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利用深度学习和先进成像系统优化光泽和曲面上的缺陷检测

Optimizing Defect Detection on Glossy and Curved Surfaces Using Deep Learning and Advanced Imaging Systems.

作者信息

Yoon Joung-Hwan, Okwuosa Chibuzo Nwabufo, Aronwora Nnamdi Chukwunweike, Hur Jang-Wook

机构信息

Department of Mechanical Engineering (Department of Aeronautics, Mechanical and Electronic Convergence Engineering), Kumoh National Institute of Technology, 61 Daehak-ro, Gumi-si 39177, Gyeonsangbuk-do, Republic of Korea.

出版信息

Sensors (Basel). 2025 Apr 13;25(8):2449. doi: 10.3390/s25082449.

DOI:10.3390/s25082449
PMID:40285138
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12031545/
Abstract

The industrial application of artificial intelligence (AI) has witnessed outstanding adoption due to its robust efficiency in recent times. Image fault detection and classification have also been implemented industrially for product defect detection, as well as for maintaining standards and optimizing processes using AI. However, there are deep concerns regarding the latency in the performance of AI for fault detection in glossy and curved surface products, due to their nature and reflective surfaces, which hinder the adequate capturing of defective areas using traditional cameras. Consequently, this study presents an enhanced method for curvy and glossy surface image data collection using a Basler vision camera with specialized lighting and KEYENCE displacement sensors, which are used to train deep learning models. Our approach employed image data generated from normal and two defect conditions to train eight deep learning algorithms: four custom convolutional neural networks (CNNs), two variations of VGG-16, and two variations of ResNet-50. The objective was to develop a computationally robust and efficient model by deploying global assessment metrics as evaluation criteria. Our results indicate that a variation of ResNet-50, ResNet-50, demonstrated the best overall efficiency, achieving an accuracy of 97.97%, a loss of 0.1030, and an average training step time of 839 milliseconds. However, in terms of computational efficiency, it was outperformed by one of the custom CNN models, CNN-240, which achieved an accuracy of 95.08%, a loss of 0.2753, and an average step time of 94 milliseconds, making CNN-240 a viable option for computational resource-sensitive environments.

摘要

近年来,由于人工智能(AI)具有强大的效率,其在工业应用中得到了广泛采用。图像故障检测和分类也已在工业中用于产品缺陷检测,以及使用人工智能来维持标准和优化流程。然而,对于光泽和曲面产品中人工智能故障检测性能的延迟存在严重担忧,因为它们的性质和反射表面阻碍了使用传统相机充分捕捉缺陷区域。因此,本研究提出了一种使用配备专门照明的Basler视觉相机和基恩士位移传感器来收集弯曲和光泽表面图像数据的增强方法,这些设备用于训练深度学习模型。我们的方法使用从正常和两种缺陷条件生成的图像数据来训练八种深度学习算法:四个定制卷积神经网络(CNN)、VGG - 16的两个变体和ResNet - 50的两个变体。目标是通过部署全局评估指标作为评估标准来开发一个计算强大且高效的模型。我们的结果表明,ResNet - 50的一个变体ResNet - 50表现出最佳的整体效率,准确率达到97.97%,损失为0.1030,平均训练步长时间为839毫秒。然而,在计算效率方面,它被定制CNN模型之一CNN - 240超越,CNN - 240的准确率为95.08%,损失为0.2753,平均步长时间为94毫秒,这使得CNN - 240成为对计算资源敏感环境的可行选择。

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