Application of the wavelet transform and the enhanced Fourier spectrum in the impact echo test
Resource
NDT & E International 41 (5): 382-394
Journal
NDT & E International
Journal Volume
41
Journal Issue
5
Pages
382-394
Date Issued
2008
Date
2008
Author(s)
Yeh, Po-Liang
Abstract
The objective of this study is to develop a reliable and effective method to analyze the signal of the impact echo test. The impact echo test is a nondestructive testing technique for civil structures. In the test, the surface response of the target structure due to an impact is measured. Then, the Fourier transform is adopted to transform the signal from the time domain to the frequency domain. Owing to the multiple reflections induced by cracks, voids, or other interfaces, peaks will form in the Fourier spectrum. The frequencies of the peaks can then be used to determine the size of the structure or the location of the defect. Several difficulties are encountered when applying the Fourier transform to impact echo data. Because the impact echo data are non-stationary and contains multiple reflections, ripples and multiple peaks appear in the Fourier spectrum, which may mislead the follow-up diagnosis. Furthermore, the existence of the high-energy surface wave and structural vibrations often complicates the spectrum and makes the data interpretation even more difficult. To overcome these difficulties, this research adopts the wavelet transform in the analysis of impact echo data. Theoretically, the wavelet transform can avoid ripple and multiple-peak phenomena. Furthermore, the frequency range and time span of surface wave can be observed in the wavelet scalogram. However, the spectral resolution of the wavelet marginal spectrum is inferior to that of the Fourier transform. Therefore, two approaches are proposed in this paper. One is to combine the Fourier spectrum and the wavelet marginal spectrum to determine the precise location of the echo peak. The other is to take the product of the two spectra to establish the enhanced Fourier spectrum. As such, the interference in the Fourier spectrum is suppressed while the peak is enhanced. Numerical and experimental tests were performed to verify the effectiveness and reliability of the proposed approaches. © 2008 Elsevier Ltd. All rights reserved.
Subjects
Enhanced Fourier spectrum; Fourier transform; Impact echo test; Nondestructive test; Wavelet transform
SDGs
Other Subjects
Fourier analysis; Frequency domain analysis; Nondestructive examination; Numerical methods; Wavelet transforms; Civil structures; Impact echo test; Wavelet scalogram; Echo suppression
Type
journal article
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