Application technique for model‐based approach to estimate fault location

Ananthan, Sundaravaradan Navalpakkam; Santoso, Surya

doi:10.1049/iet-stg.2019.0135

Cited by 4 publications

(1 citation statement)

References 30 publications

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“…Для этих целей могут использоваться методы машинного обучения, в частности аппарат искусственных нейронных сетей (ИНС) [7][8][9][11][12][13], как одна из основ искусственного интеллекта [14,15]. Эти инструменты могут использоваться для моделирования [24], обработки сигналов [17,20,23], анализа информационного обеспечения и информационного обмена в электросетевом оборудовании [16]. В полной мере это относится к устройствам релейной защиты и автоматики [26], задачам определения места повреждения [1,4,22].…”

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Accuracy Estimation for Operating Characteristics Neuromodeling of the Overcurrent Protection in a Three Phase Mains

Ivanov

Lariukhin²,

Nikandrov³

et al. 2021

Vestn. Čuv. univ.

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Modern electric power facilities-stations and high-voltage substations have become digital objects with the active use of high-speed local networks directly involved in the technological process. Management, analysis and control of information exchange in the digital substation of the power system require the development of new tools and approaches. For these purposes, machine learning methods can be used, in particular, the artificial neural networks. The paper presents the results of neural network modeling of the operation of the overcurrent protection – as a variant of the information exchange analysis. An elementary perceptron is used as a neural network with the simplest structure. The optimized structure of the neural network and estimates of the accuracy of the neural network algorithm are given, depending on the size of the training sample (from 1000 to 50000 records), the number of training epochs. It is shown that the analysis of the neural network algorithm errors encountered during testing of the neural network enables to estimate the threshold (the setting value) current protection depending on the size of the training sample. It is found that the recognition of the protection trigger threshold in neural network modeling is violated only when the all three phase currents in electrical mains are close to the threshold. The possibilities of improving the proposed approach and its use for detecting anomalies in the information exchange and operation of secondary equipment of digital substations of the power system are discussed.

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Accuracy Estimation for Operating Characteristics Neuromodeling of the Overcurrent Protection in a Three Phase Mains

Ivanov

Lariukhin²,

Nikandrov³

et al. 2021

Vestn. Čuv. univ.

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Novel system model‐based fault location approach using dynamic search technique

Ananthan

Bastos

Santoso

2021

IET Generation Trans & Dist

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Impedance-based fault location (IBFL) approaches are the most commonly used fault location methods in digital relays. However, each IBFL approach is designed specific to a line or network configuration and thus is not universal. For example, complex line configurations such as lines with mutual coupling between them and three-terminal lines have to employ individual IBFL algorithms derived specifically for them. Furthermore, they suffer from several sources of errors such as non-homogeneous system, and CT saturation. Hence, this paper presents a novel fault location approach that utilises a system model to overcome these limitations. The proposed model-based fault location (MBFL) approach estimates the fault location by identifying the closest match among various anticipated fault scenarios obtained using the system model and the actual fault scenario. It uses a dynamic search technique to implement the MBFL efficiently. A key highlight of the proposed approach is identifying the location of a fault on a neighbouring line using limited measurements, as few as only the through fault current flowing in a neighbouring line. The advantages of the approach and its practical applicability have been demonstrated by implementing it in complex network configurations as well as field data.

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