A high impedance fault detector using a neural network and subband decomposition

Author

Keyhani, Reza ; Deriche, Mohamed ; Palmer, Ed

Author_Institution

Signal Process. Res. Centre, Queensland Univ. of Technol., Brisbane, Qld., Australia

Volume

2

fYear

2001

fDate

2001

Firstpage

458

Abstract

High impedance faults (HIFs) are not easily detectable using conventional overcurrent protection relays. The fault current for HIF is usually less than the normal load current, thus the overcurrent relays cannot easily distinguish HIFs from normal currents. A new method based on a subband decomposition of the current is presented. The energies from the different subbands are used as input to train an artificial neural network (ANN) for the detection of HIFs. The technique, not only detects HIF faults, but also classifies the signals into one of several classes. The main advantage of this method is that it is less sensitive to noise and HIF can be distinguished from similar events, even in the presence of high levels of noise

Keywords

electric impedance; fault currents; feedforward neural nets; learning (artificial intelligence); perceptrons; power system faults; power system protection; signal classification; time-frequency analysis; ANN; arcing phenomenon; artificial neural network; fault current; feedforward neural networks; high impedance fault detector; noise sensitivity; perceptron neural networks; power systems; signal classification; subband decomposition; time frequency analysis; Artificial neural networks; Australia; Circuit faults; Circuit simulation; Fault currents; Fault detection; Impedance; Neural networks; Power system harmonics; Signal processing;

fLanguage

English

Publisher

ieee

Conference_Titel

Signal Processing and its Applications, Sixth International, Symposium on. 2001

Conference_Location

Kuala Lumpur

Print_ISBN

0-7803-6703-0

Type

conf

DOI

10.1109/ISSPA.2001.950179

Filename

950179