A neural network approach for the differentiation of numerical solutions of 3-D electromagnetic problems

Author

Capizzi, Giacomo ; Coco, Salvatore ; Giuffrida, Cinzia ; Laudani, Antonino

Author_Institution

Dipt. di Ingegneria Elettrica, Univ. di Catania, Italy

Volume

40

Issue

2

fYear

2004

fDate

3/1/2004 12:00:00 AM

Firstpage

953

Lastpage

956

Abstract

An innovative approach employing a neural network (NN) is presented to compute accurately derivatives and differential operators (such as Laplacian, gradient, divergence, curl, etc.) of numerical solutions of three-dimensional electromagnetic problems. The adopted NN is a multilayer perceptron, whose training is performed off-line by using a class of suitably selected polynomial functions. The desired degree of accuracy can be chosen by the user by selecting the appropriate order of the training polynomials. The on-line utilization of the trained NN allows us to obtain accurate results with a negligible computational cost. Comparative examples of differentiation performed both on analytical functions and finite element solutions are given in order to illustrate the computational advantages.

Keywords

differentiation; finite element analysis; neural nets; numerical analysis; 3-D electromagnetic problems; NN; analytical functions; computational advantages; differential operators; finite element solutions; multilayer perceptron; negligible computational cost; neural network approach; numerical differentiation; numerical solutions; on-line utilization; polynomial functions; postprocessing; training polynomials; Computational efficiency; Computer networks; Finite element methods; Laplace equations; Multilayer perceptrons; Neodymium; Neural networks; Performance analysis; Polynomials; Space technology;

fLanguage

English

Journal_Title

Magnetics, IEEE Transactions on

Publisher

ieee

ISSN

0018-9464

Type

jour

DOI

10.1109/TMAG.2004.824736

Filename

1284573