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Abstract

The authors investigate theoretically and experimentally the performance of a recently developed quadratic vibration absorber that is based on the saturation phenomenon. They consider the problem of con trolling the vibrations of a single-degree-of-freedom plant, develop the equations governing the response of the closed-loop system, and obtain an approximate solution. They investigate the strategy by studying its steady-state characteristics and comparing its performance with that of a linear tuned absorber. Then, they implement both techniques experimentally using a digital signal processing device. The authors develop a software algorithm that allows for automatic real-time tracking of the system response. They use both tech niques to control high-amplitude responses of a cantilever beam fitted with piezoceramic actuators. When each absorber's frequency is tuned properly, they show that both schemes possess similar suppression band widths. In addition, they demonstrate that the power requirement of the quadratic absorber can be reduced by judicially modifying its control signal.

Keywords

Nonlinear absorber digital control saturation autoparametric resonance

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References

Cartmell, M. and Lawson, J. , 1994, "Performance enhancement of an autoparametric vibration absorber by means of computer control," Journal of Sound and Vibration 177, 173-195.

Cuvalci, O. and Ertas, A. , 1996, "Pendulum as vibration absorber for flexible structures: Experiments and theory," Journal of Vibration and Acoustics 118, 558-566.

Fanson, J.L. and Caughey, T.K. , 1990, "Positive position feedback control for large space structures ," AIAA Journal 28, 717-724.

Haxton, R.S. and Barr, A.D.S. , 1972, "The autoparametric vibration absorber," Journal of Engineering for Industry 94, 119-225.

Hombeck, R.W. , 1975, Numerical Methods, Prentice Hall, Englewood Cliffs, NJ.

Khajepour, A. and Golnaraghi, M.F. , 1997, "Experimental control of flexible structures using nonlinear modal coupling: Forced and free vibrations ," Journal of Intelligent Material Systems and Structures 8, 697-710.

McConnell, K.G. , 1995, Vibration Testing, John Wiley , New York.

Nayfeh, A.H. , 1973, Perturbation Methods, John Wiley , New York.

Nayfeh, A.H. , 1981, Introduction to Perturbation Techniques, John Wiley, New York.

10.

Nayfeh, A.H. , Mook, D.T. , and Marshall, L.R. , 1973, "Nonlinear coupling of pitch and roll modes in ship motion ," Journal of Hydronautics 7, 145-152.

11.

Oueini, S.S. , Nayfeh, A.H. , and Pratt, J.R. , 1998, "A nonlinear vibration absorber for flexible structures ," Nonlinear Dynamics 15, 259-282.

12.

Oueini, S.S. , Nayfeh, A.H. , and Pratt, J.R. , 1999, "A review of development and implementation of a nonlinear vibration absorber," Archive of Applied Mechanics 69, 585-620.

13.

Pai, P.F. , Wen, B. , Naser, A.S. , and Schultz, M.J. , 1998, "Structural vibration control using PZT patches and non-linear phenomena," Journal of Sound and Vibration 215, 273-296.,

Analysis and Application of a Nonlinear Vibration Absorber

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