Multipeakons and the Classical Moment Problem

Beals, Richard; Sattinger, D. H.; Szmigielski, Jacek

doi:10.1006/aima.1999.1883

Cited by 251 publications

(360 citation statements)

References 20 publications

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“…Rather, the point is that the local conserved quantities do not guarantee the existence of a priori bounds for the first derivative of the solutions u(x, t) to the CH equation. A careful analysis of the behavior of u x in peakon-antipeakon collisions appears in [5]. Finally, we note that Equations (26) We now classify all first-order nonlocal 7r-symmetries of the CH equation.…”

Section: Remarkmentioning

confidence: 88%

“…These compatible equations specify the relations between the dependent variables xf and the new dependent variables y b . Conversely, a set of equations of the form (7), which is compatible on solutions to the system S a = 0, determines a covering n = (y b ; Xa,; Di) where the differential operators Ó¿ are defined by means of (5).…”

Section: Nonlocal Symmetries Of Partial Differential Equationsmentioning

confidence: 99%

“…v ' dy so that [V 5 , V e ] = 0 only after the augmented system of Equations (23)- (27) is imposed. This observation reminds us of infernal symmetries, a notion we now recall following [3].…”

Section: Remarkmentioning

confidence: 99%

“…In other words, we change our viewpoint, from thinking of the CH equation (63) as a differential equation for u(x, t), to considering (63) as an integro-differential equation for m. This approach has proved to be crucial for the analytic study of the CH equation: it has been used to determine whether solutions to CH are global in time or represent breaking waves [13,15,36], and it appears prominently in Lenells' construction of conservation laws [33], in the study of (multi)peakon dynamics and weak solutions [5,10,14], in the scattering/inverse scattering approach to CH [4,5,17], and also in a rigorous proof that the "least action principie" holds for CH [16].…”

Section: We Provide Explicit Formulae For the Functions U(xtx) M(xmentioning

confidence: 99%

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Geometric Integrability of the Camassa–Holm Equation. II

Heredero

Reyes

2011

International Mathematics Research Notices

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It is known that the Camassa-Holm (CH) equation describes pseudo-spherical surfaces and that therefore its integrability properties can be studied by geometrical means. In particular, the CH equation admits nonlocal symmetries of "pseudo-potential type": the standard quadratic pseudo-potential associated with the geodesics of the pseudospherical surfaces determined by (generic) solutions to CH, allows us to construct a covering n of the equation manifold of CH on which nonlocal symmetries can be explicitly calculated. In this article, we present the Lie algebra of (first-order) nonlocal nsymmetries for the CH equation, and we show that this algebra contains a semidirect sum of the loop algebra over si(2, R) and the centerless Virasoro algebra. As applications, we compute explicit solutions, we construct a Darboux transformation for the CH equation, and we recover its recursion operator. We also extend our results to the associated Camassa-Holm equation introduced by J. Schiff.

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Section: Remarkmentioning

confidence: 88%

Section: Nonlocal Symmetries Of Partial Differential Equationsmentioning

confidence: 99%

Section: Remarkmentioning

confidence: 99%

Section: We Provide Explicit Formulae For the Functions U(xtx) M(xmentioning

confidence: 99%

See 2 more Smart Citations

Geometric Integrability of the Camassa–Holm Equation. II

Heredero

Reyes

2011

International Mathematics Research Notices

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“…The CH equation possesses soliton solutions, periodic finite-gap solutions [8], [10], [4], real finite-gap solutions [22] and, for ν = 0, multi-peakons [6]. In particular, the algebro-geometric solutions of (CH) are described as Hamiltonian flows on nonlinear subvarieties (strata) of generalized Jacobians.…”

Section: Introductionmentioning

confidence: 99%

Modulation of the Camassa-Holm equation and reciprocal transformations

Abenda

Грава

2005

Annales De L’institut Fourier

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We derive the modulation equations or Whitham equations for the Camassa-Holm (CH) equation. We show that the modulation equations are hyperbolic and admit bi-Hamiltonian structure. Furthermore they are connected by a reciprocal transformation to the modulation equations of the first negative flow of the Korteweg de Vries (KdV) equation. The reciprocal transformation is generated by the Casimir of the second Poisson bracket of the KdV averaged flow. We show that the geometry of the bi-Hamiltonian structure of the KdV and CH modulation equations is quite different: indeed the KdV averaged bi-Hamiltonian structure can always be related to a semisimple Frobenius manifold while the CH one cannot.

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Peakons, strings, and the finite Toda lattice

Beals

Sattinger

Szmigielski

2000

Comm. Pure Appl. Math.

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As is well-known, the Toda lattice flow may be realized as an isospectral flow of a Jacobi matrix. A bijective map from a discrete string problem with positive weights to Jacobi matrices allows the pure peakon flow of the Camassa-Holm equation to be realized as an isospectral Jacobi flow as well. This gives a unified picture of the Toda, Jacobi, and multipeakon flows, and leads to explicit solutions of the Jacobi flows via Stieltjes' determination of the continued fraction expansion of a Stieltjes transform. A simple modification produces a bijection from generalized strings, with positive and negative weights, to singular Jacobi matrices, and thus brings peakon/antipeakon flows into the same picture.

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Multipeakons and the Classical Moment Problem

Cited by 251 publications

References 20 publications

Geometric Integrability of the Camassa–Holm Equation. II

Geometric Integrability of the Camassa–Holm Equation. II

Modulation of the Camassa-Holm equation and reciprocal transformations

Peakons, strings, and the finite Toda lattice

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