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dc.contributor.authorRouizi, Sarah-
dc.contributor.authorZella, Amalia-
dc.contributor.authorYkhlef, Hadjer ( Promotrice)-
dc.contributor.authorYkhlef, Farid ( Promoteur)-
dc.date.accessioned2022-09-25T11:25:19Z-
dc.date.available2022-09-25T11:25:19Z-
dc.date.issued2022-
dc.identifier.urihttps://di.univ-blida.dz/jspui/handle/123456789/19337-
dc.descriptionill., Bibliogr. Cote:ma-004-840fr_FR
dc.description.abstractLarge companies need to integrate a full fault detection system into their industry, especially electric companies. Consequently, automatic fault detection has become of utmost importance to assess the condition of electrical components and has been a long-standing challenge. Partial discharge is a common indication of faults in power systems, such as generators and cables. These PDs can eventually result in costly repairs and substantial power outages. The main goal of this work consists of devising a monitoring system capable of detecting partial discharge patterns in signals acquired from power lines. To accomplish this task, we have built and compared several detectors trained on hand-crafted features extracted using basic statistics and signal processing-based methods. These features are fed to a learning module; we have explored two kinds of learning paradigms: Sequential Learning and Ensemble-based Learning. Specifically, we have invoked four deep sequential models: Long-Short-Term-Memory (LSTM), Bidirectional LSTM (Bi-LSTM), Gated Recurrent Unit (GRU), Recurrent Neural Network (RNN), and four ensemble learning approaches namely: AdaBoost, Random Forest, LightGBM, and XGBoost. We have conducted our experiments on VSB power-linefaults-detection challenge dataset. Our experimental findings indicate that signal processing-based features do not improve the performance and that efficiently preprocessing signals achieves state-ofthe-art performance compared to other features extraction techniques. In addition, we have found that gated-based models (LSTMs and GRUs) have shown good results. Moreover, our analysis reveals that the gradient boosting machine (LightGBM, XGBoost) exhibits high scores compared with the other learning models. Most importantly, in order to build a successful fault detector, the focus has to shift from model-centric to data-centric, i.e. understand the input training data and preprocess it. Keywords: Anomaly detection, Partial discharge, Ensemble learning, Long Short Term Memory, Signal Processing.fr_FR
dc.language.isofrfr_FR
dc.publisherUniversité Blida 1fr_FR
dc.subjectAnomaly detectionfr_FR
dc.subjectPartial dischargefr_FR
dc.subjectEnsemble learningfr_FR
dc.subjectLong Short Term Memoryfr_FR
dc.subjectSignal Processingfr_FR
dc.titleAnomaly detection in power line signalsfr_FR
dc.typeThesisfr_FR
Collection(s) :Mémoires de Master

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