Abstract
Dynamics of arbitrary communication and software 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 dynamically random order, which leads to universally defined dynamical chaos, complexity, fractality, self-organisation, and adaptability. We demonstrate the origin of the huge, exponentially high efficiency of the unreduced, complex network and software dynamics and specify the universal symmetry of complexity as the fundamental guiding principle for creation and control of such qualitatively new kind of network and software systems. Practical aspects of ICT complexity transition are outlined.
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Kirilyuk, A., Salaün, M. (2006). Dynamic Complexity of Autonomic Communication and Software Systems. In: Gaïti, D. (eds) Network Control and Engineering for Qos, Security and Mobility, V. NetCon 2006. IFIP International Federation for Information Processing, vol 213. Springer, Boston, MA. https://doi.org/10.1007/978-0-387-34827-8_18
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DOI: https://doi.org/10.1007/978-0-387-34827-8_18
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