The Quasi-Periodic Centre-Saddle Bifurcation

Hanßmann, Heinz

doi:10.1006/jdeq.1997.3365

Cited by 46 publications

(59 citation statements)

References 32 publications

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“…Indeed, the same ratio and the whole bifurcation scenario may fall into a resonance gap. However, for most values of parameters s 3 , I 1 , I 3 the quasi-periodic centre-saddle bifurcations turn out to be present in the original dynamics [28].…”

Section: The Euler Topmentioning

confidence: 94%

“…This makes the phase space a ramified torus bundle, the regular fibres of n-tori forming families that are organized by families of invariant (n − 1)-tori, which in turn are organized by bifurcating (n − 1)-tori and by (n − 2)-tori and so on, down to the equilibria of the Hamiltonian system. In the case n = d of Lagrangean tori one can apply KAM theory directly to the integrable system, yielding persistence of the Lagrangean tori [2,8,20], of elliptic/hyperbolic lower dimensional tori [7,8,35] and of invariant tori 1 Mathematisch Instituut, Universiteit Utrecht, 3508 TA Utrecht, The Netherlands that undergo bifurcations [10,28,29]. Such results are valid under non-degeneracy conditions [30], the best-known being Kolmogorov's non-degeneracy condition which expresses that the frequency mapping from the families of Lagrangean tori to R d is a submersion.…”

Section: Introductionmentioning

confidence: 99%

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Perturbations of Superintegrable Systems

Hanβmann

2015

Acta Appl Math

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A superintegrable system has more integrals of motion than degrees d of freedom. The quasi-periodic motions then spin around tori of dimension n < d. Already under integrable perturbations almost all n-tori will break up; in the non-degenerate case the resulting d-tori have n fast and d − n slow frequencies. Such d-parameter families of d-tori do survive Hamiltonian perturbations as Cantor families of d-tori. A perturbation of a superintegrable system that admits a better approximation by a non-degenerate integrable perturbation of the superintegrable system is said to remove the degeneracy. In the minimal case d = n + 1 this can be achieved by means of averaging, but the more integrals of motion the superintegrable system admits the more difficult becomes the perturbation analysis.

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Section: The Euler Topmentioning

confidence: 94%

Section: Introductionmentioning

confidence: 99%

Perturbations of Superintegrable Systems

Hanβmann

2015

Acta Appl Math

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“…For the parabolic case we have mainly numerical indications for the behavior of the perturbed orbits; initial steps of a rigorous analysis of instabilities associated with PR are presented in [39] (a longer detailed version is in preparation). The behavior near a nonresonant parabolic torus does not yield instability-the lower dimensional parabolic torus persists [24]-and it appears that the behavior near it is indistinguishable from that appearing near the lower dimensional normally elliptic torus. However, numerical simulations indicate that the behavior near PR is dramatically different; orbits which appear to be chaotic and of a different nature than the homoclinic chaos are abundant.…”

Section: Qualitative Behavior Of the Near-integrable System (B)mentioning

confidence: 94%

“…Indeed, when λ p f is real and nonvanishing the corresponding family of tori is said to be normally hyperbolic, when it vanishes it is called normally parabolic, and when it is pure imaginary it is normally elliptic. For more details on the above see [33,2,5,12,13,14,15,21,22,23,24,26,44,3] and references therein. 4 Notice that a single torus belonging to this family has neutral stability in the actions directions.…”

Section: Formulation Consider a Near-integrable Hamiltonianmentioning

confidence: 99%

On Energy Surfaces and the Resonance Web

Litvak-Hinenzon¹,

Rom‐Kedar²

2004

SIAM J. Appl. Dyn. Syst.

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Abstract.A framework for understanding the global structure of near-integrable n DOF Hamiltonian systems is proposed. To this aim two tools are developed-the energy-momentum bifurcation diagrams and the branched surfaces. Their use is demonstrated on a few near-integrable 3 DOF systems. For these systems possible sources of instabilities are identified in the diagrams, and the corresponding energy surfaces are presented in the frequency space and by the branched surfaces. The main results of this formulation are theorems which describe the connection between changes in the topology of the energy surfaces and the existence of resonant lower dimensional tori. Key words. near-integrable Hamiltonians, parabolic resonances AMS subject classifications. 70H08, 37J20DOI. 10.1137/0306001061. Introduction. The study of the structure of energy surfaces of integrable systems and the study of resonances and instabilities in near-integrable systems developed into vast disparate research fields. The relation between the two received very little attention. Indeed, near regular level sets of the integrable Hamiltonian, the standard Arnold-resonance web structure appears, and the relation between the two fields reduces to the study of Arnold conjecture regarding instabilities in phase space. Here, we demonstrate that near singular level sets of the integrable Hamiltonian much information regarding possible instabilities of the near-integrable case may be deduced from the structure of the energy surface and its relations with resonance surfaces. We suggest that by adding some information to the traditional energy-momentum diagrams [7], which we name energy-momentum bifurcation diagrams (EMBD), one achieves a global qualitative understanding of the near-integrable dynamics. We relate the geometric properties of the surfaces corresponding to lower dimensional tori in this diagram to both bifurcations in the energy surface topology and the appearance of lower dimensional resonant tori.Recall that energy surfaces of generic integrable Hamiltonian systems are foliated almost everywhere by n-tori, 1 which may be expressed locally as a product of n circles on which the dynamics reduces to simple rotations (the action-angle coordinates). A given compact regular level set (the set of phase space points with given values of the constants of motion) may be composed of several such tori. The energy surface is composed of all level sets with the same

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“…We still have to show that the tori (15) persist under a small perturbation of (14). As only the relative sign between a(y 0 ) and b(y 0 ) is relevant we fix sgn b(y 0 ) = +1.…”

Section: Pitchfork Bifurcationsmentioning

confidence: 99%

Quasi-periodic bifurcations in reversible systems

Hanßmann

2010

Regul. Chaot. Dyn.

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Invariant tori of integrable dynamical systems occur both in the dissipative and in the conservative context, but only in the latter the tori are parametrised by phase space variables. This allows for quasi-periodic bifurcations within a single given system, induced by changes of the normal behaviour of the tori. It turns out that in a non-degenerate reversible system all semi-local bifurcations of co-dimension 1 persist, under small non-integrable perturbations, on large Cantor sets.

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The Quasi-Periodic Centre-Saddle Bifurcation

Cited by 46 publications

References 32 publications

Perturbations of Superintegrable Systems

Perturbations of Superintegrable Systems

On Energy Surfaces and the Resonance Web

Quasi-periodic bifurcations in reversible systems

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