MOSAIK: A Formal Model for Self-Organizing Manufacturing Systems

In this article, we review past and current system architectures displaying self-organization in the domain of manufacturing. Based on a corpus of 84 reference papers, we find that multiagent systems (MAS) play a significant role in self-organization, especially MAS featuring bio-inspired algorithms...

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Veröffentlicht in:	IEEE pervasive computing 2021-01, Vol.20 (1), p.9-18
Hauptverfasser:	Charpenay, Victor, Schraudner, Daniel, Seidelmann, Thomas, Spieldenner, Torsten, Weise, Jens, Schubotz, Rene, Mostaghim, Sanaz, Harth, Andreas
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Sprache:	eng
Schlagworte:	Algorithms Biological system modeling Complexity theory Computer architecture Cyber-physical systems Manufacturing Multiagent systems Optimization Self-organizing networks Unified modeling language Workstations
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creator	Charpenay, Victor Schraudner, Daniel Seidelmann, Thomas Spieldenner, Torsten Weise, Jens Schubotz, Rene Mostaghim, Sanaz Harth, Andreas
description	In this article, we review past and current system architectures displaying self-organization in the domain of manufacturing. Based on a corpus of 84 reference papers, we find that multiagent systems (MAS) play a significant role in self-organization, especially MAS featuring bio-inspired algorithms for agent coordination. The emergence of new classes of cyber-physical systems further strengthens the prevalence of MAS on the subject. As outcome of our review, we devise the MOSAIK model, a generic model synthesizing all system architectures found in our corpus. The MOSAIK model can be used as a reference for formally comparing distinct architectures. We also use it to identify gaps for future research on self-organizing manufacturing systems. The model includes the central concepts of Agent and Artifact, which suggest that the Web is an adequate communication infrastructure for modern manufacturing systems: Agents become (autonomous) Web Agents and Artifacts become resources exposed by Web servers.
doi_str_mv	10.1109/MPRV.2020.3035837
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subjects	Algorithms Biological system modeling Complexity theory Computer architecture Cyber-physical systems Manufacturing Multiagent systems Optimization Self-organizing networks Unified modeling language Workstations
title	MOSAIK: A Formal Model for Self-Organizing Manufacturing Systems
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