Title :
Modeling complex systems by reaction-diffusion cellular nonlinear networks with polynomial weight-functions
Author :
Gollas, Frank ; Tetzlaff, Ronald
Author_Institution :
Inst. of Appl. Phys., Johann Wolfgang Goethe-Univ., Frankfurt, Germany
Abstract :
The treatment of reaction-diffusion differential equations leads to a description of various complex phenomena like nonlinear wave propagation or structure formation, in particular in biological systems. Reaction-diffusion cellular nonlinear networks (RD-CNN) can virtually represent any feature of reaction-diffusion systems. For RD-CNN it has been shown that the existence of locally active cells is a necessary condition for emergent complex behavior (Chua, 1998). In this contribution we use RD-CNN with polynomial reaction terms for modeling complex systems. First results for a RD-CNN modeling a FitzHugh-Nagumo system, with network parameters obtained by a supervised optimization process, are given.
Keywords :
cellular neural nets; differential equations; large-scale systems; optimisation; physiological models; reaction-diffusion systems; FitzHugh-Nagumo system; biological systems; complex system modeling; emergent complex behavior; nonlinear wave propagation; polynomial weight-function; reaction-diffusion cellular nonlinear networks; reaction-diffusion differential equations; reaction-diffusion systems; structure formation; supervised optimization; Biological system modeling; Biological systems; Cellular networks; Cellular neural networks; Differential equations; Laplace equations; Nonlinear wave propagation; Partial differential equations; Physics; Polynomials;
Conference_Titel :
Cellular Neural Networks and Their Applications, 2005 9th International Workshop on
Print_ISBN :
0-7803-9185-3
DOI :
10.1109/CNNA.2005.1543202
