Title :
Diagnosing Faults in Power Transformers With Autoassociative Neural Networks and Mean Shift
Author :
Miranda, Vladimiro ; Castro, Adriana R Garcez ; Lima, Shigeaki
fDate :
7/1/2012 12:00:00 AM
Abstract :
This paper presents a new approach to incipient fault diagnosis in power transformers, based on the results of dissolved gas analysis. A set of autoassociative neural networks or autoencoders is trained, so that each becomes tuned with a particular fault mode or no fault condition. The scarce data available forms clusters that are densified using an Information Theoretic Mean Shift algorithm, allowing all real data to be used in the validation process. Then, a parallel model is built where the autoencoders compete with one another when a new input vector is entered and the closest recognition is taken as the diagnosis sought. A remarkable accuracy of 100% is achieved with this architecture, in a validation data set using all real information available.
Keywords :
fault diagnosis; neural nets; power engineering computing; power transformers; autoassociative neural networks; autoencoders; fault diagnosis; information theoretic mean shift algorithm; input vector; parallel model; power transformers; validation data set; validation process; Data compression; IEC standards; Manifolds; Neural networks; Power transformers; Training; Vectors; Autoassociative neural networks; dissolved gas analysis (DGA); information theoretic learning; mean shift; transformer fault diagnosis;
Journal_Title :
Power Delivery, IEEE Transactions on
DOI :
10.1109/TPWRD.2012.2188143
