Title :
Microwave characterization using ridge polynomial neural networks and least-square support vector machines
Author :
Hacib, T. ; Acikgoz, H. ; Le Bihan, Y. ; Meyer, O. ; Pichon, L.
Author_Institution :
Lab. LAMEL, Univ. Jijel., Ouled Aissa, Algeria
Abstract :
Motivated by the slow learning properties of multilayer perceptrons which utilize computationally intensive training algorithms and can get trapped in local minima, this work deals with ridge polynomial neural networks (RPNN) and least-square support vector machines (LSSVM) technique. RPNN and LSSVM are combined with the finite element method (FEM), to evaluate the dielectric materials properties. RPNN maintain fast learning properties and powerful mapping capabilities of single layer high order neural networks. LSSVM is a statistical learning method that has good generalization capability and learning performance. Experimental results show that LSSVM can achieve good accuracy and faster speed than those using conventional methods.
Keywords :
dielectric materials; electrical engineering computing; finite element analysis; learning (artificial intelligence); least squares approximations; neural nets; polynomials; support vector machines; FEM; LSSVM; dielectric materials properties; finite element method; intensive training algorithms; learning properties; least-square support vector machines; microwave characterization; multilayer perceptrons; ridge polynomial neural networks; Computer networks; Dielectric materials; Finite element methods; Machine learning; Multi-layer neural network; Multilayer perceptrons; Neural networks; Polynomials; Statistical learning; Support vector machines;
Conference_Titel :
Electromagnetic Field Computation (CEFC), 2010 14th Biennial IEEE Conference on
Conference_Location :
Chicago, IL
Print_ISBN :
978-1-4244-7059-4
DOI :
10.1109/CEFC.2010.5481797
