Article information
2020 , Volume 25, ¹ 5, p.17-41
Khakimzyanov G.S., Fedotova Z.I., Dutykh D.
Two-dimensional model of wave hydrodynamics with high accuracy dispersion relation
Application of nonlinear dispersion wave hydrodynamics (NLD-) models for solving practical problems constantly stimulates the search for ways to expand their field of applicability and achieve a more accurate reproduction of the characteristics of the simulated processes. A productive step in this direction turned out to be the method proposed by Madsen & Sørensen (1992), which made it possible to increase the approximation order of the dispersion relation of the Peregrine model while preserving the third order of derivatives included in the original equations and the second order of long-wave approximation. Later, other approaches were proposed to achieve this goal, which had a noticeable effect on expanding the field of applicability of NLD-models (for example, Nwogu (1993), Beji & Nadaoka (1996)). In the present work, we set a similar goal — to improve the properties of the dispersion relation of the model (and, therefore, the phase velocity), providing the Pade approximation (2,2) of the dispersion relation of the 3D model of potential flows. In contrast to earlier works on this subject, where weakly non-linear models were considered, we proceed from the fully nonlinear weakly dispersive two-dimensional Serre — Green — Naghdi (SGN-) model. The novelty of the proposed method consists in modifying the formula for the non-hydrostatic part of the pressure, while the accuracy of the long-wave approximation is preserved. It is shown that in some special cases the obtained fully nonlinear model is close to the known models (for example, after appropriate simplification it coincides with the model from Beji & Nadaoka (1996)). A dispersion analysis was performed one of the results of which was the conclusion that for sufficiently long waves the approximation order of the dispersion relation of the 3D model increases from the second to the fourth and an improvement was also achieved for more short waves. The proposed modification of the SGN-model is invariant with respect to the Galilean transformation; the law of conservation of mass and the law of balance of the total momentum are satisfied. However, the law of conservation of total energy is not satisfied. Apparently all NLD-models with improved dispersion characteristics possess this negative quality.
[full text] Keywords: long surface waves, nonlinear dispersive equations, dispersion relation, phase velocity
doi: 10.25743/ICT.2020.25.5.003
Author(s): Khakimzyanov Gayaz Salimovich Dr. , Professor Position: Leading research officer Office: Federal Research Center for Information and Computational Technologies Address: 630090, Russia, Novosibirsk, Ac. Lavrentiev ave. 6
Phone Office: (383) 330 86 56 E-mail: khak@ict.nsc.ru SPIN-code: 3144-0877Fedotova Zinaida Ivanovna PhD. Position: Senior Research Scientist Office: Federal Research Center for Information and Computational Technologies Address: 630090, Russia, Novosibirsk, Lavrentiev ave. 6
Phone Office: (383) 334-91-21 E-mail: zf@ict.nsc.ru Dutykh Denys Office: University Grenoble Alpes, University Savoie Mont Blanc, CNRS LAMA Address: 73376, France, Chambery, Lavrentiev ave. 6
Phone Office: (330) 4 79 75 94 38 E-mail: Denys.Dutykh@univ-smb.fr
References:
1. Fedotova Z.I., Khakimzyanov G.S., Dutykh D. Energy equation for certain approximate models of long-wave hydrodynamics. Russian Journal of Numerical Analysis and Mathematical Modelling. 2014; 29(3):167–178.
2. Shokin Yu.I., Fedotova Z.I., Khakimzyanov G.S. Hierarchy of nonlinear models of the hydrodynamics of long surface waves. Doklady Physics. 2015; 60(5):224–228.
3. Madsen P.A., Fuhrman D.R. High-order Boussinesq-type modeling of nonlinear wave phenomena in deep and shallow water. Advances in Numerical Simulation of Nonlinear Water Waves (ed. Ma Q.W.). Singapore: World Scientific Publishing Co. Pte. Ltd; 2010: 245–286.
