Extracting Weld Bead Shapes from Radiographic Testing Images with U-Net

Metals created by melting basic metal and welding rods in welding operations are referred to as weld beads. The weld bead shape allows the observation of pores and defects such as cracks in the weld zone. Radiographic testing images are used to determine the quality of the weld zone. The extraction...

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Veröffentlicht in:	Applied sciences 2021-12, Vol.11 (24), p.12051, Article 12051
Hauptverfasser:	Jin, Gang-soo, Oh, Sang-jin, Lee, Yeon-seung, Shin, Sung-chul
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Sprache:	eng
Schlagworte:	Algorithms Automation Chemistry Chemistry, Multidisciplinary Datasets Deep learning Engineering Engineering, Multidisciplinary Equalization Histograms Image contrast Image quality image segmentation Inspection Materials Science Materials Science, Multidisciplinary Metals Methods Noise Physical Sciences Physics Physics, Applied Preprocessing Radiographic testing Science & Technology Shipbuilding Technology weld bead Welding Welding rods
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description	Metals created by melting basic metal and welding rods in welding operations are referred to as weld beads. The weld bead shape allows the observation of pores and defects such as cracks in the weld zone. Radiographic testing images are used to determine the quality of the weld zone. The extraction of only the weld bead to determine the generative pattern of the bead can help efficiently locate defects in the weld zone. However, manual extraction of the weld bead from weld images is not time and cost-effective. Efficient and rapid welding quality inspection can be conducted by automating weld bead extraction through deep learning. As a result, objectivity can be secured in the quality inspection and determination of the weld zone in the shipbuilding and offshore plant industry. This study presents a method for detecting the weld bead shape and location from the weld zone image using image preprocessing and deep learning models, and extracting the weld bead through image post-processing. In addition, to diversify the data and improve the deep learning performance, data augmentation was performed to artificially expand the image data. Contrast limited adaptive histogram equalization (CLAHE) is used as an image preprocessing method, and the bead is extracted using U-Net, a pixel-based deep learning model. Consequently, the mean intersection over union (mIoU) values are found to be 90.58% and 85.44% in the train and test experiments, respectively. Successful extraction of the bead from the radiographic testing image through post-processing is achieved.
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In addition, to diversify the data and improve the deep learning performance, data augmentation was performed to artificially expand the image data. Contrast limited adaptive histogram equalization (CLAHE) is used as an image preprocessing method, and the bead is extracted using U-Net, a pixel-based deep learning model. Consequently, the mean intersection over union (mIoU) values are found to be 90.58% and 85.44% in the train and test experiments, respectively. 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The weld bead shape allows the observation of pores and defects such as cracks in the weld zone. Radiographic testing images are used to determine the quality of the weld zone. The extraction of only the weld bead to determine the generative pattern of the bead can help efficiently locate defects in the weld zone. However, manual extraction of the weld bead from weld images is not time and cost-effective. Efficient and rapid welding quality inspection can be conducted by automating weld bead extraction through deep learning. As a result, objectivity can be secured in the quality inspection and determination of the weld zone in the shipbuilding and offshore plant industry. This study presents a method for detecting the weld bead shape and location from the weld zone image using image preprocessing and deep learning models, and extracting the weld bead through image post-processing. In addition, to diversify the data and improve the deep learning performance, data augmentation was performed to artificially expand the image data. Contrast limited adaptive histogram equalization (CLAHE) is used as an image preprocessing method, and the bead is extracted using U-Net, a pixel-based deep learning model. Consequently, the mean intersection over union (mIoU) values are found to be 90.58% and 85.44% in the train and test experiments, respectively. Successful extraction of the bead from the radiographic testing image through post-processing is achieved.</abstract><cop>BASEL</cop><pub>Mdpi</pub><doi>10.3390/app112412051</doi><tpages>13</tpages><orcidid>https://orcid.org/0000-0001-5095-0862</orcidid><orcidid>https://orcid.org/0000-0003-1814-9578</orcidid><oa>free_for_read</oa></addata></record>
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subjects	Algorithms Automation Chemistry Chemistry, Multidisciplinary Datasets Deep learning Engineering Engineering, Multidisciplinary Equalization Histograms Image contrast Image quality image segmentation Inspection Materials Science Materials Science, Multidisciplinary Metals Methods Noise Physical Sciences Physics Physics, Applied Preprocessing Radiographic testing Science & Technology Shipbuilding Technology weld bead Welding Welding rods
title	Extracting Weld Bead Shapes from Radiographic Testing Images with U-Net
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