Abstract
The maintenance of power quality in electrical power systems depends on addressing the major disturbances that may arise during generation, transmission and distribution. Many studies aim to investigate these disturbances by analyzing the behavior of the electrical signal through the classification of short circuit faults in power transmission lines as a way to assist the administration and maintenance of the electrical system. However, most fault classification methods generate a high computational cost that do not always yield satisfactory results; these methods utilize front ends in data processing before being processed by conventional classification algorithms such as Artificial Neural Network (ANN), Support Vector Machine (SVM), K-Nearest Neighbors (KNN), and Random Forest (RF) that are adopted into the Frame Based Sequence Classification (FBSC) architecture that uses the front ends Wavelet energy, Waveletconcat, RAW, Root Mean Square front ends (RMS) and Con cat Front End. An alternative method for classifying faults without having to use front ends employs the UFPAFaults database and the Hidden Markov Model (HMM) algorithm that directly treats the electrical signal in the form of multivariate time series. The results indicate the HMM algorithm as a potential classifier because its comparatively low error rate of 0.03% exceeds the performance of the conventional classifiers ANN, SVM, KNN and RF as used with the FBSC architecture. When the statistical test with a significance of α =5 % is applied, only the ANN and RF classifiers present a result close to what the HMM algorithm provides. Another relevant factor is that the HMM algorithm considerably decreases the computational cost by more than 90% of processing time as compared to the conventional classifiers of the FBSC architecture, thereby validating its potential in the direct classification of faults in electric power system transmission lines.
Highlights
The transmission line is the component of an Electric Power System (EPS) that is most vulnerable to faults, especially when considering that from one end to another, the line is subject to various diverse types of natural phenomena such as atmospheric discharge, forest fires, windstorms, and more
The Hidden Markov Model (HMM) algorithm was used, which allowed for the direct classification of an event without the use of pre-processing steps with multivariate characteristics of variable duration
The efficiency of the results was proven by comparing them with an architecture called Frame Based Sequence Classification (FBSC) developed to classify the faults from the UFPAFaults dataset
Summary
The transmission line is the component of an Electric Power System (EPS) that is most vulnerable to faults, especially when considering that from one end to another, the line is subject to various diverse types of natural phenomena such as atmospheric discharge, forest fires, windstorms, and more. The growing demand for electric power and the increase in consumption of electro-electronic equipment vulnerable to electrical disturbances entails a greater need for good, quality energy This reality requires that EPSs possess more acceptable configurations of the physical, operational, and control infrastructures that can help avoid and reduce electrical disturbances, hereafter referred to as short circuit faults in transmission lines [4]. The voltage or current waveforms undergo certain changes and deviate from their nominal values, resulting in the so-called quality of energy events
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