Abstract mechanical connection and abelian reconstruction foralmost Kähler manifolds

Pekarsky, Sergey; Marsden, Jerrold E.

doi:10.1155/s1110757x01000043

Cited by 4 publications

(4 citation statements)

References 11 publications

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“…and I n (λ), n = 0, 1, 2 are the three roots of the cubic polynomial in (36) for which Aref and Pomphrey give explicit expressions [3]. From the theory of elliptic functions and integrals, (37) and (38) In general, some integral multiple of these time periods will be the time period T of the periodic orbit on the symplectic reduced space-the (I 1 , φ 1 ) space. Note that I 1 is proportional to the oriented area of the vortex triangle but I := (I 1 /I 2 ) 2 masks orientation information.…”

Section: Geometric Phase Formulamentioning

confidence: 99%

“…From the theory of elliptic functions and integrals, (37) and ( 38) are periodic with period equal to twice the complete elliptic integral of the first kind K(m), where m is the modulus of the elliptic function. Transforming to time t, the time period of the I variable is obtained as In general, some integral multiple of these time periods will be the time period T of the periodic orbit on the symplectic reduced space-the (I 1 , φ 1 ) space.…”

Section: Geometric Phase Formulamentioning

confidence: 99%

“…A noteworthy exception is Montgomery's work on phases in the dynamics of a free rigid body where, in addition to a geometric phase formula, a simple exact formula for the dynamic phase is obtained; see [32]. In the framework of Poisson reduction and in the framework of almost Kähler manifolds, respectively, Blaom [6] and Pekarsky and Marsden [38] have also obtained some general formulas for dynamic and geometric phases.…”

Section: Introduction: Symmetry and Reconstruction Phasesmentioning

confidence: 99%

See 2 more Smart Citations

Reconstruction phases in the planar three- and four-vortex problems

Hernández-Garduño

Shashikanth

2018

Nonlinearity

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Pure reconstruction phases-geometric and dynamic-are computed in the N -point-vortex model in the plane, for the cases N = 3 and N = 4. The phases are computed relative to a metric-orthogonal connection on appropriately defined principal fiber bundles. The metric is similar to the kinetic energy metric for point masses but with the masses replaced by vortex strengths. The geometric phases are shown to be proportional to areas enclosed by the closed orbit on the symmetry reduced spaces. More interestingly, simple formulae are obtained for the dynamic phases, analogous to Montgomery's result for the free rigid body, which show them to be proportional to the time period of the symmetry reduced closed orbits. For the case N = 3 a nonzero total vortex strength is assumed. For the case N = 4 the vortex strengths are assumed equal.

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Section: Geometric Phase Formulamentioning

confidence: 99%

Section: Geometric Phase Formulamentioning

confidence: 99%

Section: Introduction: Symmetry and Reconstruction Phasesmentioning

confidence: 99%

See 1 more Smart Citation

Reconstruction phases in the planar three- and four-vortex problems

Hernández-Garduño

Shashikanth

2018

Nonlinearity

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“…We mention this as a possible link to the notion of the abstract mechanical connection which is a Lie-algebra valued connection one-form deÿned on the phase space of a system with symmetry. This subject is explored in detail in the papers of Blaom (2000) and Pekarsky and Marsden (2001).…”

Section: Dynamic Phasementioning

confidence: 99%

Leapfrogging vortex rings: Hamiltonian structure, geometric phases and discrete reduction

Shashikanth¹,

Marsden²

2003

Fluid Dyn. Res.

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We present two interesting features of vortex rings in incompressible, Newtonian uids that involve their Hamiltonian structure.The ÿrst feature is for the Hamiltonian model of dynamically interacting thin-cored, coaxial, circular vortex rings described, for example, in the works of Dyson (Philos. Trans. Roy. Soc. London Ser. A 184 (1893) 1041) and Hicks (Proc. Roy. Soc. London Ser. A 102 (1922) 111). For this model, the symplectic reduced space associated with the translational symmetry is constructed. Using this construction, it is shown that for periodic motions on this reduced space, the reconstructed dynamics on the momentum level set can be split into a dynamic phase and a geometric phase. This splitting is done relative to a cotangent bundle connection deÿned for abelian isotropy symmetry groups. In this setting, the translational motion of leapfrogging vortex pairs is interpreted as the total phase, which has a dynamic and a geometric component.Second, it is shown that if the rings are modeled as coaxial circular ÿlaments, their dynamics and Hamiltonian structure is derivable from a more general Hamiltonian model for N interacting ÿlament rings of arbitrary shape in R 3 , where the mutual interaction is governed by the Biot-Savart law for ÿlaments and the self-interaction is determined by the local induction approximation. The derivation is done using the ÿxed point set for the action of the group of rotations about the axis of symmetry using methods of discrete reduction theory.

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Nonstandard Finite Difference Variational Integrators for Multisymplectic PDEs

Liao

Ding

2012

Journal of Applied Mathematics

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We use the idea of nonstandard finite difference methods to derive the discrete variational integrators for multisymplectic PDEs. We obtain a nonstandard finite difference variational integrator for linear wave equation with a triangle discretization and two nonstandard finite difference variational integrators for the nonlinear Klein-Gordon equation with a triangle discretization and a square discretization, respectively. These methods are naturally multisymplectic. Their discrete multisymplectic structures are presented by the multisymplectic form formulas. The convergence of the discretization schemes is discussed. The effectiveness and efficiency of the proposed methods are verified by the numerical experiments.

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Abstract mechanical connection and abelian reconstruction foralmost Kähler manifolds

Cited by 4 publications

References 11 publications

Reconstruction phases in the planar three- and four-vortex problems

Reconstruction phases in the planar three- and four-vortex problems

Leapfrogging vortex rings: Hamiltonian structure, geometric phases and discrete reduction

Nonstandard Finite Difference Variational Integrators for Multisymplectic PDEs

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