Title :
Deterministic chaos in atmospheric flows as a model for self-organised neural networks
Author_Institution :
Indian Inst. of Tropical Meteorol., Pune, India
Abstract :
A cell dynamical system model incorporating the physics of deterministic chaos in digital computer realizations of nonlinear mathematical models of dynamical systems is presented. The model shows that persistent microscopic domain perturbations generate, spontaneously, a continuum of logarithmic spiral circulations with the quasiperiodic Penrose tiling pattern for the internal small-scale circulation pattern with ordered energy flow between the scales. The neural network of the human brain is shown by the analogy to closely resemble the self-organized adaptive network of atmospheric flows comprising fluctuations ranging in size from millimeters to thousands of kilometers
Keywords :
artificial intelligence; chaos; fractals; neural nets; physics computing; atmospheric flows; cell dynamical system model; deterministic chaos; digital computer; fluctuations; human brain; internal small-scale circulation pattern; logarithmic spiral circulations; microscopic domain perturbations; nonlinear mathematical models; ordered energy flow; quasiperiodic Penrose tiling pattern; self-organised neural networks; self-organized adaptive network; Adaptive systems; Atmospheric modeling; Biological neural networks; Chaos; Fluctuations; Humans; Mathematical model; Microscopy; Physics computing; Spirals;
Conference_Titel :
Aerospace and Electronics Conference, 1990. NAECON 1990., Proceedings of the IEEE 1990 National
Conference_Location :
Dayton, OH
DOI :
10.1109/NAECON.1990.112937
