Control of magnetic levitation positioning stage with an eddy current damper

Wei Ming Wang; Ming Cai Shan; Shu Yuan Ma; Shui Yuan Tang

Control of magnetic levitation positioning stage with an eddy current damper

Wei Ming Wang, Ming Cai Shan, Shu Yuan Ma^*, Shui Yuan Tang

^*Corresponding author for this work

School of Mechanical Engineering

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

2 Citations (Scopus)

Abstract

To enhance the system damping, a permanent magnet set which served as an eddy current damper was added to the magnetic levitation positioning stage which consists of a moving table, four Halbach permanent magnetic arrays, four stators and displacement sensors. The dynamics model of this stage was a complex nonlinear, strong coupling system which made the control strategy to be a focus research. The nonlinear controller of the system was proposed based on the theory of differential geometry. Both simulation and experimental results show that either the decoupling control of the movement can be realized in horizontal and vertical directions, and the control performance was improved by the damper, verifying the validity and efficiency of this method.

Original language	English
Pages (from-to)	315-320
Number of pages	6
Journal	Journal of Beijing Institute of Technology (English Edition)
Volume	21
Issue number	3
Publication status	Published - Sept 2012

Keywords

Eddy current damper
Feedback linearization
Magnetic levitation (maglev) positioning stage
Nonlinear control

Cite this

@article{9f2382e1c3ef4254ab89d6d9b2ba2854,

title = "Control of magnetic levitation positioning stage with an eddy current damper",

abstract = "To enhance the system damping, a permanent magnet set which served as an eddy current damper was added to the magnetic levitation positioning stage which consists of a moving table, four Halbach permanent magnetic arrays, four stators and displacement sensors. The dynamics model of this stage was a complex nonlinear, strong coupling system which made the control strategy to be a focus research. The nonlinear controller of the system was proposed based on the theory of differential geometry. Both simulation and experimental results show that either the decoupling control of the movement can be realized in horizontal and vertical directions, and the control performance was improved by the damper, verifying the validity and efficiency of this method.",

keywords = "Eddy current damper, Feedback linearization, Magnetic levitation (maglev) positioning stage, Nonlinear control",

author = "Wang, {Wei Ming} and Shan, {Ming Cai} and Ma, {Shu Yuan} and Tang, {Shui Yuan}",

year = "2012",

month = sep,

language = "English",

volume = "21",

pages = "315--320",

journal = "Journal of Beijing Institute of Technology (English Edition)",

issn = "1004-0579",

publisher = "Beijing Institute of Technology",

number = "3",

}

TY - JOUR

T1 - Control of magnetic levitation positioning stage with an eddy current damper

AU - Wang, Wei Ming

AU - Shan, Ming Cai

AU - Ma, Shu Yuan

AU - Tang, Shui Yuan

PY - 2012/9

Y1 - 2012/9

N2 - To enhance the system damping, a permanent magnet set which served as an eddy current damper was added to the magnetic levitation positioning stage which consists of a moving table, four Halbach permanent magnetic arrays, four stators and displacement sensors. The dynamics model of this stage was a complex nonlinear, strong coupling system which made the control strategy to be a focus research. The nonlinear controller of the system was proposed based on the theory of differential geometry. Both simulation and experimental results show that either the decoupling control of the movement can be realized in horizontal and vertical directions, and the control performance was improved by the damper, verifying the validity and efficiency of this method.

AB - To enhance the system damping, a permanent magnet set which served as an eddy current damper was added to the magnetic levitation positioning stage which consists of a moving table, four Halbach permanent magnetic arrays, four stators and displacement sensors. The dynamics model of this stage was a complex nonlinear, strong coupling system which made the control strategy to be a focus research. The nonlinear controller of the system was proposed based on the theory of differential geometry. Both simulation and experimental results show that either the decoupling control of the movement can be realized in horizontal and vertical directions, and the control performance was improved by the damper, verifying the validity and efficiency of this method.

KW - Eddy current damper

KW - Feedback linearization

KW - Magnetic levitation (maglev) positioning stage

KW - Nonlinear control

UR - http://www.scopus.com/inward/record.url?scp=84868369101&partnerID=8YFLogxK

M3 - Article

AN - SCOPUS:84868369101

SN - 1004-0579

VL - 21

SP - 315

EP - 320

JO - Journal of Beijing Institute of Technology (English Edition)

JF - Journal of Beijing Institute of Technology (English Edition)

IS - 3

ER -

Control of magnetic levitation positioning stage with an eddy current damper

Abstract

Keywords

Other files and links

Fingerprint

Cite this