Morphology-induced collective behaviors: dynamic pattern formation in water-floating elements

Complex systems involving many interacting elements often organize into patterns. Two types of pattern formation can be distinguished, static and dynamic. Static pattern formation means that the resulting structure constitutes a thermodynamic equilibrium whose pattern formation can be understood in...

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Veröffentlicht in:	PloS one 2012-06, Vol.7 (6), p.e37805-e37805
Hauptverfasser:	Nakajima, Kohei, Ngouabeu, Aubery Marchel Tientcheu, Miyashita, Shuhei, Göldi, Maurice, Füchslin, Rudolf Marcel, Pfeifer, Rolf
Format:	Artikel
Sprache:	eng
Schlagworte:	Artificial intelligence Biology Complex systems Containers Data mining Energy Energy conservation Engineering Entropy Equilibrium Experiments Floating structures Free energy Informatics Information theory Knowledge discovery Mathematics Models, Theoretical Morphology Motors Pattern formation Physics Polypeptides Studies Thermodynamic equilibrium Thermodynamics Triangles Vibration
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creator	Nakajima, Kohei Ngouabeu, Aubery Marchel Tientcheu Miyashita, Shuhei Göldi, Maurice Füchslin, Rudolf Marcel Pfeifer, Rolf
description	Complex systems involving many interacting elements often organize into patterns. Two types of pattern formation can be distinguished, static and dynamic. Static pattern formation means that the resulting structure constitutes a thermodynamic equilibrium whose pattern formation can be understood in terms of the minimization of free energy, while dynamic pattern formation indicates that the system is permanently dissipating energy and not in equilibrium. In this paper, we report experimental results showing that the morphology of elements plays a significant role in dynamic pattern formation. We prepared three different shapes of elements (circles, squares, and triangles) floating in a water-filled container, in which each of the shapes has two types: active elements that were capable of self-agitation with vibration motors, and passive elements that were mere floating tiles. The system was purely decentralized: that is, elements interacted locally, and subsequently elicited global patterns in a process called self-organized segregation. We showed that, according to the morphology of the selected elements, a different type of segregation occurs. Also, we quantitatively characterized both the local interaction regime and the resulting global behavior for each type of segregation by means of information theoretic quantities, and showed the difference for each case in detail, while offering speculation on the mechanism causing this phenomenon.
doi_str_mv	10.1371/journal.pone.0037805
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subjects	Artificial intelligence Biology Complex systems Containers Data mining Energy Energy conservation Engineering Entropy Equilibrium Experiments Floating structures Free energy Informatics Information theory Knowledge discovery Mathematics Models, Theoretical Morphology Motors Pattern formation Physics Polypeptides Studies Thermodynamic equilibrium Thermodynamics Triangles Vibration
title	Morphology-induced collective behaviors: dynamic pattern formation in water-floating elements
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