Your search keyword '"37K05, 37K10, 37K20, 37K25"' showing total 12 results

1. Classification of non-homogeneous multidimensional Hamiltonian operators

Author

Rizzo, Alessandra

Subjects

Mathematical Physics, Nonlinear Sciences - Exactly Solvable and Integrable Systems, 37K05, 37K10, 37K20, 37K25

Abstract

In this paper, we study Hamiltonian operators which are sum of a first order operator and of a Poisson tensor, in two spatial independent variables. In particular, a complete classification of these operators is presented in two and three components, analyzing both the cases of degenerate and non degenerate leading coefficients.

Published

2024

2. Miura-reciprocal transformations and localizable Poisson pencils

Author

Lorenzoni, P., Shadrin, S., and Vitolo, R.

Subjects

Mathematical Physics, 37K05, 37K10, 37K20, 37K25

Abstract

We show that the equivalence classes of deformations of localizable semisimple Poisson pencils of hydrodynamic type with respect to the action of the Miura-reciprocal group contain a local representative and are in one-to-one correspondence with the equivalence classes of deformations of local semisimple Poisson pencils of hydrodynamic type with respect to the action of the Miura group., Comment: 27 pages

Published

2023

3. WDVV equations and invariant bi-Hamiltonian formalism

Author

Vašíček, Jakub and Vitolo, Raffaele

Subjects

Mathematical Physics, High Energy Physics - Theory, Nonlinear Sciences - Exactly Solvable and Integrable Systems, 37K05, 37K10, 37K20, 37K25

Abstract

The purpose of the paper is to show that, in low dimensions, the WDVV equations are bi-Hamiltonian. The invariance of the bi-Hamiltonian formalism is proved for $N=3$. More examples in higher dimensions show that the result might hold in general. The invariance group of the bi-Hamiltonian pairs that we find for WDVV equations is the group of projective transformations. The significance of projective invariance of WDVV equations is discussed in detail. The computer algebra programs that were used for calculations throughout the paper are provided in a GitHub repository., Comment: 37 pages, no figures

Published

2021

4. On a class of third-order nonlocal Hamiltonian operators

Author

Casati, M., Ferapontov, E. V., Pavlov, M. V., and Vitolo, R. F.

Subjects

Mathematical Physics, Mathematics - Differential Geometry, Nonlinear Sciences - Exactly Solvable and Integrable Systems, 37K05, 37K10, 37K20, 37K25

Abstract

Based on the theory of Poisson vertex algebras we calculate skew-symmetry conditions and Jacobi identities for a class of third-order nonlocal operators of differential-geometric type. Hamiltonian operators within this class are defined by a Monge metric and a skew-symmetric two-form satisfying a number of differential-geometric constraints. Complete classification results in the 2-component and 3-component cases are obtained., Comment: 19 pages

Published

2018

5. Systems of conservation laws with third-order Hamiltonian structures

Author

Ferapontov, E. V., Pavlov, M. V., and Vitolo, R. F.

Subjects

Nonlinear Sciences - Exactly Solvable and Integrable Systems, Mathematical Physics, Mathematics - Differential Geometry, 37K05, 37K10, 37K20, 37K25

Abstract

We investigate $n$-component systems of conservation laws that possess third-order Hamiltonian structures of differential-geometric type. The classification of such systems is reduced to the projective classification of linear congruences of lines in $\mathbb{P}^{n+2}$ satisfying additional geometric constraints. Algebraically, the problem can be reformulated as follows: for a vector space $W$ of dimension $n+2$, classify $n$-tuples of skew-symmetric 2-forms $A^{\alpha} \in \Lambda^2(W)$ such that \[ \phi_{\beta \gamma}A^{\beta}\wedge A^{\gamma}=0, \] for some non-degenerate symmetric $\phi$., Comment: 31 pages

Published

2017

6. Remarks on the Lagrangian representation of bi-Hamiltonian equations

Author

Pavlov, M. V. and Vitolo, R. F.

