Incipient Fault Detection in Power Distribution System: A Time–Frequency Embedded Deep-Learning-Based Approach

Li, Qiyue; Luo, Huan; Cheng, Hong; Deng, Yuxing; Sun, Wei; Li, Weitao; Liu, Zhi

doi:10.1109/tim.2023.3250220

Cited by 9 publications

(5 citation statements)

References 45 publications

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“…The article proposes an Adaptive Time-Frequency Memory (AD-TFM) cell embedded in Long Short-Term Memory (LSTM) to detect incipient faults in power distribution systems. The model, called the AD-TFM-AT model, uses learnable scale and translation parameters to detect faults in time and frequency domains [28].…”

Section: Lstmmentioning

confidence: 99%

Fault Detection and Fault Diagnosis in Power System Using AI: A Review

Nasim,

Aziz,

Qaiser

et al. 2024

SSURJET

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Electricity, which is essential to modern society, necessitates a consistent and uninterrupted supply. Faults in power systems pose difficulties, highlighting the vital importance of fault identification and diagnosis. This review paper provides a concise overview of artificial intelligence-based fault detection and diagnosis in power systems. The primary focus is on deep learning; on the one hand, it compares various works and acts as a primer for those who are unfamiliar with them. On the other hand, it delves into the application of UV-visible video processing to detect incipient faults by analyzing corona discharge and air ionization. Moreover, this state-of-the-art work highlights deep learning applications, particularly in UV-visible video processing, with the goal of detecting incipient faults through corona discharge and air ionization analysis. Despite ongoing research, the field lacks a clear path and structure, emphasizing the need for continued advancement in utilizing AI for effective fault detection and diagnosis in power systems.

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Section: Lstmmentioning

confidence: 99%

Fault Detection and Fault Diagnosis in Power System Using AI: A Review

Nasim,

Aziz,

Qaiser

et al. 2024

SSURJET

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“…As a vital component of these systems, the stability and safety of battery performance directly impact the reliability and economic efficiency of the entire system. Researchers have been dedicatedly analyzing changes in key parameters such as voltage, current, and temperature during the actual use of batteries, striving to predict the health status and potential fault types of batteries [21]- [23]. This analytical approach relies not only on traditional theoretical research based on physical and chemical models but also includes data-driven research utilizing advanced machine learning and signal processing technologies.…”

Section: A Battery Fault Detectionmentioning

confidence: 99%

“…Therefore, accurately monitoring the state of batteries and promptly detecting anomalies have become key technical challenges to ensure the safe operation of EVs. The non-stationarity and complex dynamics of battery charging data further increase the difficulty of monitoring, making traditional monitoring methods inadequate for practical applications [4]- [6].…”

Section: Introductionmentioning

confidence: 99%

Enhanced Wavelet Transform Dynamic Attention Transformer Model For Lithium-ion Battery Anomaly Detection

Liu,

Huang

2024

Preprint

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In the context of rapid advancements in electric vehicle (EV) technology, the safety and reliability of lithium-ion (Li) batteries,as the core power source, have garnered significant attention. The non-stationarity and complex dynamics of battery data posemajor challenges in the field of battery state monitoring, making it difficult for existing monitoring and prediction methods toaccurately address the variability of real-world environments. To address these issues, we propose a Transformer model based ona wavelet transform dynamic attention mechanism (WADT), capable of effectively handling the non-stationarity of battery dataand capturing its complex dynamic changes. The dynamic attention mechanism, grounded in wavelet transform, can adaptivelyfocus on the most informative parts of the battery data, thereby enhancing the accuracy of anomaly detection. Building on thismechanism, we further developed a deep learning model that incorporates an improved Transformer architecture, specificallydesigned to handle the complex dynamics of time series data. This model not only considers the temporal dependencies of batterydata but also adapts to its non-stationary behavior, achieving more accurate and reliable anomaly detection. Experimental resultson public battery datasets have demonstrated the effectiveness of our proposed approach. Compared to existing technologies, ourmodel has achieved significant improvements in several key performance indicators, including but not limited to accuracy, AUCscore. These results not only validate the innovation and effectiveness of our method but also showcase its potential applicationin the field of battery anomaly detection.

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“…To solve the restrictions of traditional relays, several methods were studied and proposed 8 – 20 such as the travelling method 8 – 11 , the Fourier transform 12 , 13 , and the Wavelet transform 14 – 16 .…”

Section: Introductionmentioning

confidence: 99%

“…The reason was the original signal has noise and high frequency effect The accuracy of the traveling wave is reduced when used in more complex electrical systems. It suitable for use in single end terminals Fourier transform 12 , 13 Can be used to analyze faults in high voltage power system Processing time and accuracy are good Usage conditions are limited by having to choose to analyze only frequencies or magnitudes on one-time domain Wavelet transform 14 – 16 Developed further from the Fourier transform. Fourier constraint has been solved which parameter of frequencies and magnitudes can be extracted on one-time domain It is widely used in research related to power systems and the performance is satisfactory Not suitable for analyzing large power systems Most analyzes are based on simulations only.…”

Section: Introductionmentioning

confidence: 99%

Development of overcurrent relay based on wavelet transform for fault detection in transmission line

Ananwattanaporn,

Lertwanitrot,

Ngaopitakkul

et al. 2024

Sci Rep

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This study proposes a protection relay using a microcontroller to detect and classify faults in transmission lines based on the wavelet transform. An experimental model was constructed from an actual 115 kV transmission system prototype. The current signal was observed based on the fault type, phase, and position. Clark’s transform and the discrete wavelet transform (DWT) were applied to transform signals for analysis. Moreover, the performance of fault detection based on the output signals of Clark’s transform (alpha sequence, beta sequence, and zero sequence current) was compared to the performance of the alternative proposed fault detection method, which is based on the combining factor between alpha and beta sequence current. In addition, the influence of DWT level on fault analysis is also considered and is used to confirm the accuracy of fault detection. Results show that the proposed method is efficient for fault detection and classification. This finding allows the researcher to choose the appropriate analytical method. Moreover, it can also be used as the basis for overcurrent relay algorithm design in the effort to develop more advanced technologies.

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Incipient Fault Detection in Power Distribution System: A Time–Frequency Embedded Deep-Learning-Based Approach

Cited by 9 publications

References 45 publications

Fault Detection and Fault Diagnosis in Power System Using AI: A Review

Fault Detection and Fault Diagnosis in Power System Using AI: A Review

Enhanced Wavelet Transform Dynamic Attention Transformer Model For Lithium-ion Battery Anomaly Detection

Development of overcurrent relay based on wavelet transform for fault detection in transmission line

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