http://de.evo-art.org/index.php?action=history&feed=atom&title=Self-Assembling_Dynamical_Hierarchies 2026-04-20T19:39:42Z Versionsgeschichte dieser Seite in de_evolutionary_art_org MediaWiki 1.27.4 http://de.evo-art.org/index.php?title=Self-Assembling_Dynamical_Hierarchies&diff=3248&oldid=prev 2015-01-13T12:13:32Z

<p>Die Seite wurde neu angelegt: „== Reference == <a href="/index.php?title=Alan_Dorin&amp;action=edit&amp;redlink=1" class="new" title="Alan Dorin (Seite nicht vorhanden)">Alan Dorin</a> and <a href="/index.php?title=Jon_McCormack" title="Jon McCormack">Jon McCormack</a>: <a href="/index.php?title=Self-Assembling_Dynamical_Hierarchies" title="Self-Assembling Dynamical Hierarchies">Self-Assembling Dynamical Hierarchies</a>. In: R. K. Standish, M. A. Bedau and H. A. Abbass (eds), Procee…“</p> <p><b>Neue Seite</b></p><div>== Reference ==<br /> [[Alan Dorin]] and [[Jon McCormack]]: [[Self-Assembling Dynamical Hierarchies]]. In: R. K. Standish, M. A. Bedau and H. A. Abbass (eds), Proceedings of the Eighth International Conference on Artificial Life (Artificial Life VIII), NSW, Australia, 9-13 December 2002, The MIT Press, London, England, ISBN: 0-262-69281-3, pp 423-428. <br /> <br /> == DOI ==<br /> <br /> == Abstract ==<br /> This paper addresses the open problem of assembling multi-<br /> levelled hierarchical structure. It presents a model of an in-<br /> finitely-levelled, self-assembling dynamical hierarchy which<br /> arises from the interaction of geometric primary elements<br /> with a fixed complexity. A formal description of the pre-<br /> sented hierarchy is derived. This quantifies the relative<br /> compression achieved by describing the system in terms of<br /> components of different organization. The relationship be-<br /> tween properties of representations and those of physical ob-<br /> jects is then discussed to support the view that at each level<br /> in the hierarchy presented, the components exhibit emergent<br /> properties not possessed by those at the levels below. It is<br /> concluded that these new properties are trivial and that such<br /> infinitely-levelled structures may be constructed easily.<br /> However since the definition of the problem in the literature<br /> admits such trivial possibilities, further discussion is re-<br /> quired to ensure “interesting” emergent properties are<br /> clearly distinguished from those that are not.<br /> <br /> == Extended Abstract ==<br /> <br /> == Bibtex == <br /> <br /> == Used References ==<br /> Baas, N.A. 1994. Emergence, Hierarchies and Hyper-<br /> structures, Proc. of Artificial Life III, Addison-Wesley,<br /> 515–537.<br /> <br /> Bealer, G. 1999. Property in The Cambridge Dictionary of<br /> Philosophy, 2nd edn., Audi (ed.), Cambridge Univ. Press,<br /> 751-752.<br /> <br /> Bedau, M.A., et.al. 2000. Open Problems in Artificial Life,<br /> Artificial Life, 6(4), MIT Press, 363–376.<br /> <br /> Bertalanffy, Ludwig von, 1968. General Systems Theory,<br /> Foundations, Development, Applications, revised edition,<br /> George Braziller Inc.<br /> <br /> Boulton, D.M. and Wallace, C.S. 1970. An information<br /> measure for hierarchic classification, The Computer Journal, 16(3), 254–261. <br /> <br /> Chaitin, G.J. 1987. Information Randomness &amp; Incom- <br /> pleteness, Papers on Algorithmic Information Theory, <br /> World Scientific. <br /> <br /> Chaitin, G.J. 1970. To A Mathematical Definition of<br /> ‘Life’, ACM, SICACT News 4, January 1970, 12-18.<br /> Dennett, D.C. 1991. Real Patterns, Journal of Philosophy,<br /> 88, 27–51.<br /> <br /> Dittrich, P., Ziegler, J., Banzhaf, W. 2001. Artificial<br /> Chemistries — A Review, Artificial Life, 7(3), MIT Press,<br /> 225–275.<br /> <br /> Dorin, A. 2000. Creating a Physically-based, Virtual Me-<br /> tabolism with Solid Cellular Automata, Proc. Artificial Life<br /> 7, Bedau, M. et al (eds), MIT Press, 13–20.<br /> <br /> Gardner, M. 1970. Mathematical Games: The Fantastic<br /> Combinations of John Conway’s New Solitaire Game<br /> ‘Life’, Scientific American, 223(4), 120–123.<br /> <br /> Gross, D., McMullin, B. 2001. Is it the Right Ansatz?, Ar-<br /> tificial Life, 7(4), MIT Press, 355–366.<br /> <br /> Hansen, N.R., 1958. Patterns of Discovery, Cambridge<br /> Univ. Press.<br /> <br /> Langton, C.G. 1986. Studying Artificial Life with Cellular<br /> Automata, Physica 22D, North-Holland, 120–149.<br /> <br /> Mirkin, B., McMorris, F. R., Roberts, F. S., Rzhetsky, A.,<br /> (ed’s) 1996. Mathematical Hierarchies and Biology,<br /> DIMACS Series in Discrete Mathematics and Theoretical<br /> Computer Science, Vol. 37, Am. Math. Soc.<br /> <br /> Nehaniv, C.L., Rhodes, J.L. 2000. The Evolution and Un-<br /> derstanding of Hierarchical Complexity in Biology from an<br /> Algebraic Perspective, Artificial Life, Vol. 6, No. 1, MIT<br /> Press, 45–68.<br /> <br /> Polanyi, M. 1968. Life’s Irreducible Structure, Science,<br /> 160(21) 1308–1312.<br /> <br /> Rasmussen, S., Baas, N.A., Mayer, B., Nilsson, M., Ole-<br /> sen, W. 2001a. Ansatz for Dynamical Hierarchies, Artifi-<br /> cial Life, 7(4), MIT Press, 329–354.<br /> <br /> Rasmussen, S., Baas, N.A., Mayer, B., Nilsson, M. 2001b.<br /> Defence of the Ansatz for Dynamical Hierarchies, Artificial<br /> Life, 7(4), MIT Press, 367–374.<br /> <br /> Simon, H.A. 1962. The Architecture of Complexity, Proc.<br /> Am. Phil. Soc., 106, 467–482.<br /> <br /> Simon, H.A. 1994. The Sciences of the Artificial, second<br /> edition, MIT Press.<br /> <br /> Tufte, E.R. 1990. Envisioning Information, Graphics Press.<br /> <br /> Wallace, C.S. and Boulton, D.M. 1968. An information<br /> measure for classification. The Computer Journal, 11(2),<br /> 185-194.<br /> <br /> <br /> == Links ==<br /> === Full Text === <br /> http://www.csse.monash.edu.au/%7Ealand/PAPERS/dynHier_ALIFE8_WWW.pdf<br /> <br /> [[intern file]]<br /> <br /> === Sonstige Links ===<br /> http://www.csse.monash.edu.au/%7Ealand/TALKS/alife8.html</div>

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