An iteration-free approach to excitation harmonization

Sinusoidal excitation is particularly popular for testing structures in the nonlinear regime. Due to the nonlinear behavior and the inevitable feedback of the structure on the exciter, higher harmonics in the applied excitation are generated. This is undesired, because the acquired response may devi...

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Bibliographic Details
Published inarXiv.org
Main Authors Hippold, Patrick, Kleyman, Gleb, Woiwode, Lukas, Tong, Wei, Müller, Florian, Schwingshackl, Christoph, Scheel, Maren, Tatzko, Sebastian, Krack, Malte
Format Paper
LanguageEnglish
Published Ithaca Cornell University Library, arXiv.org 23.10.2024
Subjects
Configuration management
Control stability
Excitation
Feedback control
Harmonic distortion
Higher harmonics
Nonlinear control
Sine waves
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Summary:Sinusoidal excitation is particularly popular for testing structures in the nonlinear regime. Due to the nonlinear behavior and the inevitable feedback of the structure on the exciter, higher harmonics in the applied excitation are generated. This is undesired, because the acquired response may deviate substantially from that of the structure under purely sinusoidal excitation, in particular if one of the higher harmonics engages into resonance. We present a new approach to suppress those higher excitation harmonics and thus the unwanted exciter-structure interaction: Higher harmonics are added to the voltage input to the shaker whose Fourier coefficients are adjusted via feedback control until the excitation is purely sinusoidal. The stability of this method is analyzed for a simplified model; the resulting closed-form expressions are useful, among others, to select an appropriate exciter configuration, including the drive point. A practical procedure for the control design is suggested. The proposed method is validated in virtual and real experiments of internally resonant structures, in the two common configurations of force excitation via a stinger and base excitation. Excellent performance is achieved already when using the same control gains for all harmonics, throughout the tested range of amplitudes and frequencies, even in the strongly nonlinear regime. Compared to the iterative state of the art, it is found that the proposed method is simpler to implement, enables faster testing and it is easy to achieve a lower harmonic distortion.
ISSN:2331-8422