Numerical simulation of a solitonic gas in KdV and KdV-BBM equations

Denys Dutykh; Efim Pelinovsky

doi:10.1016/j.physleta.2014.09.008

Numerical simulation of a solitonic gas in KdV and KdV-BBM equations

Denys Dutykh, Efim Pelinovsky

Mathematics

Research output: Contribution to journal › Article › peer-review

71 Scopus citations

Abstract

The collective behaviour of soliton ensembles (i.e. the solitonic gas) is studied using the methods of the direct numerical simulation. Traditionally this problem was addressed in the context of integrable models such as the celebrated KdV equation. We extend this analysis to non-integrable KdV-BBM type models. Some high resolution numerical results are presented in both integrable and nonintegrable cases. Moreover, the free surface elevation probability distribution is shown to be quasi-stationary. Finally, we employ the asymptotic methods along with the Monte Carlo simulations in order to study quantitatively the dependence of some important statistical characteristics (such as the kurtosis and skewness) on the Stokes-Ursell number (which measures the relative importance of nonlinear effects compared to the dispersion) and also on the magnitude of the BBM term.

Original language	British English
Pages (from-to)	3102-3110
Number of pages	9
Journal	Physics Letters, Section A: General, Atomic and Solid State Physics
Volume	378
Issue number	42
DOIs	https://doi.org/10.1016/j.physleta.2014.09.008
State	Published - 28 Aug 2014

Keywords

BBM equation
KdV equation
Solitonic gas
Statistical description
Statistical moments
Stokes-Ursell number

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10.1016/j.physleta.2014.09.008

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title = "Numerical simulation of a solitonic gas in KdV and KdV-BBM equations",

abstract = "The collective behaviour of soliton ensembles (i.e. the solitonic gas) is studied using the methods of the direct numerical simulation. Traditionally this problem was addressed in the context of integrable models such as the celebrated KdV equation. We extend this analysis to non-integrable KdV-BBM type models. Some high resolution numerical results are presented in both integrable and nonintegrable cases. Moreover, the free surface elevation probability distribution is shown to be quasi-stationary. Finally, we employ the asymptotic methods along with the Monte Carlo simulations in order to study quantitatively the dependence of some important statistical characteristics (such as the kurtosis and skewness) on the Stokes-Ursell number (which measures the relative importance of nonlinear effects compared to the dispersion) and also on the magnitude of the BBM term.",

keywords = "BBM equation, KdV equation, Solitonic gas, Statistical description, Statistical moments, Stokes-Ursell number",

author = "Denys Dutykh and Efim Pelinovsky",

note = "Funding Information: D. Dutykh acknowledges the support from ERC under the research project ERC-2011-AdG 290562-MULTIWAVE . E. Pelinovsky would like to thank for the support the Russian State contract (2014/133 – theoretical part), the VolkswagenStiftung , RFBR grants ( 14-05-00092 ). The authors would like to thank Professors Gennady El and Al Osborne for stimulating discussions on the topics of integrability and solitons theory. Publisher Copyright: {\textcopyright} 2014 Elsevier B.V.",

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doi = "10.1016/j.physleta.2014.09.008",

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AU - Dutykh, Denys

AU - Pelinovsky, Efim

N1 - Funding Information: D. Dutykh acknowledges the support from ERC under the research project ERC-2011-AdG 290562-MULTIWAVE . E. Pelinovsky would like to thank for the support the Russian State contract (2014/133 – theoretical part), the VolkswagenStiftung , RFBR grants ( 14-05-00092 ). The authors would like to thank Professors Gennady El and Al Osborne for stimulating discussions on the topics of integrability and solitons theory. Publisher Copyright: © 2014 Elsevier B.V.

PY - 2014/8/28

Y1 - 2014/8/28

N2 - The collective behaviour of soliton ensembles (i.e. the solitonic gas) is studied using the methods of the direct numerical simulation. Traditionally this problem was addressed in the context of integrable models such as the celebrated KdV equation. We extend this analysis to non-integrable KdV-BBM type models. Some high resolution numerical results are presented in both integrable and nonintegrable cases. Moreover, the free surface elevation probability distribution is shown to be quasi-stationary. Finally, we employ the asymptotic methods along with the Monte Carlo simulations in order to study quantitatively the dependence of some important statistical characteristics (such as the kurtosis and skewness) on the Stokes-Ursell number (which measures the relative importance of nonlinear effects compared to the dispersion) and also on the magnitude of the BBM term.

AB - The collective behaviour of soliton ensembles (i.e. the solitonic gas) is studied using the methods of the direct numerical simulation. Traditionally this problem was addressed in the context of integrable models such as the celebrated KdV equation. We extend this analysis to non-integrable KdV-BBM type models. Some high resolution numerical results are presented in both integrable and nonintegrable cases. Moreover, the free surface elevation probability distribution is shown to be quasi-stationary. Finally, we employ the asymptotic methods along with the Monte Carlo simulations in order to study quantitatively the dependence of some important statistical characteristics (such as the kurtosis and skewness) on the Stokes-Ursell number (which measures the relative importance of nonlinear effects compared to the dispersion) and also on the magnitude of the BBM term.

KW - BBM equation

KW - KdV equation

KW - Solitonic gas

KW - Statistical description

KW - Statistical moments

KW - Stokes-Ursell number

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U2 - 10.1016/j.physleta.2014.09.008

DO - 10.1016/j.physleta.2014.09.008

M3 - Article

AN - SCOPUS:84907286185

SN - 0375-9601

VL - 378

SP - 3102

EP - 3110

JO - Physics Letters, Section A: General, Atomic and Solid State Physics

JF - Physics Letters, Section A: General, Atomic and Solid State Physics

IS - 42

ER -

Numerical simulation of a solitonic gas in KdV and KdV-BBM equations

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