Fatigue Crack Localization Using Laser Nonlinear Wave Modulation Spectroscopy (LNWMS)
Author(s) -
Peipei Liu,
Hoon Sohn,
Tribikram Kundu
Publication year - 2014
Publication title -
journal of the korean society for nondestructive testing
Language(s) - English
Resource type - Journals
eISSN - 2287-402X
pISSN - 1225-7842
DOI - 10.7779/jksnt.2014.34.6.419
Subject(s) - nonlinear system , sideband , materials science , laser , ultrasonic sensor , optics , modulation (music) , amplitude , broadband , acoustics , amplitude modulation , frequency modulation , physics , radio frequency , telecommunications , computer science , quantum mechanics
Nonlinear features of ultrasonic waves are more sensitive to the presence of a fatigue crack than their linear counterparts are. For this reason, the use of nonlinear ultrasonic techniques to detect a fatigue crack at its early stage has been widely investigated. Of the different proposed techniques, laser nonlinear wave modulation spectroscopy (LNWMS) is unique because a pulse laser is used to exert a single broadband input and a noncontact measurement can be performed. Broadband excitation causes a nonlinear source to exhibit modulation at multiple spectral peaks owing to interactions among various input frequency components. A feature called maximum sideband peak count difference (MSPCD), which is extracted from the spectral plot, measures the degree of crackinduced material nonlinearity. First, the ratios of spectral peaks whose amplitudes are above a moving threshold to the total number of peaks are computed for spectral signals obtained from the pristine and the current state of a target structure. Then, the difference of these ratios are computed as a function of the moving threshold. Finally, the MSPCD is defined as the maximum difference between these ratios. The basic premise is that the MSPCD will increase as the nonlinearity of the material increases. This technique has been used successfully for localizing fatigue cracks in metallic plates.
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