振动声调制无损检测方法中振幅和频率调制的分离

Proc. Meet. Acoust. Pub Date : 2018-09-11 DOI:10.1121/2.0000831

D. Donskoy, M. Ramezani

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引用次数: 20

摘要

振动声调制(VAM)方法利用频率为ω的高频超声波(载波信号)和频率为Ω << ω的低频调制振动的非线性相互作用，存在各种缺陷，如疲劳和应力腐蚀裂纹，剥离等。大多数报道的VAM研究将缺陷的存在和增长与频谱域中调制指数(MI)的增加联系起来，该指数定义为频率为ω±Ω的边带频谱分量与载波振幅的比值。然而，这种方法并没有区分振幅、调幅或频率、调频调制对MI的影响。人们一直认为，由于接触型非线性机制，主流调制是调幅。然而，可能有其他机制导致相位/频率调制。本研究旨在开发一种专门针对VAM方法的调幅/调频分离算法。结果表明，通常使用的希尔伯特变换(HT)分离可能不适用于典型的VAM场景。开发的同相/正交同差分离算法解决了HT的缺点。该算法在疲劳裂纹演化过程中进行了数值和实验验证，结果表明:微裂纹扩展初期以调频为主，大裂纹形成阶段以调频为主。振动声调制(VAM)方法利用频率为ω的高频超声波(载波信号)和频率为Ω << ω的低频调制振动的非线性相互作用，存在各种缺陷，如疲劳和应力腐蚀裂纹，剥离等。大多数报道的VAM研究将缺陷的存在和增长与频谱域中调制指数(MI)的增加联系起来，该指数定义为频率为ω±Ω的边带频谱分量与载波振幅的比值。然而，这种方法并没有区分振幅、调幅或频率、调频调制对MI的影响。人们一直认为，由于接触型非线性机制，主流调制是调幅。然而，可能有其他机制导致相位/频率调制。本研究旨在开发一种专门针对VAM方法的调幅/调频分离算法。结果表明，常用的希尔伯特变换(HT)分离方法可有效地提高分离精度。

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Separation of amplitude and frequency modulations in Vibro-Acoustic Modulation Nondestructive Testing Method

The Vibro-Acoustic Modulation (VAM) method utilizes nonlinear interaction of a high frequency ultrasonic wave (carrier signal) with frequency ω and a low frequency modulating vibration with frequency Ω << ω, in the presence of various flaws such as fatigue and stress-corrosion cracks, disbonds, etc. Most of the reported VAM studies correlate flaw presence and growth with the increase in the Modulation Index (MI) defined in the spectral domain as the ratio of the side-band spectral components at frequencies ω±Ω to the amplitude of the carrier. This approach, however, does not differentiate between amplitude, AM, or frequency, FM, modulations contributing to the MI. It has been assumed that the prevailing modulation is AM due to contact-type nonlinear mechanisms. However, there could be other mechanisms leading to phase/frequency modulation. The present study aims to develop an algorithm of AM/FM separation specifically for the VAM method. It is shown that the commonly used Hilbert Transform (HT) separation may not work for a typical VAM scenario. The developed In-phase/Quadrature Homodyne Separation algorithm addresses HT shortcomings. The algorithm has been tested both numerically and experimentally (for fatigue crack evolution) showing FM dominance at initial micro-crack growth stages and transition to AM dominance during macro-crack formation.The Vibro-Acoustic Modulation (VAM) method utilizes nonlinear interaction of a high frequency ultrasonic wave (carrier signal) with frequency ω and a low frequency modulating vibration with frequency Ω << ω, in the presence of various flaws such as fatigue and stress-corrosion cracks, disbonds, etc. Most of the reported VAM studies correlate flaw presence and growth with the increase in the Modulation Index (MI) defined in the spectral domain as the ratio of the side-band spectral components at frequencies ω±Ω to the amplitude of the carrier. This approach, however, does not differentiate between amplitude, AM, or frequency, FM, modulations contributing to the MI. It has been assumed that the prevailing modulation is AM due to contact-type nonlinear mechanisms. However, there could be other mechanisms leading to phase/frequency modulation. The present study aims to develop an algorithm of AM/FM separation specifically for the VAM method. It is shown that the commonly used Hilbert Transform (HT) separation...

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Proc. Meet. Acoust.

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