Abstract
Engineering of distributed computing systems requires understanding of principles of complex systems, which have not been yet identified. To address the situation we use a concept of structural complexity and present results of computational experiments suggesting the possibility of a general optimality condition of complex systems. The optimality condition introduces the structural complexity of a system as a key to its optimization.
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Allouche JP, Cosnard M (1985) Sequences generated by automata and dynamical systems. In: Dynamical systems and cellular automata, p 17. Academic, London
Ellinas D, Floratos EG, Prime decomposition and correlation measure of finite quantum systems. arXiv:quant-ph/9806007
Feigenbaum M (1980) Universal behaviour in nonlinear systems. Los Alamos Science 1:4
Fromm J, Ten questions about emergence. arXiv:nlin.AO/0509049, and references therein
Grobe R, Rzazewski K, Eberly JH (1994) Measure of electron–electron correlation in atomic physics. J Phys B 27:L503–L508
Gottlieb AD, Mauser NJ, New measure of electron correlation. arXiv:quant-ph/0503098
Korotkikh A (1999) Mathematical structure for emergent computation. Kluwer, Dordrecht
Korotkikh V (2003) The search for the Universal concept of complexity and a general optimality condition of cooperative agents. In: Butenko S, Murphey R, Pardalos PM (eds). Cooperative control: models, applications and algorithms. Kluwer, Dordrecht, pp 129–163
Korotkikh V (2004) An approach to the mathematical theory of perception-based information. In: Nikravesh M, Zadeh L, Korotkikh V (eds). Fuzzy partial differential equations and relational equations. Springer, Berlin, pp 80–115
Korotkikh V (2005) Integers: irreducible guides in the search for a unified theory. Braz J Phys, Special issue on Decoherence Inform Complex Entropy 35(2B):509–515
Korotkikh V, Korotkikh G (2004) On a new quantization in complex systems. In: Pardalos P, Sackellares C, Carney P, Iasemidis L (eds). Quantitative neuroscience: models, algorithms, diagnostics and therapeutic applications. Kluwer, Dordrecht, pp 71–91
Korotkikh V, Korotkikh G, On an irreducible theory of complex systems. arXiv:nlin.AO/0606023
Korotkikh V, Korotkikh G, Bond D, On optimality condition of complex systems: computational evidence. arXiv:cs.CC/0504092
Liu WC, Eberly JH, Haan SL, Grobe R (1999) Correlation effects in two-electron model atoms in intense laser fields. Phys Rev Lett 83 3:520–523
Reinelt G (2000) “TSPLIB”, version 1.2 (accessed 28/11/2000)
Sirovich L, Deane AE (1991) A computational study of Rayleigh-Benard convection. J Fluid Mech 222:251
Vautard R, Ghil M (1989) Singular spectrum analysis in nonlinear dynamics, with applications to paleoclimatic time series. In: Physica D: Nonlinear phenomena. Physica 35D, p 395. Elsevier Amsterdam
Zoldi SM, Greenside HS (1997) Karhunen-Loeve decomposition of extensive chaos. Phys Rev Lett 78:1687
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Korotkikh, V., Korotkikh, G. On principles in engineering of distributed computing systems. Soft Comput 12, 201–206 (2008). https://doi.org/10.1007/s00500-007-0191-x
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DOI: https://doi.org/10.1007/s00500-007-0191-x