Deep Machine Learning for Acoustic Inspection of Metallic Medium

IF 1.9 Q3 ENGINEERING, MECHANICAL
Vibration Pub Date : 2022-08-28 DOI:10.3390/vibration5030030
B. Jarreau, S. Yoshida, Emily Laprime
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引用次数: 2

Abstract

Acoustic non-destructive testing is widely used to detect signs of damage. However, an experienced technician is typically responsible for interpreting the result, and often the evaluation varies depending on the technician’s opinion. The evaluation is especially challenging when the acoustic signal is analyzed in the near field as Fresnel range diffraction complicates the data. In this study, we propose a Convolutional Neural Network (CNN) algorithm to detect anomalies bearing in mind its future application to micro-scale specimens such as biomedical materials. Data are generated by emitting a continuous sound wave at a single frequency through a metal specimen with a sub-millimeter anomaly and collecting the transmitted signal at several lateral locations on the opposite side (the observation plane) of the specimen. The distance between the anomaly and the observation plane falls in the quasi Fresnel diffraction regime. The use of transmitted signals is essential to evaluate the phase shift due to the anomaly, which contains information about the substance in the anomaly. We have developed a seven-layered CNN to analyze the acoustic signal in the frequency domain. The CNN takes spectrograms representing the change in the amplitude and phase of the Fourier transform over the lateral position on the observation plane as input and classifies the anomaly into nine classes in association with the lateral location of the anomaly relative to the probing signal and the material of the anomaly. The CNN performed excellently demonstrating the validation accuracy as high as 99.9%. This result clearly demonstrates CNN’s ability to extract features in the input signal that are undetectable to humans.
金属介质声学检测的深度机器学习
声学无损检测被广泛用于检测损伤迹象。然而,经验丰富的技术人员通常负责解释结果,并且通常根据技术人员的意见进行评估。当在近场分析声信号时,由于菲涅耳范围衍射使数据复杂化,评估尤其具有挑战性。在这项研究中,我们提出了一种卷积神经网络(CNN)算法来检测异常,并考虑到其未来在生物医学材料等微尺度标本中的应用。数据是通过在亚毫米异常的金属试样中发射单频连续声波,并在试样的对面(观测平面)的几个横向位置采集发射信号来产生的。异常与观测面之间的距离落在准菲涅耳衍射区。利用传输信号来评估由于异常引起的相移是必不可少的,它包含了异常中物质的信息。我们开发了一个七层CNN来分析频域的声信号。CNN以表示观测平面横向位置上傅里叶变换幅度和相位变化的频谱图作为输入,根据异常相对于探测信号的横向位置和异常的物质将异常分为9类。CNN表现出色,验证准确率高达99.9%。这个结果清楚地证明了CNN能够从输入信号中提取人类无法检测到的特征。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
3.20
自引率
0.00%
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审稿时长
10 weeks
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