Multi-Modal Data Fusion Using Deep Neural Network for Condition Monitoring of High Voltage Insulator

Mussina, Damira; Irmanova, Aidana; Jamwal, Prashant K.; Bagheri, Mehdi

doi:10.1109/access.2020.3027825

Cited by 24 publications

(10 citation statements)

References 40 publications

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“…In general, the literature shows an inadequate amount of work that has been devoted to train deep network architectures to classify and predict pollution levels non-intrusively. All the work done is either focused on applying deep learning models to intrusive measurement techniques [130,131] or applying classical machine learning using non-intrusive techniques [132][133][134][135]. More research is needed to combine deep learning models with non-intrusive approaches for monitoring, particularly those based on radiation type sensors.…”

Section: Contamination Diagnosismentioning

confidence: 99%

Deep Learning in High Voltage Engineering: A Literature Review

et al. 2022

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Condition monitoring of high voltage apparatus is of much importance for the maintenance of electric power systems. Whether it is detecting faults or partial discharges that take place in high voltage equipment, or detecting contamination and degradation of outdoor insulators, deep learning which is a branch of machine learning has been extensively investigated. Instead of using hand-crafted manual features as an input for the traditional machine learning algorithms, deep learning algorithms use raw data as the input where the feature extraction stage is integrated in the learning stage, resulting in a more automated process. This is the main advantage of using deep learning instead of traditional machine learning techniques. This paper presents a review of the recent literature on the application of deep learning techniques in monitoring high voltage apparatus such as GIS, transformers, cables, rotating machines, and outdoor insulators.

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Section: Contamination Diagnosismentioning

confidence: 99%

Deep Learning in High Voltage Engineering: A Literature Review

et al. 2022

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“…The triplet loss pushes the negative sample outside of the boundary by the margin and keeps the positive sample within the boundary. (6) The N-pair loss [57] is a generalization of triplet loss. It identifies a positive sample by comparing more than one negative sample, as shown in (6).…”

Section: Metric Loss Functionsmentioning

confidence: 99%

“…(6) The N-pair loss [57] is a generalization of triplet loss. It identifies a positive sample by comparing more than one negative sample, as shown in (6). z i , z j , z k are the anchor vector, negative vectors, and positive vector, respectively.…”

Section: Metric Loss Functionsmentioning

confidence: 99%

“…In the wake of superior performance in feature extraction and representation, deep learning has also been introduced into image recognition [4,5]. Mussina et al [6] consider integrating multimodal information fusion for classifying possible situations by a fully connected network. Jiang et al [7] propose multi-level perception to capture global and local representative features.…”

Section: Introductionmentioning

confidence: 99%

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Few-shot contrastive learning for image classification and its application to insulator identification

Jin

Huang

2021

Appl Intell

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This paper presents a novel discriminative Few-shot learning architecture based on batch compact loss. Currently, Convolutional Neural Network (CNN) has achieved reasonably good performance in image recognition. Most existing CNN methods facilitate classifiers to learn discriminating patterns to identify existing categories trained with large samples. However, learning to recognize novel categories from a few examples is a challenging task. To address this, we propose the Residual Compact Network to train a deep neural network to learn hierarchical nonlinear transformations to project image pairs into the same latent feature space, under which the distance of each positive pair is reduced. To better use the commonality of class-level features for category recognition, we develop a batch compact loss to form robust feature representations relevant to a category. The proposed methods are evaluated on several datasets. Experimental evaluations show that our proposed method achieves acceptable results in Few-shot learning.

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“…The use of advanced models to identify defects in insulators has been studied by several researchers. The convolutional neural network (CNN) architecture can present results of accuracy of up to 99.76% for the monitoring of insulators from aerial images [16]. For the detection of defects in insulators, modern combined models such as the ResNeSt and region pro-posal network (RPN) can be used.…”

Section: Introductionmentioning

confidence: 99%

Classification of insulators using neural network based on computer vision

Stefenon

Corso

Nied

et al. 2021

IET Generation Trans & Dist

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Insulators of the electrical power grid are usually installed outdoors, so they suffer from environmental stresses, such as the presence of contamination. Contamination can increase surface conductivity, which can lead to system failures, reducing the reliability of the network. The identification of insulators that have their properties compromised is important so that there are no discharges through its insulating body. To perform the classification of contaminated insulators, this paper presents computer vision techniques for the extraction of contamination characteristics, and a neural network (NN) model for the classification of this condition. Specifically, the Sobel edge detector, Canny edge detection, binarization with threshold, adaptive binarization with threshold, threshold with Otsu and Riddler–Calvard techniques will be evaluated. The results show that it is possible to have an accuracy of up to 97.50% for the classification of contaminated insulators from the extraction of characteristics with computer vision using the NN for the classification. The proposed model is more accurate than well‐established models such as support‐vector machine (SVM), k‐nearest neighbor (k‐NN), and ensemble learning methods. This showed that optimizing the model's parameters can make it superior to solve the problem in question.

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Multi-Modal Data Fusion Using Deep Neural Network for Condition Monitoring of High Voltage Insulator

Cited by 24 publications

References 40 publications

Deep Learning in High Voltage Engineering: A Literature Review

Deep Learning in High Voltage Engineering: A Literature Review

Few-shot contrastive learning for image classification and its application to insulator identification

Classification of insulators using neural network based on computer vision

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