Presentation is loading. Please wait.

Presentation is loading. Please wait.

1 Mechanism for the Partial Synchronization in Coupled Logistic Maps  Cooperative Behaviors in Many Coupled Maps Woochang Lim and Sang-Yoon Kim Department.

Published byLogan Ellis Modified over 8 years ago

Similar presentations

Presentation on theme: "1 Mechanism for the Partial Synchronization in Coupled Logistic Maps  Cooperative Behaviors in Many Coupled Maps Woochang Lim and Sang-Yoon Kim Department."— Presentation transcript:

1 1 Mechanism for the Partial Synchronization in Coupled Logistic Maps  Cooperative Behaviors in Many Coupled Maps Woochang Lim and Sang-Yoon Kim Department of Physics Kangwon National University  Fully Synchronized Attractor for the Case of Strong Coupling Breakdown of the Full Synchronization via a Blowout Bifurcation Partial Synchronization (PS)Complete Desynchronization : Clustering

2 2  N Globally Coupled 1D Maps  Reduced Map Governing the Dynamics of a Three-Cluster State p i (=N i /N): “coupling weight factor” corresponding to the fraction of the total population in the ith cluster  Three-Cluster State Coupled Logistic Maps (Representative Model)  Reduced 3D Map  Globally Coupled Maps with Different Coupling Weight Investigation of the PS along a path connecting the symmetric and unidirectional coupling cases: p 2 =p 3 =p, p 1 =1-2p (0  p  1/3) p 1 =p 2 =p 3 =1/3  Symmetric Coupling Case  No Occurrence of the PS p 1 =1 and p 2 =p 3 =0  Unidirectional Coupling Case  Occurrence of the PS

3 3 Transverse Stability of the Fully Synchronized Attractor (FSA) Longitudinal Lyapunov Exponent of the FSA Transverse Lyapunov Exponent of the FSA For c>c * (=0.4398),  <0   FSA on the Main Diagonal Occurrence of the Blowout Bifurcation for c=c *  FSA: Transversely Unstable (  >0) for c<c * Appearance of a New Asynchronous Attractor Transverse Lyapunov exponent a=1.95 a=1.95, c=0.5

4 4 Type of Asynchronous Attractors Born via a Blowout Bifurcation  Unidirectional Coupling Case (p=0) Two-Cluster State: Transversely Stable   Partially Synchronized Attractor on the  23 Plane  Occurrence of the PS  Symmetric Coupling Case (p=1/3) Appearance of an Intermittent Two-Cluster State on the Invariant  23 Plane (  {(X 1, X 2, X 3 ) | X 2 =X 3 }) through a Blowout Bifurcation of the FSA Two-Cluster State: Transversely Unstable   Completely Desynchronized (Hyperchaotic) Attractor Filling a 3D Subspace (containing the main diagonal)  Occurrence of the Complete Desynchronization

5 5 Two-Cluster States on the  23 Plane  Reduced 2D Map Governing the Dynamics of a Two-Cluster State For numerical accuracy, we introduce new coordinates: Two-Cluster State: Unidirectional Coupling Case Symmetric Coupling Case

6 6 Threshold Value p * ( 0.146) s.t. 0  p<p *  Two-Cluster State: Transversely Stable (  <0)  Occurrence of the PS p * 0)  Occurrence of the Complete Desynchronization Transverse Stability of Two-Cluster States  Transverse Lyapunov Exponent of the Two-Cluster State (c  cc*)(c  cc*)

7 7 Mechanism for the Occurrence of the Partial Synchronization  Intermittent Two-Cluster State Born via a Blowout Bifurcation  Decomposition of the Transverse Lyapunov Exponent  of the Two-Cluster State Fraction of the Time Spent in the i Component (L i : Time Spent in the i Component) Transverse Lyapunov Exponent of the i Component (primed summation is performed in each i component) : Weighted Transverse Lyapunov Exponent for the Laminar (Bursting) Component d = |V|: Transverse Bursting Variable d * : Threshold Value s.t. d < d * : Laminar Component (Off State), d > d * : Bursting Component (On State). We numerically follow a trajectory segment with large length L (=10 8 ), and calculate its transverse Lyapunov exponent: d (t)

