Complex Dynamics of Autonomous Communication Networks and the Intelligent Communication Paradigm

Kirilyuk, Andrei (2004) Complex Dynamics of Autonomous Communication Networks and the Intelligent Communication Paradigm. [Conference Paper] (Unpublished)

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Dynamics of arbitrary communication system is analysed as unreduced interaction process. The applied generalised, universally nonperturbative method of effective potential reveals the phenomenon of dynamic multivaluedness of competing system configurations forced to permanently replace each other in a causally random order, which leads to universally defined dynamical chaos, complexity, fractality, self-organisation, and adaptability. We demonstrate the origin of huge, exponentially high efficiency of the unreduced, complex network dynamics and specify the universal symmetry of complexity as the fundamental guiding principle for creation and control of such qualitatively new kind of networks and devices. The emerging intelligent communication paradigm and its practical realisation in the form of knowledge-based networks involve the properties of true, unreduced intelligence and consciousness ( appearing in the complex (multivalued) network dynamics and results.

Item Type:Conference Paper
Additional Information:12 pages, 24 eqs, 10 refs; two Annexes (7 and 5 pages) contain conference presentation versions
Keywords:Dynamical chaos, self-organisation, artificial intelligence, consciousness, knowledge-based network
Subjects:Computer Science > Dynamical Systems
Computer Science > Complexity Theory
Computer Science > Human Computer Interaction
ID Code:4114
Deposited By:Kirilyuk, Andrei
Deposited On:06 Mar 2005
Last Modified:11 Mar 2011 08:55

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1. Kirilyuk, A.P.: Universal Concept of Complexity by the Dynamic Redundance Paradigm: Causal Randomness, Complete Wave Mechanics, and the Ultimate Unification of Knowledge. Naukova Dumka, Kyiv (1997). For a non-technical overview see also e-print physics/9806002 at

2. Kirilyuk, A.P.: Dynamically multivalued self-organisation and probabilistic structure formation processes. Solid State Phenomena 97–98 (2004) 21–26; e-print physics/0405063.

3. Kirilyuk, A.P.: Universal symmetry of complexity and its manifestations at different levels of world dynamics. Proceedings of Institute of Mathematics of NAS of Ukraine 50 (2004) 821–828; e-print physics/0404006.

4. Kirilyuk, A.P.: The universal dynamic complexity as extended dynamic fractality: Causally complete understanding of living systems emergence and operation. In: Losa, G.A., Merlini, D., Nonnenmacher, T.F., and Weibel, E.R. (eds.): Fractals in Biology and Medicine. Vol. III. Birkhauser, Basel Boston Berlin (2002) 271–284; e-print physics/0305119.

5. Kirilyuk, A.P.: Emerging consciousness as a result of complex-dynamical interaction process. E-print physics/0409140.

6. Kirilyuk, A.P.: Theory of charged particle scattering in crystals by the generalized optical potential method. Nucl. Instr. and Meth. B 69 (1992) 200–231.

7. Kirilyuk, A.P.: Quantum chaos and fundamental multivaluedness of dynamical functions. Annales Fond. L. de Broglie 21 (1996) 455–480; quant-ph/9511034–36.

8. Kirilyuk, A.P.: Quantum field mechanics: Complex-dynamical completion of fundamental physics and its experimental implications. Nova Science, New York (accepted for publication). E-print physics/0401164.

9. Dederichs, P.H.: Dynamical diffraction theory by optical potential methods. In: Ehrenreich, H., Seitz, F., and Turnbull, D. (eds.): Solid state physics: Advances in research and applications, Vol. 27. Academic Press, New York (1972) 136–237.

10. Kirilyuk, A.P.: 75 years of the wavefunction: Complex-dynamical extension of the original wave realism and the universal Schroedinger equation. E-print quantph/0101129.


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