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[Licence| Download | New Version Template] aegh_v1_0.tar.gz(782 Kbytes)
Manuscript Title: Code C# for chaos analysis of relativistic many-body systems
Authors: I.V. Grossu, C. Besliu, Al. Jipa, C.C. Bordeianu, D. Felea, E. Stan, T. Esanu
Program title: Chaos Many-Body Engine v01
Catalogue identifier: AEGH_v1_0
Distribution format: tar.gz
Journal reference: Comput. Phys. Commun. 181(2010)1464
Programming language: Visual C# .NET 2005.
Computer: PC.
Operating system: .Net Framework 2.0 running on MS Windows.
Has the code been vectorised or parallelized?: Each many-body system is simulated on a separate execution thread
RAM: 128 Megabytes
Keywords: object oriented programming, visual C#, Microsoft .Net framework, many-body, nonlinear dynamics, billiard nuclear models, chaos theory, virial theorem, nuclear fragmentation mechanism, Lyapunov exponent, Shannon entropy, Runge-Kutta algorithm.
PACS: 24.60.Lz, 05.45.a.
Classification: 6.2, 6.5.

External routines: .Net Framework 2.0 Library

Nature of problem:
Chaos analysis of three-dimensional, relativistic many-body systems.

Solution method:
Second order Runge-Kutta algorithm for simulating relativistic many-body systems. Object oriented solution, easy to reuse, extend and customize, in any development environment which accepts .Net assemblies or COM components. Implementation of: Lyapunov exponent, "fragmentation level", "average system radius", "virial coefficient", and energy conservation precision test.

Additional comments:
Easy copy/paste based deployment method.

Running time:
Quadratic complexity