Validations from experimental testing of the capability of Neural Networks (NNs) in modelling dynamic magnetic hysteresis loops are presented. The NNs under test are components of a more complex Neural System (NS). Each NN is trained and used for managing just a specific part of the dynamic hysteresis loop. The whole hysteretic curve is recomposed by connecting the evaluations made by different NNs of the NS. Each NN consist of 3-input 1-output Feed Forward NN and models the hysteresis trajectories related to a sub-portion of the B-H plane. The input of the Neural System is the frequency of the exciting field, the flux density and the magnetic field strength. The NS has been tested on a non-oriented Fe-(3 wt%)Si laminations (thickness 0.35 mm) and results have shown that this approach is particularly able to model both static hysteresis and iron losses into a fixed range of frequencies of the exciting magnetic field
Laudani, A., RIGANTI FULGINEI, F., Ragusa, C., Salvini, A. (2014). Experimental Testing of a Neural Network approach for Dynamic Ferromagnetic Hysteresis. In CEFC 2014 - The sixteenth Biennial IEEE Conference on Electromagnetic Field Computation, Annecy, France, May 25-28, 2014.
Experimental Testing of a Neural Network approach for Dynamic Ferromagnetic Hysteresis
LAUDANI, ANTONINO;RIGANTI FULGINEI, Francesco;SALVINI, Alessandro
2014-01-01
Abstract
Validations from experimental testing of the capability of Neural Networks (NNs) in modelling dynamic magnetic hysteresis loops are presented. The NNs under test are components of a more complex Neural System (NS). Each NN is trained and used for managing just a specific part of the dynamic hysteresis loop. The whole hysteretic curve is recomposed by connecting the evaluations made by different NNs of the NS. Each NN consist of 3-input 1-output Feed Forward NN and models the hysteresis trajectories related to a sub-portion of the B-H plane. The input of the Neural System is the frequency of the exciting field, the flux density and the magnetic field strength. The NS has been tested on a non-oriented Fe-(3 wt%)Si laminations (thickness 0.35 mm) and results have shown that this approach is particularly able to model both static hysteresis and iron losses into a fixed range of frequencies of the exciting magnetic fieldI documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
