Title :
Perceptrons with polynomial post-processing
Author :
Sanzogni, Louis ; Bonner, Richard F. ; Chan, Ringo ; Vaccaro, John A.
Author_Institution :
Sch. of Inf. Syst. & Manage. Sci., Griffith Univ., Brisbane, Qld., Australia
Abstract :
Introduces tensor-product neural networks, composed of a layer of univariate neurons followed by a net of polynomial post-processing. We look at the general approximation problem by these networks observing in particular their relationship to the Stone-Weierstrass theorem for uniform function algebras. The implementation of the post-processing as a two-layer network with logarithmic and exponential neurons leads to potentially important ´generalised´ product networks which, however, require a complex approximation theory of the Müntz-Szasz-Ehrenpreis type. A backpropagation algorithm for product networks is presented and used in three computational experiments. In particular, approximation by a sigmoid product network is compared to that of a single-layer radial basis network and a multiple-layer sigmoid network.
Keywords :
approximation theory; backpropagation; perceptrons; polynomials; tensors; Muntz-Szasz-Ehrenpreis approximation theory; Stone-Weierstrass theorem; backpropagation algorithm; exponential neurons; generalised product networks; logarithmic neurons; multiple-layer sigmoid network; perceptrons; polynomial post-processing; sigmoid product network; single-layer radial basis network; tensor-product neural networks; two-layer network; uniform function algebras; univariate neurons; Algebra; Approximation methods; Computer networks; Information management; Management information systems; Neural networks; Neurons; Physics; Polynomials; Tensile stress;
Conference_Titel :
Tools with Artificial Intelligence, 1996., Proceedings Eighth IEEE International Conference on
Print_ISBN :
0-8186-7686-7
DOI :
10.1109/TAI.1996.560792