8 8 Threshold Value p * ( 0.146) s.t. 0p<p *0p<p * p * <p  1/3  Two-Cluster State: Transversely Stable  Occurrence of the PS Sign of  : Determined via the Competition of the Laminar and Bursting Components    Two-Cluster State: Transversely Unstable  Occurrence of the Complete Desynchronization (  : p=0,  : p=0.146,  : p=1/3)  Competition between the Laminar and Bursting Components  Laminar Component  Bursting Component a=1.95, d * =10 -4

9 9  Mechanism for the Occurrence of the Partial Synchronization in Coupled 1D Maps Sign of the Transverse Lyapunov Exponent of the Two-Cluster State Born via a Blowout Bifurcation of the FSA: Determined via the Competition of the Laminar and Bursting Components Summary  Two-Cluster State: Transversely Stable  Occurrence of the PS  Two-Cluster State: Transversely Unstable  Occurrence of the Complete Desynchronization

Download ppt "1 Mechanism for the Partial Synchronization in Coupled Logistic Maps  Cooperative Behaviors in Many Coupled Maps Woochang Lim and Sang-Yoon Kim Department."

Similar presentations

1 Riddling Transition in Unidirectionally-Coupled Chaotic Systems Sang-Yoon Kim Department of Physics Kangwon National University Korea Synchronization.

1 Riddling Transition in Unidirectionally-Coupled Chaotic Systems Sang-Yoon Kim Department of Physics Kangwon National University Korea Synchronization.
Globally-Coupled Excitatory Izhikevich Neurons Coupling-Induced Population Synchronization in An Excitatory Population of Subthreshold Izhikevich Neurons.

Globally-Coupled Excitatory Izhikevich Neurons Coupling-Induced Population Synchronization in An Excitatory Population of Subthreshold Izhikevich Neurons.
Dynamics of nonlinear parabolic equations with cosymmetry Vyacheslav G. Tsybulin Southern Federal University Russia Joint work with: Kurt Frischmuth Department.

Dynamics of nonlinear parabolic equations with cosymmetry Vyacheslav G. Tsybulin Southern Federal University Russia Joint work with: Kurt Frischmuth Department.
LOW-DIMENSIONAL COLLECTIVE CHAOS IN STRONGLY- AND GLOBALLY-COUPLED NOISY MAPS Hugues Chaté Service de Physique de L'Etat Condensé, CEA-Saclay, France Silvia.

LOW-DIMENSIONAL COLLECTIVE CHAOS IN STRONGLY- AND GLOBALLY-COUPLED NOISY MAPS Hugues Chaté Service de Physique de L'Etat Condensé, CEA-Saclay, France Silvia.
Summary N-body problem Globular Clusters Jackiw-Teitelboim Theory Poincare plots Chaotic Observables Symbolic Dynamics Some quick math Different Orbits.

Summary N-body problem Globular Clusters Jackiw-Teitelboim Theory Poincare plots Chaotic Observables Symbolic Dynamics Some quick math Different Orbits.
3-D State Space & Chaos Fixed Points, Limit Cycles, Poincare Sections Routes to Chaos –Period Doubling –Quasi-Periodicity –Intermittency & Crises –Chaotic.

3-D State Space & Chaos Fixed Points, Limit Cycles, Poincare Sections Routes to Chaos –Period Doubling –Quasi-Periodicity –Intermittency & Crises –Chaotic.
Re-examining the cascade problem: “... most of the time the system is completely stable, even in the face of external shocks. But once in a while, for.

