Ultrasonic guided wave imaging of pipelines based on physics embedded inversion neural network

Lv, Lingling; Chen, Shili; Tong, Junkai; Chen, Xin; Zeng, Zhoumo; Liu, Yang

doi:10.1088/1361-6501/ace98b

Cited by 3 publications

(1 citation statement)

References 36 publications

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“…Yu et al proposed a ZSL model Feature-generative adversarial network (GAN)-zero-shot learning (ZSL) fused with a generative adversarial network for ultrasonic detection to identify pipeline weld defects by integrating artificial semantic features with ultrasonic inspection signal features in a common semantic space, utilizing a Feature-GAN network to generate unseen class features and enhance feature generation with stronger discriminative power [16]. Lv et al proposed a deep neural network built upon a physical model to quantify pipeline corrosion from ultrasonic guided wave signals, which involved a workflow of forward modeling and residual inversion to reconstruct pipe wall thickness [17]. Currently, in the field of pipeline inspection, acoustic detection methods based on deep learning are primarily focused on recognizing various defects, including leaks, corrosion, and welding.…”

Section: Introductionmentioning

confidence: 99%

Research on acoustic methods for buried PE pipeline detection based on LSTM neural networks

Qi,

Wang,

Yang

et al. 2024

Meas. Sci. Technol.

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As an essential component of urban infrastructure construction, Polyethylene (PE) pipelines face the challenging task of underground detection due to the complex and dynamic nature of the subsurface environment, diverse installation paths, and the inherent insulating properties of PE materials. In order to address the non-excavation detection of buried PE pipelines, this paper proposes an acoustic method based on the Long Short-Term Memory (LSTM) neural network. The study begins by analyzing the propagation and reflection mechanisms of elastic waves in the pipe-soil coupling system, and a impact excitation source is designed to generate the excitation signal. After establishing the experimental environment and collecting experimental data, a comprehensive analysis is conducted, and the LSTM neural network is employed for data classification to determine the presence of buried PE pipelines. Through neural network training, accurate identification of the PE pipeline's existence and prediction of its burial depth are achieved, providing an efficient and reliable solution for buried PE pipeline detection. The practical results demonstrate the significant application prospects of the combined acoustic method and LSTM neural network in buried PE pipeline detection. This research contributes a novel solution to the field of non-destructive PE pipeline detection, with both theoretical and practical implications.

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Section: Introductionmentioning

confidence: 99%

Research on acoustic methods for buried PE pipeline detection based on LSTM neural networks

Qi,

Wang,

Yang

et al. 2024

Meas. Sci. Technol.

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Quantitative guided wave imaging with shear horizontal waves and deep convolutional descent full waveform inversion

Tong,

Li,

Lin

et al. 2024

NDT & E International

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Defect detection and localisation using guided wave images from array data processed by nonlinear autoregressive exogenous model and Gamma statistical operator

Wang,

Zhang,

Xiao

et al. 2024

Structural Health Monitoring

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Guided wave structural health monitoring (GWSHM) systems, using the delay-and-sum imaging algorithm, are an efficient solution to detect and localise defects in industrial structures. However, the image artifacts caused by either imperfect detection or sensor lay-out limitations make it difficult to identify and locate defects accurately. In order to enhance the performance of defect detection and localisation in GWSHM systems, this paper proposes a three-step procedure for post-processing guided wave signals prior to image formation. In the first step, the signals are processed using the nonlinear autoregressive exogenous model to suppress noise from benign features. The second step calculates the probability of defect presence based on the rescaled Gamma cumulative distribution function. This probabilistic threshold is then determined from the quantile mapping. Finally, a guide wave image is formed using the delay-and-sum imaging algorithm. The experimental validation was performed to inspect a 6 mm-diameter through-thickness circular hole on an aluminium plate and the defects were further scaled as simulated datasets to test its detectability under various amplitudes. In the second procedure step, the detection and localisation performance of the proposed procedure was compared with that of using the signal difference coefficient and the Rayleigh maximum likelihood estimator. It is shown that the proposed procedure can enhance the contrast between damaged and undamaged regions, providing more reliable and accurate guided wave images.

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Ultrasonic guided wave imaging of pipelines based on physics embedded inversion neural network

Cited by 3 publications

References 36 publications

Research on acoustic methods for buried PE pipeline detection based on LSTM neural networks

Research on acoustic methods for buried PE pipeline detection based on LSTM neural networks

Quantitative guided wave imaging with shear horizontal waves and deep convolutional descent full waveform inversion

Defect detection and localisation using guided wave images from array data processed by nonlinear autoregressive exogenous model and Gamma statistical operator

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