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Detection of Ordered and Chaotic Motion using The Dynamical Spectra

Published online by Cambridge University Press:  12 April 2016

N. Voglis ,
G. Contopoulos  and
C. Efthymiopoulos
N. Voglis
Affiliation:
Department of Astronomy, University of Athens
G. Contopoulos
Affiliation:
Research Center for Astronomy, Academy of Athens Department of Astronomy, University of Athens
C. Efthymiopoulos
Affiliation:
Research Center for Astronomy, Academy of Athens Department of Astronomy, University of Athens

Abstract

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Two simple and efficient numerical methods to explore the phase space structure are presented, based on the properties of the “dynamical spectra”. 1) We calculate a “spectral distance” D of the dynamical spectra for two different initial deviation vectors. D → 0 in the case of chaotic orbits, while Dconst ≠ 0 in the case of ordered orbits. This method is by orders of magnitude faster than the method of the Lyapunov Characteristic Number (LCN). 2) We define a sensitive indicator called ROTOR (ROtational TOri Recongnizer) for 2D maps. The ROTOR remains zero in time on a rotational torus, while it tends to infinity at a rate ∝ N = number of iterations, in any case other than a rotational torus. We use this method to locate the last KAM torus of an island of stability, as well as the most important cantori causing stickiness near it.

Type
Analytical and Numerical Tools
Information
International Astronomical Union Colloquium , Volume 172: Impact of Modern Dynamics in Astronomy , 1999 , pp. 211 - 220
Copyright
Copyright © Kluwer 1999

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