Deploying Machine Learning for Radiography of Aerospace Welds

Artificial intelligence is providing new possibilities for analysis in the field of industrial radiography. As capabilities evolve, there is the need for knowledge concerning how to deploy these technologies in practice and benefit from the new automatically generated information. In this study, aut...

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Veröffentlicht in:	Journal of nondestructive evaluation 2024-03, Vol.43 (1), Article 24
Hauptverfasser:	Tyystjärvi, Topias, Fridolf, Peter, Rosell, Anders, Virkkunen, Iikka
Format:	Artikel
Sprache:	eng
Schlagworte:	Annotations Artificial intelligence building the eco-system and continuing research Characterization and Evaluation of Materials Classical Mechanics Control Dynamical Systems Engineering Flaw detection Laser beam welding Machine learning Nondestructive testing Quality control Radiography Reliability analysis Solid Mechanics Statistical analysis TC: NDE 4.0 Creating success stories Vibration Weld defects
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container_title	Journal of nondestructive evaluation
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creator	Tyystjärvi, Topias Fridolf, Peter Rosell, Anders Virkkunen, Iikka
description	Artificial intelligence is providing new possibilities for analysis in the field of industrial radiography. As capabilities evolve, there is the need for knowledge concerning how to deploy these technologies in practice and benefit from the new automatically generated information. In this study, automatic defect recognition based on machine learning was deployed as an aid in industrial radiography of laser welds in an aerospace component, and utilized to produce statistics for improved quality control. A multi-model approach with an added weld segmentation step improved the inference speed and decreased false calls to improve field use. A user interface with visualization options was developed to display the evaluation results. A dataset of 451 radiographs was automatically analysed, yielding 10037 indications with size and location information, providing capability for statistical analysis beyond what is practical to carry out with manual annotation. The distribution of indications was modeled as a product of the probability of detection and an exponentially decreasing underlying flaw distribution, opening the possibility for model reliability assessment and predictive capabilities on weld defects. An analysis of the indications demonstrated the capability to automatically detect both large-scale trends and individual components and welds that were more at risk of failing the inspection. This serves as a step towards smarter utilization of non-destructive evaluation data in manufacturing.
doi_str_mv	10.1007/s10921-023-01041-w
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The distribution of indications was modeled as a product of the probability of detection and an exponentially decreasing underlying flaw distribution, opening the possibility for model reliability assessment and predictive capabilities on weld defects. An analysis of the indications demonstrated the capability to automatically detect both large-scale trends and individual components and welds that were more at risk of failing the inspection. 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The distribution of indications was modeled as a product of the probability of detection and an exponentially decreasing underlying flaw distribution, opening the possibility for model reliability assessment and predictive capabilities on weld defects. An analysis of the indications demonstrated the capability to automatically detect both large-scale trends and individual components and welds that were more at risk of failing the inspection. 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As capabilities evolve, there is the need for knowledge concerning how to deploy these technologies in practice and benefit from the new automatically generated information. In this study, automatic defect recognition based on machine learning was deployed as an aid in industrial radiography of laser welds in an aerospace component, and utilized to produce statistics for improved quality control. A multi-model approach with an added weld segmentation step improved the inference speed and decreased false calls to improve field use. A user interface with visualization options was developed to display the evaluation results. A dataset of 451 radiographs was automatically analysed, yielding 10037 indications with size and location information, providing capability for statistical analysis beyond what is practical to carry out with manual annotation. The distribution of indications was modeled as a product of the probability of detection and an exponentially decreasing underlying flaw distribution, opening the possibility for model reliability assessment and predictive capabilities on weld defects. An analysis of the indications demonstrated the capability to automatically detect both large-scale trends and individual components and welds that were more at risk of failing the inspection. This serves as a step towards smarter utilization of non-destructive evaluation data in manufacturing.</abstract><cop>New York</cop><pub>Springer US</pub><doi>10.1007/s10921-023-01041-w</doi><oa>free_for_read</oa></addata></record>
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subjects	Annotations Artificial intelligence building the eco-system and continuing research Characterization and Evaluation of Materials Classical Mechanics Control Dynamical Systems Engineering Flaw detection Laser beam welding Machine learning Nondestructive testing Quality control Radiography Reliability analysis Solid Mechanics Statistical analysis TC: NDE 4.0 Creating success stories Vibration Weld defects
title	Deploying Machine Learning for Radiography of Aerospace Welds
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