Abstract
Abstract Nowadays, electrical power system is considered as one of the most complicated artificial systems all over the globe, as social and economic development depends on intact, consistent, stable and economic functions. Owing to diverse random causes, accidental failures occur in electrical power systems. Considering this issue, this article aimed to propose the use of deep belief network (DBN) in detecting and classifying fault signals such as transient, sag and swell in the transmission line. Here, wavelet-decomposed fault signals are extracted and the fault is diagnosed based on the decomposed signal by the DBN model. Further, this article provides the performance analysis by determining the types I and II measures and root-mean-square-error (RMSE) measure. In the performance analysis, it compares the performance of the DBN model to various conventional models like linear support vector machine (SVM), quadratic SVM, radial basis function SVM, polynomial SVM, multilayer perceptron SVM, Levenberg-Marquardt neural network and gradient descent neural network models. The simulation results validate that the proposed DBN model effectively detects and classifies the fault signal in power distribution system when compared to the traditional model.
Highlights
Since the demand for power is rising, lack of power generation is a fundamental problem in today’s life
The simulation results validate that the proposed deep belief network (DBN) model effectively detects and classifies the fault signal in power distribution system when compared to the traditional model
The experimentation is done at load of 10 Ă— 103 W, which is further varied to 20 Ă— 103 W, and the results are observed using the DBN model, revealing the behavior of fault signals such as transient, sag and swell signals at load variations
Summary
Since the demand for power is rising, lack of power generation is a fundamental problem in today’s life. Under such a circumstance, it is essential to make the best use of existing power transmission potential in a power system. The main factors like shortage of maintenance, equipment breakdown, fire, animals, trees, etc. Optimal diagnosis of the faulty phase, its location, and classification of signals is an essential task in the case of power transmission maintenance. Determination of fault location is necessary for the clearance of fault and the transmission of power restoration. Recognizing the type of fault is needed, and it is classified as line-to-line, single line-toground, multi-location, transforming and triple-line faults
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