dorsal/arxiv
View SchemaA General Systems Theory for Chaos, Quantum Mechanics and Gravity for Dynamical Systems of all Space-Time Scales
| Authors | A M Selvam |
|---|---|
| Categories | |
| ArXiv ID | physics/0503028 |
| URL | https://arxiv.org/abs/physics/0503028 |
Abstract
Non-local connections, i. e. long-range space-time correlations intrinsic to the observed subatomic dynamics of quantum systems is also exhibited by macro-scale dynamical systems as selfsimilar fractal space-time fluctuations and is identified as self-organized criticality. The author has developed a general systems theory for the observed self-organized criticality applicable to dynamical systems of all space-time scales based on the concept that spatial integration of enclosed small-scale fluctuations results in the formation of large eddy circulation. The eddy energy spectrum therefore represents the statistical normal distribution according to the Central Limit Theorem. The additive amplitudes of eddies, when squared (variance or eddy kinetic energy), represent the statistical normal (probability) distribution, a result observed in the subatomic dynamics of quantum systems. The model predicts Kepler's laws of planetary motion for eddy circulation dynamics. Inverse square law of gravitation therefore applies to the eddy continuum ranging from subatomic to macro-scale dynamical systems, e.g. weather systems. The model is similar to a superstring model for subatomic dynamics which unifies quantum mechanical and classical concepts and manifestation of matter is visualised as vibrational modes in string-like energy flow patterns. The cumulative sum of centripetal forces in a hierarchy of vortex circulations may result in the observed inverse square law form for gravitational attraction between inertial masses of the eddies.
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"abstract": "Non-local connections, i. e. long-range space-time correlations intrinsic to\nthe observed subatomic dynamics of quantum systems is also exhibited by\nmacro-scale dynamical systems as selfsimilar fractal space-time fluctuations\nand is identified as self-organized criticality. The author has developed a\ngeneral systems theory for the observed self-organized criticality applicable\nto dynamical systems of all space-time scales based on the concept that spatial\nintegration of enclosed small-scale fluctuations results in the formation of\nlarge eddy circulation. The eddy energy spectrum therefore represents the\nstatistical normal distribution according to the Central Limit Theorem. The\nadditive amplitudes of eddies, when squared (variance or eddy kinetic energy),\nrepresent the statistical normal (probability) distribution, a result observed\nin the subatomic dynamics of quantum systems. The model predicts Kepler\u0027s laws\nof planetary motion for eddy circulation dynamics. Inverse square law of\ngravitation therefore applies to the eddy continuum ranging from subatomic to\nmacro-scale dynamical systems, e.g. weather systems. The model is similar to a\nsuperstring model for subatomic dynamics which unifies quantum mechanical and\nclassical concepts and manifestation of matter is visualised as vibrational\nmodes in string-like energy flow patterns. The cumulative sum of centripetal\nforces in a hierarchy of vortex circulations may result in the observed inverse\nsquare law form for gravitational attraction between inertial masses of the\neddies.",
"arxiv_id": "physics/0503028",
"authors": [
"A M Selvam"
],
"categories": [
"physics.gen-ph"
],
"title": "A General Systems Theory for Chaos, Quantum Mechanics and Gravity for Dynamical Systems of all Space-Time Scales",
"url": "https://arxiv.org/abs/physics/0503028"
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