Machine Learning-Based Fault Location for Smart Distribution Networks Equipped with Micro-PMU

Mirshekali, Hamid; Dashti, Rahman; Keshavarz, Ahmad; Shaker, Hamid Reza

doi:10.3390/s22030945

Cited by 39 publications

(11 citation statements)

References 37 publications

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“…The outlined protection strategy relies on communication between overcurrent protections to detect faults, yet the findings are constrained to situations involving symmetrical faults. The authors in [51] focused on fault location in radial system using KNN and SVM based on the voltage of the faulty section and DG sources . In this study, the proposed approach can detect, classify and identify faulty lines in an entire ring system without requiring communication facilities or traditional protections relays.…”

Section: Research Gapmentioning

confidence: 99%

Fault Detection and Classification in Ring Power System With DG Penetration Using Hybrid CNN-LSTM

Alhanaf,

Farsadi,

Balik

2024

IEEE Access

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A modern electric power system integrated with advanced technologies such as sensors and smart meters is referred to as a "smart grid," aimed at enhancing electrical power delivery efficiency and reliability. However, fault location and prediction can become challenging when dynamic fault currents from renewable energy sources are present.To address these challenges, three unique deep learning models that make use of Deep Neural Networks (DNN) have been proposed. CNN, LSTM, and Hybrid CNN-LSTM are deep learning models. Line faulty identification (LF), fault classification (FC), and fault location estimate (FL) are the subjects on which they concentrate. These models analyze data gathered both pre and post faults occur in order to enhance decision making. Signals including the voltage and current were fed into these models from many different locations across the test networks. Once the 1D CNN has extracted characteristics from the gathered signals, LSTM uses these features to make accurate estimations and identify faults. Complex data are compatible with this method in terms of optimal outcomes. Using training and testing data from transmission line failure simulations, the proposed approaches were evaluated on the IEEE 6-bus and IEEE 9-bus systems. The tests encompassed a range of fault classes, locations, and ground fault resistances at various locations. Distributed Generator (DG) resources were additionally included in the system architecture and changes in the topology of the networks were considered in terms of location and number of DG resources .The results demonstrated that the proposed algorithms outperformed contemporary technologies in terms of detection, classification, and location accuracy. They demonstrated high accuracy and robustness in their performance.

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Section: Research Gapmentioning

confidence: 99%

Fault Detection and Classification in Ring Power System With DG Penetration Using Hybrid CNN-LSTM

Alhanaf,

Farsadi,

Balik

2024

IEEE Access

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“…For precise identification of fault in entire system support vector machine is introduced where transmission line faults that occurs in different locations can be identified using Fourier transform technique. Conversely the major disadvantage of the Fourier transformation (Mohanta et al, 2015) is the inherent compromise that exists between frequency and time resolution. By considering the aforementioned issues (Sobrinho et al, 2018; Adewole et al, 2016; Pignati et al, 2017; Prasad and Vinod Kumar, 2018; Della Giustina et al, 2014; Pal et al, 2017; Wu et al, 2015; Saha Roy et al, 2017; Saber et al, 2018; Jiang et al, 2012; Das et al, 2017; Chen and Liu, 2003; Li et al, 2016; Wu et al, 2018; Barman and Roy, 2018; Appasani and Mohanta, 2018; Carvalho et al, 2018; Cui et al, 2019; Mohanta et al, 2015), a new-fangled technique is introduced in power system line fault finding and localisation method for power grids, to precisely recognize and assess the location of the fault taking place anywhere in the network using PMU measurements.…”

Section: Scenario Of Grid Integration- Solar Cells and Wireless Systemsmentioning

confidence: 99%

Application of solar cells and wireless system for detecting faults in phasor measurement units using non-linear optimization

Manoharan¹,

Teekaraman

Kuppusamy³

et al. 2022

Energy Exploration & Exploitation

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This research study examines the integration of wireless system and solar cells for detection and location of faults in power grids by implementing minimum number of Phasor Measurement Units (PMUs) after considering zero injection buses. A fault in the grid networks indicates a failure in the entire network that interfaces the normal flow of current which can be measured using wireless systems. The fault location in power grid is problematic because of high existence in several lateral tap-offs. In addition, the identification of exact location with presence of faults in the power system and severity of the faults are challenging tasks due to bulk and complex nature of the electrical power system state estimation. The major requirement of PMU placement approach is to find the minimum number of PMUs and their location with maximum wireless coverage under fault conditions with a prerequisite for the projected algorithm. The integrated algorithm is tested and validated for different fault conditions where the results are compared with different conventional methods using different optimization models such as heuristics, decision rules and mathematical programming where the outcomes proves to be much effective in terms of number of PMU installation for proper placements and detection, location in number of fault systems thus achieving 82% reliability using Ant Lion Optimizer (ALO).

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“…The basic idea of machine learning is to parse data, find out from it, and apply what they have discovered to create informed decisions. For instance, in [13], to detect fault taking, recorded data of micro-phasor measurement units through BCF. The voltage signals' frequency component is then chosen as a feature vector.…”

Section: Literature Reviewmentioning

confidence: 99%

An Unbalance Three Phase Currents Detection Technique for Load Side Broken Conductor Fault in the Iraqi Distribution System

Al-Baghdadi¹,

Mohammed²,

Flaih³

2022

ETJ

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Machine Learning-Based Fault Location for Smart Distribution Networks Equipped with Micro-PMU

Cited by 39 publications

References 37 publications

Fault Detection and Classification in Ring Power System With DG Penetration Using Hybrid CNN-LSTM

Fault Detection and Classification in Ring Power System With DG Penetration Using Hybrid CNN-LSTM

Application of solar cells and wireless system for detecting faults in phasor measurement units using non-linear optimization

An Unbalance Three Phase Currents Detection Technique for Load Side Broken Conductor Fault in the Iraqi Distribution System

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