Anomaly Detection and Automatic Labeling for Solar Cell Quality Inspection Based on Generative Adversarial Network

Balzategui, Julen; Eciolaza, Luka; Maestro-Watson, Daniel

doi:10.3390/s21134361

Cited by 25 publications

(9 citation statements)

References 40 publications

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“…We have explored changing the architecture from the original proposal which has resulted in more precise segmentation. This technique adds another step in the methodology presented in [2] which completes the process to develop an inspection system by first using defect-free samples to generate an anomaly inspection model, then which will serve as automatic labeling to train a more accurate model, and now update the final model by incorporating new defect classes with few samples.…”

Section: Discussionmentioning

confidence: 99%

“…A possible alternative to avoid the need for defective samples may be to approach the problem from an anomaly detection perspective [1,2,3], where instead of creating the training set from defective samples, the set is generated using defect-free samples that are more accessible in a production line. However, as the objective of the unsupervised approach is to detect anomalous patterns which encompasses defective and non-defective patterns, it usually reports lower detection rates than supervised models that are strictly trained to detect only defective features.…”

Section: Introductionmentioning

confidence: 99%

“…In this work, we experiment with the incremental few-shot learning proposed in [15] in the industrial context of solar cell inspection where we try to update a model that has been trained on three base defect classes (i.e., cracks, microcracks, and finger interruptions) and incorporate new defects (i.e., black spots and bad soldering) such that the final model is able to segment five different defects. In this way, we will add another feature into the proposed anomaly detection based methodology [2] incorporating an adaptation stage for the supervised model to make it able to detect new types of defect classes that can arise during production, or also, incorporate features that were not previously considered important but for now on it should be controlled.…”

Section: Introductionmentioning

confidence: 99%

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Few-shot incremental learning in the context of solar cell quality inspection

Balzategui¹,

Eciolaza²

2022

Preprint

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In industry, Deep Neural Networks have shown high defect detection rates surpassing other more traditional manual feature engineering based proposals. This has been achieved mainly through supervised training where a great amount of data is required in order to learn good classification models. However, such amount of data is sometimes hard to obtain in industrial scenarios, as few defective pieces are produced normally. In addition, certain kinds of defects are very rare and usually just appear from time to time, which makes the generation of a proper dataset for training a classification model even harder. Moreover, the lack of available data limits the adaptation of inspection models to new defect types that appear in production as it might require a model retraining in order to incorporate the detects and detect them. In this work, we have explored the technique of weight imprinting in the context of solar cell quality inspection where we have trained a network on three base defect classes, and then we have incorporated new defect classes using few samples. The results have shown that this technique allows the network to extend its knowledge with regard to defect classes with few samples, which can be interesting for industrial practitioners.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Few-shot incremental learning in the context of solar cell quality inspection

Balzategui¹,

Eciolaza²

2022

Preprint

Self Cite

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“…In this case the autoencoder not only allowed the anomaly in PV modules be segmented, but it also facilitated defect detection. In another work a CNN based on generative adversarial network has been evaluated for detecting anomalies in solar cells [18]. Although tested on different datasets, such a network performs less satisfactorily with recall, precision and specificity averaging at 79%, 73% and 73% respectively.…”

Section: Defect Detection Based On Deep Learning Approachmentioning

confidence: 99%

Detection of microcracks and dark spots in monocrystalline PERC cells using photoluminescene imaging and YOLO-based CNN with spatial pyramid pooling

et al. 2022

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Two common defects encountered during manufacturing of crystalline silicon solar cells are microcrack and dark spot or dark region. The microcrack in particular is a major threat to module performance since it is responsible for most PV failures and other types of damage in the field. On the other hand, dark region in which one cell or part of the cell appears darker under UV illumination is mainly responsible for PV reduced efficiency, and eventually lost of performance. Therefore, one key challenge for solar cell manufacturers is to remove defective cells from further processing. Recently, few researchers have investigated deep learning as an alternative approach for defect detection in solar cell manufacturing. The results are quite encouraging. This paper evaluates the convolutional neural network based on heavy-weighted You Only Look Once (YOLO) version 4 or YOLOv4 and the tiny version of this algorithm referred here as Tiny-YOLOv4. Experimental results suggest that the multi-class YOLOv4 is the best model in term of mean average precision (mAP) and prediction time, averaging at 98.8% and 62.9 ms respectively. Meanwhile an improved Tiny-YOLOv4 with Spatial Pyramid Pooling scheme resulted in mAP of 91.0% and runtime of 28.2 ms. Even though the tiny-weighted YOLOv4 performs slightly lower compared to its heavy-weighted counterpart, however the runtime of the former is 2.2 order much faster than the later.

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“…However, this work is based on the fact that the GAN model is not trained on defected images, so it will reconstruct distorted images when the input contains defects, providing less control of the generation. In [20] the authors deploy a GAN-based model for detecting defects and anomalies on solar cell manufacturing. Although a novel approach for such a task, this work doesn't exploit the capabilities of GAN models for generating new samples, which is where GANs excel at.…”

Section: Introductionmentioning

confidence: 99%

A Novel Data Augmentation Method for Improved Visual Crack Detection Using Generative Adversarial Networks

2023

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Condition monitoring and inspection are core activities for assessing and evaluating the health of critical infrastructure spanning from road networks to nuclear power stations. Defect detection on visual inspections of such assets is a field that enjoys increasing attention. However, data-based models are prone to a lack of available data depicting cracks of various modalities and present a great data imbalance. This paper introduces a novel data augmentation technique by deploying the CycleGan Generative Adversarial Network (GAN). The proposed model is deployed between different image datasets depicting cracks, with a nuclear application as the main industrial example. The aim of this network is to improve the segmentation accuracy on these datasets using deep convolutional neural networks. The proposed GAN generates realistic images that are challenging to segment and under-represented in the original datasets. Different deep networks are trained with the augmented datasets while introducing no labelling overhead. A comparison is drawn between the performance of the different neural networks on the original data and their augmented counterparts. Extensive experiments suggest that the proposed augmentation method results in superior crack detection in challenging cases across all datasets. This is reflected by the respective increase in the quantitative evaluation metrics.

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Anomaly Detection and Automatic Labeling for Solar Cell Quality Inspection Based on Generative Adversarial Network

Cited by 25 publications

References 40 publications

Few-shot incremental learning in the context of solar cell quality inspection

Few-shot incremental learning in the context of solar cell quality inspection

Detection of microcracks and dark spots in monocrystalline PERC cells using photoluminescene imaging and YOLO-based CNN with spatial pyramid pooling

A Novel Data Augmentation Method for Improved Visual Crack Detection Using Generative Adversarial Networks

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