Active Attenuation of Periodic Vibration in Nonlinear Systems Using an Adaptive Harmonic Controller-Reference-Cited by-同舟云学术

Active Attenuation of Periodic Vibration in Nonlinear Systems Using an Adaptive Harmonic Controller

Published:1995-07-01 Issue:3A Volume:117 Page:355-362
ISSN:1048-9002
Container-title:Journal of Vibration and Acoustics
language:en
Short-container-title:

Author:

Sutton T. J.¹,Elliott S. J.¹

Affiliation:

1. Institute of Sound and Vibration Research, University of Southampton, Southampton S017 1BJ, UK

Abstract

The article describes a nonlinear adaptive controller for the attenuation of harmonic disturbances in nonlinear systems. The steepest descent algorithm is used to adapt the controller coefficients and synthesize the optimum periodic waveform at the input of the nonlinear system, giving the best attenuation of the disturbance. A simple frequencydomain model of the system is required to implement the steepest descent approach. The scheme is particularly applicable where the secondary actuator used for active vibration control is a nonlinear device such as a magnetostrictive actuator. Simulation studies show that an adaptive scheme of this type is robust to the choice of frequency-domain model when the nonlinearity is hysteretic, but much more sensitive when the nonlinearity is a saturation function. A real-time adaptive harmonic controller has been built and used to control the motion of a magnetostrictive actuator. With dc and 7 harmonics under control the system was able to overcome the inherent nonlinearity of the actuator at fundamental frequencies in excess of 3 kHz.

Publisher

ASME International

Subject

General Engineering

Link

http://asmedigitalcollection.asme.org/vibrationacoustics/article-pdf/117/3A/355/5825175/355_1.pdf

Reference15 articles.

1. Billings, S., and Chen, S., 1992, “Neural Networks and System Identification,” Chapter 9 of Neural Networks for Control and Systems, K. Warwick, et al., eds., Peter Peregrinus Ltd., London.

2. Bouc, R., 1967, “Forced Vibration of Mechanical System with Hysteresis,” Proceedings of the Fourth Conference on Nonlinear Oscillations, Prague.

3. Elliott, S. J., Stothers, I. M., Nelson, P. A., McDonald, A. M., Quinn, D. C, and Saunders, T. J., 1988, “The Active Control of Engine Noise Inside Cars,” Proceedings of Internoise 88, Avignon, France, pp. 987–990.

4. Elliott S. J. , NelsonP. A., StothersI. M., and BoucherC. C., 1990, “In-flight Experiments on the Active Control of Propellor-induced Cabin Noise,” Journal of Sound and Vibration, Vol. 140, No. 2, pp. 219–238.

5. Elliott S. J. , BoucherC. C., and NelsonP. A., 1992, “The Behaviour of a Multiple Channel Active Control System,” IEEE Transactions on Signal Processing, Vol. 40, No. 5, May 1992, pp. 1041–1052.

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