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RESEARCH PRODUCT
Analytical properties of horizontal visibility graphs in the Feigenbaum scenario
Alberto RobledoLucas LacasaBartolo LuqueFernando J. Ballesterossubject
Dynamical systems theoryMatemáticasGeneral Physics and AstronomyFOS: Physical sciencesLyapunov exponentDynamical Systems (math.DS)Fixed point01 natural sciencesAeronáutica010305 fluids & plasmassymbols.namesakeBifurcation theoryOscillometry0103 physical sciencesAttractorFOS: MathematicsEntropy (information theory)Computer SimulationStatistical physicsMathematics - Dynamical Systems010306 general physicsMathematical PhysicsMathematicsSeries (mathematics)Degree (graph theory)Applied MathematicsStatistical and Nonlinear Physics16. Peace & justiceNonlinear Sciences - Chaotic DynamicsNonlinear DynamicsPhysics - Data Analysis Statistics and ProbabilitysymbolsChaotic Dynamics (nlin.CD)AlgorithmsData Analysis Statistics and Probability (physics.data-an)description
Time series are proficiently converted into graphs via the horizontal visibility (HV) algorithm, which prompts interest in its capability for capturing the nature of different classes of series in a network context. We have recently shown [1] that dynamical systems can be studied from a novel perspective via the use of this method. Specifically, the period-doubling and band-splitting attractor cascades that characterize unimodal maps transform into families of graphs that turn out to be independent of map nonlinearity or other particulars. Here we provide an in depth description of the HV treatment of the Feigenbaum scenario, together with analytical derivations that relate to the degree distributions, mean distances, clustering coefficients, etc., associated to the bifurcation cascades and their accumulation points. We describe how the resultant families of graphs can be framed into a renormalization group scheme in which fixed-point graphs reveal their scaling properties. These fixed points are then re-derived from an entropy optimization process defined for the graph sets, confirming a suggested connection between renormalization group and entropy optimization. Finally, we provide analytical and numerical results for the graph entropy and show that it emulates the Lyapunov exponent of the map independently of its sign.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2012-03-01 |