Subjects

Mathematical Physics, Mathematics - Differential Geometry, Nonlinear Sciences - Exactly Solvable and Integrable Systems, 37K05, 37K10, 37K20, 37K25

Abstract

The Lagrangian representation of multi-Hamiltonian PDEs has been introduced by Y. Nutku and one of us (MVP). In this paper we focus on systems which are (at least) bi-Hamiltonian by a pair $A_1$, $A_2$, where $A_1$ is a hydrodynamic-type Hamiltonian operator. We prove that finding the Lagrangian representation is equivalent to finding a generalized vector field $\tau$ such that $A_2=L_\tau A_1$. We use this result in order to find the Lagrangian representation when $A_2$ is a homogeneous third-order Hamiltonian operator, although the method that we use can be applied to any other homogeneous Hamiltonian operator. As an example we provide the Lagrangian representation of a WDVV hydrodynamic-type system in $3$ components., Comment: 21 pages

Published

2016

7. On the bi-Hamiltonian Geometry of WDVV Equations

Author

Pavlov, M. V. and Vitolo, R. F.

Subjects

Mathematical Physics, Nonlinear Sciences - Exactly Solvable and Integrable Systems, 37K05, 37K10, 37K20, 37K25

Abstract

We consider the WDVV associativity equations in the four dimensional case. These nonlinear equations of third order can be written as a pair of six component commuting two-dimensional non-diagonalizable hydrodynamic type systems. We prove that these systems possess a compatible pair of local homogeneous Hamiltonian structures of Dubrovin--Novikov type (of first and third order, respectively)., Comment: 21 pages, revised published version; exposition substantially improved

Published

2014

8. WDVV equations and invariant bi-Hamiltonian formalism

Author

Raffaele Vitolo, Jakub Vašíček, Vasicek, J., and Vitolo, R.

Subjects

High Energy Physics - Theory, Physics, Nuclear and High Energy Physics, Pure mathematics, Nonlinear Sciences - Exactly Solvable and Integrable Systems, Formalism (philosophy), Group (mathematics), Field Theories in Lower Dimensions, Integrable Hierarchies, QC770-798, Invariant (physics), 37K05, 37K10, 37K20, 37K25, Symbolic computation, Differential and Algebraic Geometry, Field Theories in Lower Dimensions, Integrable Hierarchies, Topological Field Theories, Nonlinear Sciences::Exactly Solvable and Integrable Systems, Hamiltonian formalism, Topological Field Theories, Nuclear and particle physics. Atomic energy. Radioactivity, Differential and Algebraic Geometry, Projective test, Mathematical Physics, Projective invariance

Abstract

The purpose of the paper is to show that, in low dimensions, the WDVV equations are bi-Hamiltonian. The invariance of the bi-Hamiltonian formalism is proved for $N=3$. More examples in higher dimensions show that the result might hold in general. The invariance group of the bi-Hamiltonian pairs that we find for WDVV equations is the group of projective transformations. The significance of projective invariance of WDVV equations is discussed in detail. The computer algebra programs that were used for calculations throughout the paper are provided in a GitHub repository., Comment: 37 pages, no figures

Published

2021

9. WDVV equations and invariant bi-Hamiltonian formalism

Author

Va������ek, Jakub and Vitolo, Raffaele

Subjects

Nonlinear Sciences::Exactly Solvable and Integrable Systems, High Energy Physics - Theory (hep-th), FOS: Physical sciences, Mathematical Physics (math-ph), Exactly Solvable and Integrable Systems (nlin.SI), 37K05, 37K10, 37K20, 37K25

Abstract

The purpose of the paper is to show that, in low dimensions, the WDVV equations are bi-Hamiltonian. The invariance of the bi-Hamiltonian formalism is proved for $N=3$. More examples in higher dimensions show that the result might hold in general. The invariance group of the bi-Hamiltonian pairs that we find for WDVV equations is the group of projective transformations. The significance of projective invariance of WDVV equations is discussed in detail. The computer algebra programs that were used for calculations throughout the paper are provided in a GitHub repository., 37 pages, no figures

Published

2021

10. On a class of third-order nonlocal Hamiltonian operators

Author

Raffaele Vitolo, Matteo Casati, Evgeny Ferapontov, Maxim V. Pavlov, Casati, M., Ferapontov, E. V., Pavlov, M. V., and Vitolo, R. F.

