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On Numerical Solution of the Gardner–Ostrovsky Equation

Published online by Cambridge University Press:  29 February 2012

M. A. Obregon
Affiliation:
E.T.S. Ingeniería Industrial, University of Malaga, Dr Ortiz Ramos s/n, 29071, Malaga, Spain
Y. A. Stepanyants*
Affiliation:
Department of Mathematics and Computing, Faculty of Sciences, University of Southern Queensland, Toowoomba, Australia
*
Corresponding author. E-mail: [email protected]
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Abstract

A simple explicit numerical scheme is proposed for the solution of the Gardner–Ostrovskyequation (ut + cux + α uux + α1u2ux + βuxxx)x = γuwhich is also known as the extended rotation-modified Korteweg–de Vries(KdV) equation. This equation is used for the description of internal oceanic wavesaffected by Earth’ rotation. Particular versions of this equation with zero some ofcoefficients, α, α1, β, orγ are also known in numerous applications. The proposed numericalscheme is a further development of the well-known finite-difference scheme earlier usedfor the solution of the KdV equation. The scheme is of the second order accuracy both ontemporal and spatial variables. The stability analysis of the scheme is presented forinfinitesimal perturbations. The conditions for the calculations with the appropriateaccuracy have been found. Examples of calculations with the periodic boundary conditionsare presented to illustrate the robustness of the proposed scheme.

Type
Research Article
Copyright
© EDP Sciences, 2012

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References

M.J. Ablowitz, H. Segur. Solitons and the Inverse Scattering Transform. SIAM, Philadelphia, 1981.
Apel, J., Ostrovsky, L.A., Stepanyants, Y.A., Lynch, J.F.. Internal solitons in the ocean and their effect on underwater sound, J. Acoust. Soc. Am., 121 (2007), No. 2, 695722. CrossRefGoogle ScholarPubMed
Yu. Berezin. Modelling Nonlinear Wave Processes. VNU Science Press, 1987.
Dehghan, M., Fakhar-Izadi, F.. The spectral collocation method with three different bases for solving a nonlinear partial differential equation arising in modeling of nonlinear waves, Math. Comp. Modelling, 53 (2011), 18651877. CrossRefGoogle Scholar
Galkin, V.M., Stepanyants, Yu.A.. On the existence of stationary solitary waves in a rotating fluid, J. Appl. Maths. Mechs., 55 (1991), No. 6, 939943 (English translation of the Russian journal “Prikladnaya Matematika i Mekhanika”). CrossRefGoogle Scholar
Gilman, O.A., Grimshaw, R., Stepanyants, Yu.A.. Approximate analytical and numerical solutions of the stationary Ostrovsky equation, Stud. Appl. Math., 95 (1995), No. 1, 115126. CrossRefGoogle Scholar
Gilman, O.A., Grimshaw, R., Stepanyants, Yu.A.. Dynamics of internal solitary waves in a rotating fluid, Dynamics. Atmos. and Oceans, 23 (1996), No. 1–4, 403411. CrossRefGoogle Scholar
Grimshaw, R., He, J.-M., Ostrovsky, L.A.. Terminal damping of a solitary wave due to radiation in rotational systems, Stud. Appl. Math., 101 (1998), 197210. CrossRefGoogle Scholar
Grimshaw, R., Ostrovsky, L.A., Shrira, V.I., Stepanyants, Yu.A.. Long nonlinear surface and internal gravity waves in a rotating ocean, Surveys in Geophys., 19 (1998), 289338. CrossRefGoogle Scholar
Grimshaw, R., Helfrich, K.. Long-time solutions of the Ostrovsky equation, Stud. Appl. Math., 121 (2008), No. 1, 7188. CrossRefGoogle Scholar
Holloway, P., Pelinovsky, E., Talipova, T.. A generalised Korteweg-de Vries model of internal tide transformation in the coastal zone, J. Geophys. Res. 104 (1999), No. 18, 333350. CrossRefGoogle Scholar
Leonov, A.I.. The effect of the Earth’s rotation on the propagation of weak nonlinear surface and internal long oceanic waves, Ann. New York Acad. Sci., 373 (1981), 150159. CrossRefGoogle Scholar
Obregon, M.A., Stepanyants, Yu.A.. Oblique magneto-acoustic solitons in rotating plasma, Phys. Lett. A, 249, (1998), No. 4, 315323. CrossRefGoogle Scholar
Ostrovsky, L.A.. Nonlinear internal waves in a rotating ocean, Oceanology, 18 (1978), 119125. (English translation of the Russian journal “Okeanologiya”). Google Scholar
L.A. Ostrovsky, Yu.A. Stepanyants. Nonlinear surface and internal waves in rotating fluids. In : “Nonlinear Waves 3”, Proc. 1989 Gorky School on Nonlinear Waves, (1990), 106–128. Eds. A.V. Gaponov-Grekhov, M.I. Rabinovich and J. Engelbrecht, Springer-Verlag, Berlin–Heidelberg.
L.A. Ostrovsky, Yu.A. Stepanyants. Internal solitons in laboratory experiments : Comparison with theoretical models, Chaos, 15, (2005) 037111, 28 p.
Pelinovsky, D.E., Stepanyants, Yu.A.. Convergence of Petviashvili’s iteration method for numerical approximation of stationary solutions of nonlinear wave equations, SIAM J. Numerical Analysis, 42, (2004), 11101127. CrossRefGoogle Scholar
V.I. Petviashvili, O.V. Pokhotelov. Solitary Waves in Plasmas and in the Atmosphere. Gordon and Breach, Philadelphia, 1992.
Stepanyants, Yu.A.. On stationary solutions of the reduced Ostrovsky equation : Periodic waves, compactons and compound solitons, Chaos, Solitons and Fractals, 28, (2006), 193204. CrossRefGoogle Scholar
Yu.A. Stepanyants, I.K. Ten, H. Tomita. Lump solutions of 2D generalised Gardner equation. In : “Nonlinear Science and Complexity”, Proc. of the Conference, Beijing, China, 7–12 August 2006, 264–271. Eds. A.C.J. Luo, L. Dai and H.R. Hamidzadeh, World Scientific, 2006.
Vakhnenko, V.O.. High-frequency soliton-like waves in a relaxing medium, J. Math. Phys., 40, (1999), 20112020. CrossRefGoogle Scholar
G.B. Whitham. Linear and Nonlinear Waves. John Wiley & Sons, 1974.
Yaguchi, T., Matsuo, T., Sugihara, M.. Conservative numerical schemes for the Ostrovsky equation, J. Comp. Appl. Maths., 234, (2010), 10361048. CrossRefGoogle Scholar