TY - CONF Y1 - 2009/// SN - 9780769535210 UR - https://www.scopus.com/inward/record.uri?eid=2-s2.0-65949118488&doi=10.1109%2fICCET.2009.171&partnerID=40&md5=2a8f020ea4d6cff2b0a70b5ed1d3a08e A1 - Desta Zahlay, F. A1 - Rao, K.S.R. VL - 2 EP - 155 AV - none N1 - cited By 5 N2 - This paper presents a method to discriminate a temporary fault from a permanent one in an extra high voltage (EHV) transmission line so that improper reclosing of the line onto a fault is avoided. The fault identification prior to reclosing is based on optimized artificial neural network associated with standard Error Back-Propagation, Levenberg Marquardt Algorithm and Resilient Back-Propagation training algorithms together with Taguchi's Method. The algorithms are developed using MATLAB software. A range of faults are simulated on EHV modeled transmission line using SimPowerSytems, and the spectra of the fault data are analyzed using fast Fourier transform to extract features of each type of fault. For both training and testing purposes, the neural network is fed with the normalized energies of the DC component, the fundamental and the first four harmonics of the faulted voltages. The developed algorithm is effectively trained, verified and validated with a set of training, dedicated testing and validation data respectively. © 2009 IEEE. KW - Artificial neural networks; Autoreclosure; EHV transmission line faults; Levenberg Marquardt algorithm; RPROP; Taguchi's method KW - Algorithms; Backpropagation; DC generators; Electric lines; Fast Fourier transforms; Feature extraction; MATLAB; Neural networks; Optimization; Transmission line theory KW - Electric fault location SP - 151 TI - Autoreclosure in extra high voltage lines using Taguchi's method and optimized neural networks ID - scholars725 ER -