Macroscopic models of collective motion and self-organization | Zendy

Pierre Degond | Zendy; Amic Frouvelle | Zendy; JianGuo Liu | Zendy; Sébastien Motsch | Zendy; Laurent Navoret | Zendy

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Macroscopic models of collective motion and self-organization

Author(s) -

Pierre Degond,

Amic Frouvelle,

JianGuo Liu,

Sébastien Motsch,

Laurent Navoret

Publication year - 2014

Publication title -

séminaire laurent schwartz — edp et applications

Language(s) - English

Resource type - Journals

ISSN - 2266-0607

DOI - 10.5802/slsedp.32

Subject(s) - self organization , collective motion , statistical physics , motion (physics) , limit (mathematics) , field (mathematics) , physics , classical mechanics , computer science , mathematics , artificial intelligence , mathematical analysis , pure mathematics

In this paper, we review recent developments on the derivation and properties of macroscopic models of collective motion and self-organization. The starting point is a model of self-propelled particles interacting with its neighbors through alignment. We successively derive a mean-field model and its hydrodynamic limit. The resulting macroscopic model is the Self-Organized Hydrodynamics (SOH). We review the available existence results and known properties of the SOH model and discuss it in view of its possible extensions to other kinds of collective motion.

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