Active disturbance rejection position control for a magnetic rodless pneumatic cylinder

Ling Zhao; Yafei Yang; Yuanqing Xia; Zhixin Liu

doi:10.1109/TIE.2015.2418319

Active disturbance rejection position control for a magnetic rodless pneumatic cylinder

Ling Zhao
, Yafei Yang
, Yuanqing Xia
, Zhixin Liu

School of Automation

Yanshan University

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

130 Citations (Scopus)

Abstract

This paper presents an active disturbance rejection position control scheme for a magnetic rodless cylinder in servo systems without pressure states. It is very hard to achieve precise position control of magnetic rodless cylinders due to nonlinearity from large friction force and hysteresis. In this paper, the overshoot, which has a negative influence on position control, is effectively reduced by using a tracking differentiator. Furthermore, the nonlinearity is estimated by a designed extended-state observer. In addition, the self-stable region theory is used to prove the convergence of the extended-state observer. Finally, both control precision and response speed are guaranteed via a nonlinear error feedback controller in the pneumatic system. Experimental results show that the steady-state error within 0.05 mm is achieved for a step signal.

Original language	English
Article number	7076607
Pages (from-to)	5838-5846
Number of pages	9
Journal	IEEE Transactions on Industrial Electronics
Volume	62
Issue number	9
DOIs	https://doi.org/10.1109/TIE.2015.2418319
Publication status	Published - 1 Sept 2015

Keywords

Magnetic rodless pneumatic cylinder
active disturbance rejection control
positioning control
self-stable region

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10.1109/TIE.2015.2418319

Cite this

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title = "Active disturbance rejection position control for a magnetic rodless pneumatic cylinder",

abstract = "This paper presents an active disturbance rejection position control scheme for a magnetic rodless cylinder in servo systems without pressure states. It is very hard to achieve precise position control of magnetic rodless cylinders due to nonlinearity from large friction force and hysteresis. In this paper, the overshoot, which has a negative influence on position control, is effectively reduced by using a tracking differentiator. Furthermore, the nonlinearity is estimated by a designed extended-state observer. In addition, the self-stable region theory is used to prove the convergence of the extended-state observer. Finally, both control precision and response speed are guaranteed via a nonlinear error feedback controller in the pneumatic system. Experimental results show that the steady-state error within 0.05 mm is achieved for a step signal.",

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AU - Zhao, Ling

AU - Yang, Yafei

AU - Xia, Yuanqing

AU - Liu, Zhixin

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Y1 - 2015/9/1

N2 - This paper presents an active disturbance rejection position control scheme for a magnetic rodless cylinder in servo systems without pressure states. It is very hard to achieve precise position control of magnetic rodless cylinders due to nonlinearity from large friction force and hysteresis. In this paper, the overshoot, which has a negative influence on position control, is effectively reduced by using a tracking differentiator. Furthermore, the nonlinearity is estimated by a designed extended-state observer. In addition, the self-stable region theory is used to prove the convergence of the extended-state observer. Finally, both control precision and response speed are guaranteed via a nonlinear error feedback controller in the pneumatic system. Experimental results show that the steady-state error within 0.05 mm is achieved for a step signal.

AB - This paper presents an active disturbance rejection position control scheme for a magnetic rodless cylinder in servo systems without pressure states. It is very hard to achieve precise position control of magnetic rodless cylinders due to nonlinearity from large friction force and hysteresis. In this paper, the overshoot, which has a negative influence on position control, is effectively reduced by using a tracking differentiator. Furthermore, the nonlinearity is estimated by a designed extended-state observer. In addition, the self-stable region theory is used to prove the convergence of the extended-state observer. Finally, both control precision and response speed are guaranteed via a nonlinear error feedback controller in the pneumatic system. Experimental results show that the steady-state error within 0.05 mm is achieved for a step signal.

KW - Magnetic rodless pneumatic cylinder

KW - active disturbance rejection control

KW - positioning control

KW - self-stable region

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Active disturbance rejection position control for a magnetic rodless pneumatic cylinder

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