Re-examining the cascade problem: “... most of the time the system is completely stable, even in the face of external shocks. But once in a while, for.
Introduction to chaotic dynamics

Introduction to chaotic dynamics
Dynamical Systems and Chaos Coarse-Graining in Time Low Dimensional Dynamical Systems Bifurcation Theory Saddle-Node, Intermittency, Pitchfork, Hopf Normal.

Dynamical Systems and Chaos Coarse-Graining in Time Low Dimensional Dynamical Systems Bifurcation Theory Saddle-Node, Intermittency, Pitchfork, Hopf Normal.
II. Towards a Theory of Nonlinear Dynamics & Chaos 3. Dynamics in State Space: 1- & 2- D 4. 3-D State Space & Chaos 5. Iterated Maps 6. Quasi-Periodicity.

II. Towards a Theory of Nonlinear Dynamics & Chaos 3. Dynamics in State Space: 1- & 2- D 4. 3-D State Space & Chaos 5. Iterated Maps 6. Quasi-Periodicity.
Analysis of the Rossler system Chiara Mocenni. Considering only the first two equations and ssuming small z The Rossler equations.

Analysis of the Rossler system Chiara Mocenni. Considering only the first two equations and ssuming small z The Rossler equations.
1 Universal Critical Behavior of Period Doublings in Symmetrically Coupled Systems Sang-Yoon Kim Department of Physics Kangwon National University Korea.

1 Universal Critical Behavior of Period Doublings in Symmetrically Coupled Systems Sang-Yoon Kim Department of Physics Kangwon National University Korea.
Renormalization and chaos in the logistic map. Logistic map Many features of non-Hamiltonian chaos can be seen in this simple map (and other similar one.

Renormalization and chaos in the logistic map. Logistic map Many features of non-Hamiltonian chaos can be seen in this simple map (and other similar one.
10/2/2015Electronic Chaos1 2009 Fall Steven Wright and Amanda Baldwin Special Thanks to Mr. Dan Brunski.

10/2/2015Electronic Chaos Fall Steven Wright and Amanda Baldwin Special Thanks to Mr. Dan Brunski.
Sparsely Synchronized Brain Rhythms in A Small-World Neural Network W. Lim (DNUE) and S.-Y. KIM (LABASIS)

Sparsely Synchronized Brain Rhythms in A Small-World Neural Network W. Lim (DNUE) and S.-Y. KIM (LABASIS)
Ch 9.8: Chaos and Strange Attractors: The Lorenz Equations

Ch 9.8: Chaos and Strange Attractors: The Lorenz Equations
Synchronization State Between Pre-turbulent Hyperchaotic Attractors G. Vidal H. Mancini Universidad de Navarra.

Synchronization State Between Pre-turbulent Hyperchaotic Attractors G. Vidal H. Mancini Universidad de Navarra.
1 Effect of Asymmetry on Blow-Out Bifurcations in Coupled Chaotic Systems  System Coupled 1D Maps: Invariant Synchronization Line: y = x  =0: Symmetrical.

1 Effect of Asymmetry on Blow-Out Bifurcations in Coupled Chaotic Systems  System Coupled 1D Maps: Invariant Synchronization Line: y = x  =0: Symmetrical.
11 Dynamical Routes to Clusters and Scaling in Globally Coupled Chaotic Systems Sang-Yoon Kim Department of Physics Kangwon National University  Globally.

11 Dynamical Routes to Clusters and Scaling in Globally Coupled Chaotic Systems Sang-Yoon Kim Department of Physics Kangwon National University  Globally.
Quantifying Chaos 1.Introduction 2.Time Series of Dynamical Variables 3.Lyapunov Exponents 4.Universal Scaling of the Lyapunov Exponents 5.Invariant Measures.

Quantifying Chaos 1.Introduction 2.Time Series of Dynamical Variables 3.Lyapunov Exponents 4.Universal Scaling of the Lyapunov Exponents 5.Invariant Measures.

Similar presentations

Ads by Google