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Abstract

This paper presents shear stress tracking control of an electrorheological (ER) fluid actuator subjected to the hysteresis non-linearity. As a first step, polymethylaniline (PMA) particles are prepared and mixed with silicone oil to make an ER fluid. The Couette-type electroviscometer is employed to achieve the field-dependent shear stress. The Preisach model for the PMA-based ER fluid is identified using experimental first-order descending (FOD) curves. A compensation strategy is then formulated in a discrete manner through the Preisach model inversion to achieve the desired shear stress of the ER fluid. A proportional-intergal-derivative (PID) feedback controller is also integrated with the compensator in order to guarantee control robustness to uncertainty due to temperature-dependent hysteresis variation. The tracking performance of the control strategy is experimentally evaluated for two different desired shear stress trajectories.

Keywords

electrorheological fluid polymethylaniline hysteresis variation shear stress tracking inverse Preisach model PID controller

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References

Choi

S. B.

Lee

C. H.

Force tracking control of a flexible gripper driven by a piezoceramic actuator. Trans. ASME, J. Dynamic Systems, Measmt, and Control, 1997, 119(3), 439–446.

Mittal

Menq

C. H.

Hysteresis compensation in electromagnetic actuators through Preisach model inversion. IEEE/ASME Trans. Mechatronics, 2000, 5(4), 394–409.

Song

J. C.

Modeling of piezo actuator's nonlinear and frequency dependent dynamics. Mechatronics, 1999, 391–410.

Hughes

Wen

J. T.

Preisach modeling of piezo-ceramic and shape memory alloy hysteresis. In Proceedings of the IEEE Control Conference on Application, Albany, New York, 1994, pp. 1086–1091.

Gorbet

R. B.

Wang

D. W.

Morris

K. A.

Preisach model identification of a two-wire SMA actuator. In Proceedings of the IEEE International Conference on Robotics and Automation, Leuben, Belgium, 1998, pp. 2161–2167.

Jouaneh

Generalized Preisach model for hysteresis nonlinearity of piezoceramic actuators. Precision Engng, 1997, 20, 99–111.

Choi

H. J.

Cho

M. S.

Jhon

M. S.

Hysteresis behaviors of poly(naphthalene quinone) radical electro-rheological fluid. In Proceedings of the 6th International Conference on Electro-Rheolocical Fluids, Magneto-Rheological Suspensions and Their Applications, Yonezawa, Japan, 1997, pp. 271–277.

Kamath

G. M.

Wereley

N. M.

A nonlinear viscoelastic-plastic model for electrorheological fluids. Smart Mater. Structs, 1997, 6(3), 351–359.

Stanway

Sproston

J. L.

Stevens

N. G.

Non-linear modeling of an electro-rheological vibration damper. J. Electrostatics, 1987, 20(2), 167–184.

10.

Spencer

B. F.

Jr. Dyke

S. J.

Sain

M. K.

Carlson

J. D.

Phenomenological model for a magnetorheological damper. ASCE J. Engng Mechanics, 1997, 123(3), 230–238.

11.

Kamath

G. M.

Wereley

N. M.

Nonlinear viscoelastic-plastic mechanisms-based model of an electrorheological damper. J. Guidance, Control and Dynamics, 1997, 20(6), 1125–1132.

12.

Kim

J. W.

Kim

S. G.

Choi

H. J.

Jhon

M. S.

Synthesis and electrorheological properties of polyaniline Na⁺ montmorillonite suspensions. Macromol. Rapid Commun., 1999, 20(8), 450–452.

13.

Choi

S. B.

Kim

W. K.

Vibration control of a semi-active suspension featuring electrorheological fluid damper. J. Sound Vibr., 2000, 234(3), 537–546.

14.

Sim

I. S.

Kim

J. W.

Choi

H. J.

Kim

C. A.

Jhon

M. S.

Preparation and electrorheological characteristics of poly(p-phenylene)-based suspensions. Chem. Mater., 2001, 13(4), 1243–1247.

15.

Kim

J. W.

Jang

H. J.

Choi

H. J.

Joo

Synthesis and electrorheological characteristics of polyaniline derivatives with different substituents. Synthetic Metals, 2001, 119, 173–174.

16.

Mayergoyz

I. D.

Mathematical Models of Hysteresis, 1991 (Springer-Verlag, New York).

17.

Jouaneh

Tracking control of a piezoceramic actuator. IEEE Trans. Control Systems Technol., 1996, 4(3), 209–216.

Shear stress tracking control of an electrorheological fluid considering hysteresis non-linearity

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