2015
DOI: 10.1007/978-3-319-19015-0_3
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Orbital Stability: Analysis Meets Geometry

Abstract: ABSTRACT. We present an introduction to the orbital stability of relative equilibria of Hamiltonian dynamical systems on (finite and infinite dimensional) Banach spaces. A convenient formulation of the theory of Hamiltonian dynamics with symmetry and the corresponding momentum maps is proposed that allows us to highlight the interplay between (symplectic) geometry and (functional) analysis in the proofs of orbital stability of relative equilibria via the so-called energy-momentum method. The theory is illustra… Show more

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Cited by 31 publications
(71 citation statements)
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“…Then it has been developed, in the general context of Hamiltonian systems by Grillakis, Shatah, Strauss in [10], [11]. A clear and rigorous presentation of the method and its formalism in a general setting is given in the paper [7] of De Bièvre, Genoud, and Rota Nodari.…”
Section: Aliasing Generating Inhomogeneitymentioning
confidence: 99%
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“…Then it has been developed, in the general context of Hamiltonian systems by Grillakis, Shatah, Strauss in [10], [11]. A clear and rigorous presentation of the method and its formalism in a general setting is given in the paper [7] of De Bièvre, Genoud, and Rota Nodari.…”
Section: Aliasing Generating Inhomogeneitymentioning
confidence: 99%
“…There is at least one class of solutions that can be defined without ambiguity, the standing waves (i.e. when ξ 2 " 0) which are solutions of the form (7) @t 0 P R, @t P R, upt 0`t q " e iξ1t uptq.…”
Section: Introductionmentioning
confidence: 99%
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“…In [17] and [34], the theory is worked out in a Hilbert space setting, and when the symmetry group G is a one-dimensional Lie group. More recently, in [10], a version of the energy-momentum method has been presented for Hamiltonian dynamical systems on a Banach space E having as invariance group a Lie group G of arbitrary finite dimension. What is shown there is that the proof of orbital stability can be reduced to a "local coercivity estimate" on an appropriately constructed Lyapunov function L. It is shown in [10] that, in the above infinite dimensional setting, the construction of the latter follows naturally from the Hamiltonian structure and basic properties of the momentum map, in complete analogy with the finite dimensional situation.…”
Section: Introductionmentioning
confidence: 99%
“…More recently, in [10], a version of the energy-momentum method has been presented for Hamiltonian dynamical systems on a Banach space E having as invariance group a Lie group G of arbitrary finite dimension. What is shown there is that the proof of orbital stability can be reduced to a "local coercivity estimate" on an appropriately constructed Lyapunov function L. It is shown in [10] that, in the above infinite dimensional setting, the construction of the latter follows naturally from the Hamiltonian structure and basic properties of the momentum map, in complete analogy with the finite dimensional situation. In specific models, it then remains to show the appropriate local coercivity estimate on L which amounts to a lower bound on its Hessian restricted to an appropriate subspace of E (see (2.14)).…”
Section: Introductionmentioning
confidence: 99%