Towards Sustainable Energy Efficiency With Intelligent Electricity Theft Detection in Smart Grids Emphasising Enhanced Neural Networks

Aldegheishem, Abdulaziz; Anwar, Mubbashra; Javaid, Nadeem; Alrajeh, Nabil; Shafiq, Muhammad; Ahmed, Hasan

doi:10.1109/access.2021.3056566

Cited by 49 publications

(32 citation statements)

References 52 publications

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“…The proposed architecture employs a generator based on DRN and a discriminator based on CNN to provide high reconstruction accuracy while sacrificing the computational complexity [95]. Reference [96] employs Wasserstein GAN with gradient penalty to capture the real distribution of the electricity consumption data for electricity theft detection. Reference [97] employs GAN for power loss mitigation of active distribution networks.…”

Section: F Deep Reinforced Models and Deep Unsupervised Learning 1) Deep Generative Models (Dgm)mentioning

confidence: 99%

Deep Learning in Smart Grid Technology: A Review of Recent Advancements and Future Prospects

et al. 2021

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The current electric power system witnesses a significant transition into Smart Grids (SG) as a promising landscape for high grid reliability and efficient energy management. This ongoing transition undergoes rapid changes, requiring a plethora of advanced methodologies to process the big data generated by various units. In this context, SG stands tied very closely to Deep Learning (DL) as an emerging technology for creating a more decentralized and intelligent energy paradigm while integrating high intelligence in supervisory and operational decision-making. Motivated by the outstanding success of DL-based prediction methods, this article attempts to provide a thorough review from a broad perspective on the state-of-the-art advances of DL in SG systems. Firstly, a bibliometric analysis has been conducted to categorize this review's methodology. Further, we taxonomically delve into the mechanism behind some of the trending DL algorithms. We then showcase the DL enabling technologies in SG, such as federated learning, edge intelligence, and distributed computing. Finally, challenges and research frontiers are provided to serve as guidelines for future work in the futuristic power grid domain. This study's core objective is to foster the synergy between these two fields for decision-makers and researchers to accelerate DL's practical deployment for SG systems. INDEX TERMSSmart grid, deep learning, deep neural networks, edge computing, distributed and federated learning, power systems. NOMENCLATURE Abbreviations DDL Distributed deep learning DL Deep learning DRL Deep reinforcement learning DRN Deep residual network EI Edge intelligence EPS Electric power systems FL Federated learning IoT Internet of things LSTM Long short-term memory neural network The associate editor coordinating the review of this manuscript and approving it for publication was Shadi Alawneh . NN Neural network PVPF Photovoltaic power forecasting D. RESEARCH METHODOLOGY AND SYSTEMATIC REVIEW PROTOCOLStarting from September 2019, the multiple-methods approach was conducted [24]. The collection of the mainstream research papers on SG/AI from Web of Science (WoS), Scopus, IEEE Xplore, Science Direct, and Google scholar was conducted as the largest databases of peerreviewed articles. Only peer-reviewed articles written in English, providing experimental results, and having a unique identifier from the mentioned databases were taken into consideration, including reviews, research articles, patent reports, and conference proceedings. The adopted methodology for conducting this review article employs a combination of keywords categorized into three main groups, specifically, 'Deep Learning', 'Smart Grid', and 'Prediction'. The search methodology focuses on the recent research articles from 2015-2020 to identify the comprehensive statues of the AI applications on SG. The filtering process results in 220 research papers from 600 related papers selected based on their relevance by reading the title, abstract, conclusion,

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Section: F Deep Reinforced Models and Deep Unsupervised Learning 1) Deep Generative Models (Dgm)mentioning

confidence: 99%

Deep Learning in Smart Grid Technology: A Review of Recent Advancements and Future Prospects

et al. 2021

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“…Its effect exceeded sigmoid in deeper networks, optimized the gradient dispersion problem of sigmoid in deeper networks, and established the position of convolutional neural network in deep learning. With the increase of data volume, the problems encountered become more and more complex, followed by more excellent models such as AlexNet [3] , VGG [4] , GoogleNet [5] and MobileNet [6] .…”

Section: Development Of Convolutional Neural Networkmentioning

confidence: 99%

Image recognition algorithms based on deep learning

Xie

Chen

et al. 2021

J. Phys.: Conf. Ser.

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Convolutional neural network is a very important research direction in deep learning technology. According to the current development of convolutional network, in this paper, convolutional neural networks are induced. Firstly, this paper induces the development process of convolutional neural network; then it introduces the structure of convolutional neural network and some typical convolutional neural networks. Finally, several examples of the application of deep learning is introduced.

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“…Tumen et al implemented the LSTM fraud detection algorithm [12], which excels the anomaly detector but does not automatically generate features [12]; therefore, there is a data selection module which attempts to select some data. Ahmed et al [13] implemented two algorithms that handle the issue that fraud data are imbalanced data. The authors use Python imbalance handling library SMOTEENN which performs oversampling by the SMOTE function and cleaning using ENN: "synthetic minority oversampling technique with edited nearest neighbor" [14].…”

Section: Introductionmentioning

confidence: 99%

An Energy-Fraud Detection-System Capable of Distinguishing Frauds from Other Energy Flow Anomalies in an Urban Environment

Calamaro¹,

Beck²,

Melech³

et al. 2021

Sustainability

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Energy fraud detection bears significantly on urban ecology. Reduced losses and power consumption would affect carbon dioxide emissions and reduce thermal pollution. Fraud detection also provides another layer of urban socio-economic correlation heatmapping and improves city energy distribution. This paper describes a novel algorithm of energy fraud detection, utilizing energy and energy consumption specialized knowledge poured into AI front-end. The proposed algorithm improves fraud detection’s accuracy and reduces the false positive rate, as well as reducing the preliminary required training dataset. The paper also introduces a holistic algorithm, specifying the major phenomena that disguises as energy fraud or affects it. Consequently, a mathematical foundation for energy fraud detection for the proposed algorithm is presented. The results show that a unique pattern is obtained during fraud, which is independent of a reference non-fraud pattern of the same customer. The theory is implemented on real data taken from smart metering systems and validated in real life scenarios.

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Towards Sustainable Energy Efficiency With Intelligent Electricity Theft Detection in Smart Grids Emphasising Enhanced Neural Networks

Cited by 49 publications

References 52 publications

Deep Learning in Smart Grid Technology: A Review of Recent Advancements and Future Prospects

Deep Learning in Smart Grid Technology: A Review of Recent Advancements and Future Prospects

Image recognition algorithms based on deep learning

An Energy-Fraud Detection-System Capable of Distinguishing Frauds from Other Energy Flow Anomalies in an Urban Environment

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