Full Waveform Inversion for NDT using ultrasonic linear arrays

Research and Review Journal of Nondestructive Testing Pub Date : 2023-08-01 DOI:10.58286/28117

Daniel Rossato, F. D. Gutierrez, G. A. Guarneri, T. Passarin, G. Pires, D. Pipa

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Abstract

Ultrasonic (UT) imaging is a widespread technique for nondestructive testing (NDT). The state-of-the-art UT image reconstruction algorithms are based on delay-and-sum (DAS) operations, which assume constant acoustic velocity across the tested objects and also neglects nonlinear effects such as diffractions and multiple reflections. These assumptions limit the reconstruction capabilities of DAS-based algorithms, especially for complex objects composed by several materials. In seismology, Full Waveform Inversion (FWI) methods have been used to obtain subsurface properties based on scattered and transmitted sound waves - which is a very similar problem to ultrasonic imaging in NDT - using the full wave information, showing promising results. In this paper, we present the application of FWI in NDT using simulated data representing acquisitions with a common linear array transducer. We review the theoretical formulation of FWI and discuss some difficulties that arise when it is applied to NDT. Image reconstruction is performed using both a state-of-the-art DAS algorithm, namely the Total Focusing Method, and FWI. The implementation targets a GPU platform, using the CUDA API. This leverages the highly parallelizable nature of the simulations and the FWI algorithm. The obtained results show that FWI can show more internal structures than TFM, with less information about the specimen. To foster further development, all source codes are provided.

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超声线性阵列无损检测全波形反演

超声成像是一种广泛应用于无损检测的技术。最先进的UT图像重建算法基于延迟和(DAS)操作，该操作假设被测物体的声速恒定，并且忽略了衍射和多次反射等非线性效应。这些假设限制了基于das的算法的重建能力，特别是对于由几种材料组成的复杂物体。在地震学中，全波形反演(FWI)方法已被用于利用全波信息获得基于散射和透射声波的地下性质，这与无损检测中的超声成像问题非常相似，并显示出很好的结果。在本文中，我们介绍了FWI在无损检测中的应用，使用了代表普通线性阵列换能器采集的模拟数据。我们回顾了FWI的理论表述，并讨论了应用于无损检测时出现的一些困难。图像重建是使用最先进的DAS算法，即全聚焦方法和FWI进行的。该实现针对GPU平台，使用CUDA API。这充分利用了模拟和FWI算法的高度并行性。结果表明，与TFM相比，FWI可以显示更多的内部结构，但对试件的信息较少。为了促进进一步的开发，提供了所有源代码。

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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Research and Review Journal of Nondestructive Testing

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