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1. Verfasser: Matsuno, Yoshimasa
Format: Preprint
Veröffentlicht: 2024
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Online-Zugang:https://arxiv.org/abs/2409.18350
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author Matsuno, Yoshimasa
author_facet Matsuno, Yoshimasa
contents We study the cubic Szegö equation which is an integrable nonlinear non-dispersive and nonlocal evolution equation. In particular, we present a direct approach for obtaining the multiphase and multisoliton solutions as well as a special class of periodic solutions. Our method is substantially different from the existing one which relies mainly on the spectral analysis of the Hankel operator. We show that the cubic Szegö equation can be bilinearized through appropriate dependent variable transformations and then the solutions satisfy a set of bilinear equations. The proof is carried out within the framework of an elementary theory of determinants. Furthermore, we demonstrate that the eigenfunctions associated with the multiphase solutions satisfy the Lax pair for the cubic Szegö equation, providing an alternative proof of the solutions. Last, the eigenvalue problem for a periodic solution is solved exactly to obtain the analytical expressions of the eigenvalues.
format Preprint
id arxiv_https___arxiv_org_abs_2409_18350
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle A direct approach for solving the cubic Szegö equation
Matsuno, Yoshimasa
Exactly Solvable and Integrable Systems
Mathematical Physics
37K10, 35B15, 47B35
We study the cubic Szegö equation which is an integrable nonlinear non-dispersive and nonlocal evolution equation. In particular, we present a direct approach for obtaining the multiphase and multisoliton solutions as well as a special class of periodic solutions. Our method is substantially different from the existing one which relies mainly on the spectral analysis of the Hankel operator. We show that the cubic Szegö equation can be bilinearized through appropriate dependent variable transformations and then the solutions satisfy a set of bilinear equations. The proof is carried out within the framework of an elementary theory of determinants. Furthermore, we demonstrate that the eigenfunctions associated with the multiphase solutions satisfy the Lax pair for the cubic Szegö equation, providing an alternative proof of the solutions. Last, the eigenvalue problem for a periodic solution is solved exactly to obtain the analytical expressions of the eigenvalues.
title A direct approach for solving the cubic Szegö equation
topic Exactly Solvable and Integrable Systems
Mathematical Physics
37K10, 35B15, 47B35
url https://arxiv.org/abs/2409.18350