Then, a modified ESO structure is introduced, in which two pole-related parameters are employed to adaptively adjust the observer gains. These parameters enable effective suppression of both low-frequency disturbances and high-frequency measurement noise within their designated ranges. Finally, simulation results verify the effectiveness and superior performance of the proposed method.

Original language	English
Article number	100
Journal	Actuators
Volume	15
Issue number	2
DOIs	https://doi.org/10.3390/act15020100
State	Published - Feb 2026

Keywords

motion control
precision positioning
variable-gain observer
wafer stage

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10.3390/act15020100

Cite this

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title = "A Pole-Placement-Based Variable-Gain Observer for Precision Motion Stages: Addressing the Disturbance-Noise Trade-Off",

abstract = "Accurate pattern transfer in the lithography process demands extreme positioning accuracy. However, various external disturbances acting on the wafer stage can lead to positioning errors. To address this issue, this paper proposes a pole-placement-based Variable-Gain Extended State Observer (VGESO). First, the trade-off between disturbance rejection and noise attenuation faced by conventional Extended State Observers (ESOs) in precision motion systems is analyzed. Then, a modified ESO structure is introduced, in which two pole-related parameters are employed to adaptively adjust the observer gains. These parameters enable effective suppression of both low-frequency disturbances and high-frequency measurement noise within their designated ranges. Finally, simulation results verify the effectiveness and superior performance of the proposed method.",

keywords = "motion control, precision positioning, variable-gain observer, wafer stage",

author = "Aichen Wu and Xipeng Wu and Fazhi Song and Pengyu Sun and Jiubin Tan",

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TY - JOUR

T1 - A Pole-Placement-Based Variable-Gain Observer for Precision Motion Stages

T2 - Addressing the Disturbance-Noise Trade-Off

AU - Wu, Aichen

AU - Wu, Xipeng

AU - Song, Fazhi

AU - Sun, Pengyu

AU - Tan, Jiubin

PY - 2026/2

Y1 - 2026/2

N2 - Accurate pattern transfer in the lithography process demands extreme positioning accuracy. However, various external disturbances acting on the wafer stage can lead to positioning errors. To address this issue, this paper proposes a pole-placement-based Variable-Gain Extended State Observer (VGESO). First, the trade-off between disturbance rejection and noise attenuation faced by conventional Extended State Observers (ESOs) in precision motion systems is analyzed. Then, a modified ESO structure is introduced, in which two pole-related parameters are employed to adaptively adjust the observer gains. These parameters enable effective suppression of both low-frequency disturbances and high-frequency measurement noise within their designated ranges. Finally, simulation results verify the effectiveness and superior performance of the proposed method.

AB - Accurate pattern transfer in the lithography process demands extreme positioning accuracy. However, various external disturbances acting on the wafer stage can lead to positioning errors. To address this issue, this paper proposes a pole-placement-based Variable-Gain Extended State Observer (VGESO). First, the trade-off between disturbance rejection and noise attenuation faced by conventional Extended State Observers (ESOs) in precision motion systems is analyzed. Then, a modified ESO structure is introduced, in which two pole-related parameters are employed to adaptively adjust the observer gains. These parameters enable effective suppression of both low-frequency disturbances and high-frequency measurement noise within their designated ranges. Finally, simulation results verify the effectiveness and superior performance of the proposed method.

KW - motion control

KW - precision positioning

KW - variable-gain observer

KW - wafer stage

UR - https://www.scopus.com/pages/publications/105031294465

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DO - 10.3390/act15020100

M3 - 文章

AN - SCOPUS:105031294465

SN - 2076-0825

VL - 15

JO - Actuators

JF - Actuators

IS - 2

M1 - 100

ER -

A Pole-Placement-Based Variable-Gain Observer for Precision Motion Stages: Addressing the Disturbance-Noise Trade-Off

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