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Auteurs principaux: Ghamisi, Assef, Charter, Todd, Ji, Li, Rivard, Maxime, Lund, Gil, Najjaran, Homayoun
Format: Preprint
Publié: 2023
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Accès en ligne:https://arxiv.org/abs/2307.07893
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author Ghamisi, Assef
Charter, Todd
Ji, Li
Rivard, Maxime
Lund, Gil
Najjaran, Homayoun
author_facet Ghamisi, Assef
Charter, Todd
Ji, Li
Rivard, Maxime
Lund, Gil
Najjaran, Homayoun
contents Conventional defect detection systems in Automated Fibre Placement (AFP) typically rely on end-to-end supervised learning, necessitating a substantial number of labelled defective samples for effective training. However, the scarcity of such labelled data poses a challenge. To overcome this limitation, we present a comprehensive framework for defect detection and localization in Automated Fibre Placement. Our approach combines unsupervised deep learning and classical computer vision algorithms, eliminating the need for labelled data or manufacturing defect samples. It efficiently detects various surface issues while requiring fewer images of composite parts for training. Our framework employs an innovative sample extraction method leveraging AFP's inherent symmetry to expand the dataset. By inputting a depth map of the fibre layup surface, we extract local samples aligned with each composite strip (tow). These samples are processed through an autoencoder, trained on normal samples for precise reconstructions, highlighting anomalies through reconstruction errors. Aggregated values form an anomaly map for insightful visualization. The framework employs blob detection on this map to locate manufacturing defects. The experimental findings reveal that despite training the autoencoder with a limited number of images, our proposed method exhibits satisfactory detection accuracy and accurately identifies defect locations. Our framework demonstrates comparable performance to existing methods, while also offering the advantage of detecting all types of anomalies without relying on an extensive labelled dataset of defects.
format Preprint
id arxiv_https___arxiv_org_abs_2307_07893
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Anomaly Detection in Automated Fibre Placement: Learning with Data Limitations
Ghamisi, Assef
Charter, Todd
Ji, Li
Rivard, Maxime
Lund, Gil
Najjaran, Homayoun
Computer Vision and Pattern Recognition
Artificial Intelligence
Machine Learning
Image and Video Processing
Conventional defect detection systems in Automated Fibre Placement (AFP) typically rely on end-to-end supervised learning, necessitating a substantial number of labelled defective samples for effective training. However, the scarcity of such labelled data poses a challenge. To overcome this limitation, we present a comprehensive framework for defect detection and localization in Automated Fibre Placement. Our approach combines unsupervised deep learning and classical computer vision algorithms, eliminating the need for labelled data or manufacturing defect samples. It efficiently detects various surface issues while requiring fewer images of composite parts for training. Our framework employs an innovative sample extraction method leveraging AFP's inherent symmetry to expand the dataset. By inputting a depth map of the fibre layup surface, we extract local samples aligned with each composite strip (tow). These samples are processed through an autoencoder, trained on normal samples for precise reconstructions, highlighting anomalies through reconstruction errors. Aggregated values form an anomaly map for insightful visualization. The framework employs blob detection on this map to locate manufacturing defects. The experimental findings reveal that despite training the autoencoder with a limited number of images, our proposed method exhibits satisfactory detection accuracy and accurately identifies defect locations. Our framework demonstrates comparable performance to existing methods, while also offering the advantage of detecting all types of anomalies without relying on an extensive labelled dataset of defects.
title Anomaly Detection in Automated Fibre Placement: Learning with Data Limitations
topic Computer Vision and Pattern Recognition
Artificial Intelligence
Machine Learning
Image and Video Processing
url https://arxiv.org/abs/2307.07893