Subjects

Mathematics - Differential Geometry, Pure mathematics, Nonlinear Sciences - Exactly Solvable and Integrable Systems, 010102 general mathematics, FOS: Physical sciences, General Physics and Astronomy, Mathematical Physics (math-ph), Poisson distribution, 37K05, 37K10, 37K20, 37K25, 01 natural sciences, symbols.namesake, Third order, Differential Geometry (math.DG), 0103 physical sciences, FOS: Mathematics, symbols, 010307 mathematical physics, Geometry and Topology, Exactly Solvable and Integrable Systems (nlin.SI), 0101 mathematics, Hamiltonian (quantum mechanics), Hamiltonian operators, quadratic line complex, integrable systems, Mathematical Physics, Mathematics

Abstract

Based on the theory of Poisson vertex algebras we calculate skew-symmetry conditions and Jacobi identities for a class of third-order nonlocal operators of differential-geometric type. Hamiltonian operators within this class are defined by a Monge metric and a skew-symmetric two-form satisfying a number of differential-geometric constraints. Complete classification results in the 2-component and 3-component cases are obtained., 19 pages

Published

2018

11. On the Bi-Hamiltonian Geometry of WDVV Equations

Author

Maxim V. Pavlov, Raffaele Vitolo, Pavlov, M. V., and Vitolo, Raffaele

Subjects

Mathematics - Mathematical Physic, Complex system, Statistical and Nonlinear Physics, Geometry, 37K05, 37K10, 37K20, 37K25, Nonlinear Sciences - Exactly Solvable and Integrable System, Nonlinear system, symbols.namesake, Third order, Nonlinear Sciences::Exactly Solvable and Integrable Systems, Homogeneous, symbols, Mathematical Physic, Hamiltonian (quantum mechanics), Mathematical Physics, Associative property, Mathematics

Abstract

We consider the WDVV associativity equations in the four dimensional case. These nonlinear equations of third order can be written as a pair of six component commuting two-dimensional non-diagonalizable hydrodynamic type systems. We prove that these systems possess a compatible pair of local homogeneous Hamiltonian structures of Dubrovin--Novikov type (of first and third order, respectively).

Published

2015

12. Remarks on the Lagrangian representation of bi-Hamiltonian equations

Author

Raffaele Vitolo, Maxim V. Pavlov, Pavlov, M. V., and Vitolo, Raffaele

Subjects

Mathematics - Differential Geometry, FOS: Physical sciences, General Physics and Astronomy, 01 natural sciences, symbols.namesake, 0103 physical sciences, FOS: Mathematics, Covariant Hamiltonian field theory, 0101 mathematics, Mathematics::Symplectic Geometry, Mathematical Physics, Mathematical physics, Mathematics, Nonlinear Sciences - Exactly Solvable and Integrable Systems, 010102 general mathematics, Mathematical analysis, Mathematical Physics (math-ph), 37K05, 37K10, 37K20, 37K25, Differential Geometry (math.DG), Homogeneous, symbols, Vector field, 010307 mathematical physics, Geometry and Topology, Exactly Solvable and Integrable Systems (nlin.SI), Hamiltonian (quantum mechanics), Lagrangian representation, bi-hamiltonian equation, WDVV equation, Lagrangian

Abstract

The Lagrangian representation of multi-Hamiltonian PDEs has been introduced by Y. Nutku and one of us (MVP). In this paper we focus on systems which are (at least) bi-Hamiltonian by a pair $A_1$, $A_2$, where $A_1$ is a hydrodynamic-type Hamiltonian operator. We prove that finding the Lagrangian representation is equivalent to finding a generalized vector field $\tau$ such that $A_2=L_\tau A_1$. We use this result in order to find the Lagrangian representation when $A_2$ is a homogeneous third-order Hamiltonian operator, although the method that we use can be applied to any other homogeneous Hamiltonian operator. As an example we provide the Lagrangian representation of a WDVV hydrodynamic-type system in $3$ components., Comment: 21 pages

Published

2016