Temporal-Quality Ensemble Technique for Handling Image Blur in Packaging Defect Inspection

Despite achieving numerous successes with surface defect inspection based on deep learning, the industry still faces challenges in conducting packaging defect inspections that include critical information such as ingredient lists. In particular, while previous achievements primarily focus on defect...

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Published in:Sensors (Basel, Switzerland) Switzerland), 2024-07, Vol.24 (14), p.4438
Main Authors: Son, Guk-Jin, Jung, Hee-Chul, Kim, Young-Duk
Format: Article
Language:English
Subjects:
Accuracy
Cameras
Deep learning
defect inspection
Defects
ensemble
image blur
packaging
temporal-quality analysis
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Jung, Hee-Chul
Kim, Young-Duk
description Despite achieving numerous successes with surface defect inspection based on deep learning, the industry still faces challenges in conducting packaging defect inspections that include critical information such as ingredient lists. In particular, while previous achievements primarily focus on defect inspection in high-quality images, they do not consider defect inspection in low-quality images such as those containing image blur. To address this issue, we proposed a noble inference technique named temporal-quality ensemble (TQE), which combines temporal and quality weights. Temporal weighting assigns weights to input images by considering the timing in relation to the observed image. Quality weight prioritizes high-quality images to ensure the inference process emphasizes clear and reliable input images. These two weights improve both the accuracy and reliability of the inference process of low-quality images. In addition, to experimentally evaluate the general applicability of TQE, we adopt widely used convolutional neural networks (CNNs) such as ResNet-34, EfficientNet, ECAEfficientNet, GoogLeNet, and ShuffleNetV2 as the backbone network. In conclusion, considering cases where at least one low-quality image is included, TQE has an F1-score approximately 17.64% to 22.41% higher than using single CNN models and about 1.86% to 2.06% higher than an average voting ensemble.
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subjects Accuracy
Cameras
Deep learning
defect inspection
Defects
ensemble
image blur
packaging
temporal-quality analysis
title Temporal-Quality Ensemble Technique for Handling Image Blur in Packaging Defect Inspection
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