A data-driven approach to suppress artefacts using PCA and autoencoders

Sergio Cantero-Chinchilla; Anthony J Croxford; Paul D Wilcox

doi:10.1016/j.ndteint.2023.102904

A data-driven approach to suppress artefacts using PCA and autoencoders

Sergio Cantero-Chinchilla^*, Anthony J Croxford, Paul D Wilcox

^*Corresponding author for this work

Research output: Contribution to journal › Article (Academic Journal) › peer-review

8 Citations (Scopus)

Abstract

A data-driven framework for artefact suppression in non-destructive testing data is proposed in this paper. The framework consists of two stages for dimensionality reduction through (1) a principal component analysis and (2) an autoencoder. The first stage reduces the dimensionality of the input data. This allows the architecture of the autoencoder to be relatively shallow, which means that the deep learning model is fast to train and does not need as much training data. The output of the autoencoder contains artefact information (originating from structural features) and is projected back to the original domain. This is subtracted from the input data in order to isolate defect and noise information. The framework trains on defect-free experimental data and it does not require a large amount of training data. An optimisation approach to arrive at a near-optimal framework architecture is also proposed. An ultrasonic phased-array imaging application is used to illustrate the methodology and compared against the state-of-the-art deep learning approach to suppressing artefacts. The proposed method proves to be effective at suppressing artefacts leading to a good defect detection and characterisation performance.

Original language	English
Article number	102904
Journal	NDT & E International
Volume	139
Early online date	7 Jul 2023
DOIs	https://doi.org/10.1016/j.ndteint.2023.102904
Publication status	Published - 1 Oct 2023

Bibliographical note

Funding Information:
The work reported is part of a pilot project (Grant number 100374) funded by Lloyd's Register Foundation, United Kingdom and the Alan Turing Institute Data-Centric Engineering Programme, United Kingdom . This work was partly carried out using the computational facilities of the Advanced Computing Research Centre, University of Bristol - http://www.bris.ac.uk/acrc/.

Funding Information:
The work reported is part of a pilot project (Grant number 100374 ) funded by Lloyd’s Register Foundation, United Kingdom and the Alan Turing Institute Data-Centric Engineering Programme, United Kingdom . This work was partly carried out using the computational facilities of the Advanced Computing Research Centre, University of Bristol - http://www.bris.ac.uk/acrc/ .

Publisher Copyright:
© 2023 The Author(s)

Research Groups and Themes

Ultrasonics and Non-Destructive Testing (UNDT)

Keywords

Non-Destructive Evaluation (NDE
Deep learning
Artefacts
Ultrasound
Phased-array imaging
principal component analysis (PCA)
Autoencoder (AE)

Access to Document

10.1016/j.ndteint.2023.102904Licence: CC BY

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Data Science for NDE
Wilcox, P. D. (Principal Investigator), Croxford, A. J. (Co-Investigator) & Cantero Chinchilla, S. (Researcher)
Project: Research

HPC (High Performance Computing) and HTC (High Throughput Computing) Facilities
Alam, S. R. (Manager), Williams, D. A. G. (Manager), Eccleston, P. E. (Manager) & Greene, D. (Manager)
Facility/equipment: Facility

Cite this

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abstract = "A data-driven framework for artefact suppression in non-destructive testing data is proposed in this paper. The framework consists of two stages for dimensionality reduction through (1) a principal component analysis and (2) an autoencoder. The first stage reduces the dimensionality of the input data. This allows the architecture of the autoencoder to be relatively shallow, which means that the deep learning model is fast to train and does not need as much training data. The output of the autoencoder contains artefact information (originating from structural features) and is projected back to the original domain. This is subtracted from the input data in order to isolate defect and noise information. The framework trains on defect-free experimental data and it does not require a large amount of training data. An optimisation approach to arrive at a near-optimal framework architecture is also proposed. An ultrasonic phased-array imaging application is used to illustrate the methodology and compared against the state-of-the-art deep learning approach to suppressing artefacts. The proposed method proves to be effective at suppressing artefacts leading to a good defect detection and characterisation performance.",

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note = "Funding Information: The work reported is part of a pilot project (Grant number 100374) funded by Lloyd's Register Foundation, United Kingdom and the Alan Turing Institute Data-Centric Engineering Programme, United Kingdom . This work was partly carried out using the computational facilities of the Advanced Computing Research Centre, University of Bristol - http://www.bris.ac.uk/acrc/. Funding Information: The work reported is part of a pilot project (Grant number 100374 ) funded by Lloyd{\textquoteright}s Register Foundation, United Kingdom and the Alan Turing Institute Data-Centric Engineering Programme, United Kingdom . This work was partly carried out using the computational facilities of the Advanced Computing Research Centre, University of Bristol - http://www.bris.ac.uk/acrc/ . Publisher Copyright: {\textcopyright} 2023 The Author(s)",

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N2 - A data-driven framework for artefact suppression in non-destructive testing data is proposed in this paper. The framework consists of two stages for dimensionality reduction through (1) a principal component analysis and (2) an autoencoder. The first stage reduces the dimensionality of the input data. This allows the architecture of the autoencoder to be relatively shallow, which means that the deep learning model is fast to train and does not need as much training data. The output of the autoencoder contains artefact information (originating from structural features) and is projected back to the original domain. This is subtracted from the input data in order to isolate defect and noise information. The framework trains on defect-free experimental data and it does not require a large amount of training data. An optimisation approach to arrive at a near-optimal framework architecture is also proposed. An ultrasonic phased-array imaging application is used to illustrate the methodology and compared against the state-of-the-art deep learning approach to suppressing artefacts. The proposed method proves to be effective at suppressing artefacts leading to a good defect detection and characterisation performance.

AB - A data-driven framework for artefact suppression in non-destructive testing data is proposed in this paper. The framework consists of two stages for dimensionality reduction through (1) a principal component analysis and (2) an autoencoder. The first stage reduces the dimensionality of the input data. This allows the architecture of the autoencoder to be relatively shallow, which means that the deep learning model is fast to train and does not need as much training data. The output of the autoencoder contains artefact information (originating from structural features) and is projected back to the original domain. This is subtracted from the input data in order to isolate defect and noise information. The framework trains on defect-free experimental data and it does not require a large amount of training data. An optimisation approach to arrive at a near-optimal framework architecture is also proposed. An ultrasonic phased-array imaging application is used to illustrate the methodology and compared against the state-of-the-art deep learning approach to suppressing artefacts. The proposed method proves to be effective at suppressing artefacts leading to a good defect detection and characterisation performance.

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KW - Artefacts

KW - Ultrasound

KW - Phased-array imaging

KW - principal component analysis (PCA)

KW - Autoencoder (AE)

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JF - NDT & E International

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ER -

A data-driven approach to suppress artefacts using PCA and autoencoders

Abstract

Bibliographical note

Research Groups and Themes

Keywords

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Projects

Data Science for NDE

Equipment

HPC (High Performance Computing) and HTC (High Throughput Computing) Facilities

Cite this