Citation
Asatiani, P. and Chavchanidze, V. (2010), "Introduction to unitary physical and mathematical modelling of information system", Kybernetes, Vol. 39 No. 1. https://doi.org/10.1108/k.2010.06739aab.001
Publisher
:Emerald Group Publishing Limited
Copyright © 2010, Emerald Group Publishing Limited
Introduction to unitary physical and mathematical modelling of information system
Article Type: Communications and forum From: Kybernetes, Volume 39, Issue 1
As well as it is known, the twenty-first century enters a new phase of the mankind development history-information society whose basic resource and product is information.
At the same time, the development of information technology initiates information nature studying (Prigogine, 2001, 1984, 1980; Prangishvili, 2000; Platt, 1958; Asatiani, 2005, 2009; Bohr, 1955; Lloyd and Jack Ng, 2005; Lopes da Silva and van Rotterdam, 1982; Hudson, 1967) and informatiology as a system of relations and interactions (particle-particle, object-observer-man-computer, etc.) revealing at the same time the Bohr’s (1955) unity of knowledge system with Prigogine (1984, 1980) phase fluctuation transitions between chaos and order states which open a way to unitary physical and mathematical modelling of information system. In this modelling development process, as investigations show (Asatiani, 1977, 2005), the superfluids physics with its universal mathematical apparatus shows productive unitary application to information system modelling according to Prigogine’s (1984, 1980) order-chaos approach. As well as it is known the superfluids (helium and superconductors) (London, 1950; Asatiani, 1977) show the similar behaviour as a quantum superposition of normal (chaotic) and superfluid (order) states with phase fluctuation transitions between the states (Patashinsky and Pokroysky, 1975) too. This approach is extrapolated now in different fields of non-organic, biological and semantic information systems (Platt, 1958; Asatiani, 1977, 2005; London, 1950; Lopes da Silva and van Rotterdam, 1982) directly connected at the same time with entropy processes as quantum zero (order) and non-zero (normal, chaotic) entropy states superposition.
The semantic physical modelling of information systems has begun through condensed matter (superfluids) physics investigations in 1969-1998 in E. Andronikashvili – P. Kapitza international school founded by Nobel Prize winner Lord E. Rutherford and continue today (Asatiani, 1977, 2005, 2009).
At the same time, the Georgian School of Cybernetics under leadership of Chavchanidze (1970) has independently conducted quantum-coherent wave modelling of information nets and systems. Now, the superfluid modelling and mentioned quantum-coherent wave modelling of information nets and systems are united in works of Asatiani (1977, 2005) introducing unitary two-fluid (superfluid) dispersion model of information system with macroscopic wave function transferred from superfluids to information system.
Generalizing quantum hydrodynamics of superfluids (Asatiani, 2009) in the language of mentioned wave function and using (Hudson, 1967) correlation between mathematical expectation of wave function and measure of dispersion of random variables Asatiani (2009) gets interesting results. All the latest experimentally proved dispersion theories known for us are covered in a striking way by the unitary two-fluid (superfluid) dispersion model curve in two-dimensional coordinate system: mathematical expectation of wave function depending on measure of dispersion random variables of unitary information system (Platt, 1958; London, 1950; Patashinsky and Pokroysky, 1975; Prigogine, 1980; Lloyd and Jack Ng, 2005; Lopes da Silva and van Rotterdam, 1982; Hudson, 1967), taking into account frequency resonant origin of these probabilistic dispersion information processes distinctive for our Universe.
The proposed model also shows very interesting application in the early Universe formation description using structural factor of relict helium relating to phonon-photon correlations in information processes and regulating the probabilistic processes of the Universe development as a singular computer (Lloyd and Jack Ng, 2005) in a cosmic symphony of the Universe (Lloyd and Jack Ng, 2005; Scientific American, May 2004).
P. Asatiani and V. Chavchanidze
Acknowledgements
Communications to this section are not “peer-reviewed” and are published as soon as possible. The journal does not necessarily agree with the contributors and invites readers to respond with their own views.
Pavle Asatiani is the corresponding author and can be contacted at: pavleasatiani@mail.ru
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