The fast Lyapunov indicators are functions defined on the tangent fiber of the phase-space of a discrete (or continuous) dynamical system by using a finite number of iterations of the dynamics. In the last decade, they have been largely used in numerical computations to localize the resonances in the phase-space and, more recently, also the stable and unstable manifolds of normally hyperbolic invariant manifolds. In this paper, we provide an analytic description of the growth of tangent vectors for orbits with initial conditions which are close to the stable-unstable manifolds of hyperbolic saddle points. The representation explains why the fast Lyapunov indicator detects the stable-unstable manifolds of all fixed points which satisfy a cer...
We present a new method for computing the global one-dimensional unstable manifold of a hyperbolic f...
Algorithms for computing stable manifolds of hyperbolic stationary solutions of autonomous systems a...
In two previous papers [J. Differential Equations, 228 (2006), pp. 530 579; Discrete Contin. Dyn. Sy...
The fast Lyapunov indicators are functions defined on the tangent fiber of the phase-space of a disc...
The Fast Lyapunov Indicators are functions defined on the tangent fiber of the phase–space of a disc...
In the last decades finite time chaos indicators have been used to compute the phase-portraits of co...
The stable and unstable manifolds of the Lyapunov orbits of the Lagrangian equilibrium points L1, L2...
The circular restricted three-body problem has five relative equilibria L1 , L2 , ..., L5. Theinvari...
Di\ufb00usion in generic quasi integrable systems at small values of the perturbing parameters has b...
We describe and compare two recent tools for detecting the geometry of resonances of a dynamical sys...
Many physical systems can be modeled through nonlinear time-invariant differential equations. When t...
Using numerical methods we study the hyperbolic manifolds in a model of a priori unstable dynamical ...
The circular restricted three-body problem has five relative equilibria L1,L2, ...,L5. The invariant...
The detection and identi\ufb01cation of resonances is a key ingredient in the studies of stability o...
The contribution describes some applications of the Fast Lyapunov Indicator to Hamiltonian Dynamics
We present a new method for computing the global one-dimensional unstable manifold of a hyperbolic f...
Algorithms for computing stable manifolds of hyperbolic stationary solutions of autonomous systems a...
In two previous papers [J. Differential Equations, 228 (2006), pp. 530 579; Discrete Contin. Dyn. Sy...
The fast Lyapunov indicators are functions defined on the tangent fiber of the phase-space of a disc...
The Fast Lyapunov Indicators are functions defined on the tangent fiber of the phase–space of a disc...
In the last decades finite time chaos indicators have been used to compute the phase-portraits of co...
The stable and unstable manifolds of the Lyapunov orbits of the Lagrangian equilibrium points L1, L2...
The circular restricted three-body problem has five relative equilibria L1 , L2 , ..., L5. Theinvari...
Di\ufb00usion in generic quasi integrable systems at small values of the perturbing parameters has b...
We describe and compare two recent tools for detecting the geometry of resonances of a dynamical sys...
Many physical systems can be modeled through nonlinear time-invariant differential equations. When t...
Using numerical methods we study the hyperbolic manifolds in a model of a priori unstable dynamical ...
The circular restricted three-body problem has five relative equilibria L1,L2, ...,L5. The invariant...
The detection and identi\ufb01cation of resonances is a key ingredient in the studies of stability o...
The contribution describes some applications of the Fast Lyapunov Indicator to Hamiltonian Dynamics
We present a new method for computing the global one-dimensional unstable manifold of a hyperbolic f...
Algorithms for computing stable manifolds of hyperbolic stationary solutions of autonomous systems a...
In two previous papers [J. Differential Equations, 228 (2006), pp. 530 579; Discrete Contin. Dyn. Sy...