4. Brocchini M. A reasoned overview on Boussinesq-type models: The interplay between physics, mathematics and numerics. Proc. of Royal Soc. of London. A. 2013; 469(2160):20130496.
5. Kirby J.T. Boussinesq models and their application to coastal processes across a wide range of scales. Journal of Waterway, Port, Coastal and Ocean Engineering. 2016; 142(6):03116005.
6. Witting J.M. A unified model for the evolution of nonlinear water waves. Journal Comput. Phys. 1984; 56(2):203–236.
7. Ataie-Ashtiani B., Najafi-Jilani A. A higher-order Boussinesq-type model with moving bottom boundary: Applications to submarine landslide tsunami waves. Int. J. Numer. Meth. Fluids. 2007; (53):1019–1048.
8. Gobbi M.F., Kirby J.T. Wave evolution over submerged sills: Tests of a high-order Boussinesq model. Coastal Engineering. 1999; (37):57–96.
9. Gobbi M.F., Kirby J.T., Wei G. A fully nonlinear Boussinesq model for surface waves. Part 2. Extension to O(kh)4. Journal of Fluid Mechanics. 2000; (405):181–210.
10. Lynett P., Liu P.L-F. A multi-layer approach to wave modeling. Proc. of Royal Soc. of London. A., 2004; (460):2637–2669.
11. Madsen P.A., Murray R., Sørensen O.R. A new form of the Boussinesq equations with improved linear dispersion characteristics. Coastal Engineering. 1991; (15):371–388.
12. Madsen P.A., Sørensen O.R. A new form of the Boussinesq equations with improved linear dispersion characteristics. Part 2. A slowly-varying bathymetry. Coastal Engineering. 1992; (18):183–204.
13. Abbott M.B., Petersen H.M., Skovgaard O. On the numerical modelling of short waves in shallow water. Journal of Hydraulic Research. 1978; 16(3):173–204.
14. Peregrine D.H. Long waves on a beach. Journal of Fluid Mechanics. 1967; (27):815–827.
15. Nwogu O. Alternative form of Boussinesq equations for nearshore wave propagation. Journal of Waterway, Port, Coastal, and Ocean Engineering. 1993; 119(6):618–638.
16. Beji S., Nadaoka K. A formal derivation and numerical modelling of the improved Boussinesq equations for varying depth. Ocean Engineering. 1996; 23(8):691–704.
17. Agnon Y., Madsen P.A., Sch¨affer H.A. A new approach to high order Boussinesq models. Journal of Fluid Mechanics. 1999; (399):319–333.
18. Madsen P.A., Bingham H.B., Liu H. A new Boussinesq method for fully nonlinear waves from shallow to deep water. Journal of Fluid Mechanics. 2002; (462):1–30.
19. Madsen P.A., Agnon Y. Accuracy and convergence of velocity formulations for water waves in the framework of Boussinesq theory. Journal of Fluid Mechanics. 2003; (477):285–319.
20. Clamond D., Dutykh D., Mitsotakis D. Conservative modified Serre — Green — Naghdi equations with improved dispersion characteristics. Commun. Nonlinear Sci. Numer. Simul. 2017; (45):245–257.
21. Løvholt F., Pedersen G.K., Glimsdal S. Coupling of dispersive tsunami propagation and shallow water coastal response. The Open Oceanography Journal. 2010; (4):71–82.
22. Tavakkol S., Lynett P. Celeris: A GPU-accelerated open source software with a Boussinesq type wave solver for real-time interactive simulation and visualization. Computer Physics Communications. 2017; (217):117–127.
23. Shi F., Kirby J.T., Harris J.C., Geiman J.D., Grilli S.T. A high-order adaptive time-stepping TVD solver for Boussinesq modeling of breaking waves and coastal inundation. Ocean Modelling. 2012; (43–44):36–51.
24. Khakimzyanov G., Dutykh D., Fedotova Z., Mitsotakis D. Dispersive shallow water wave modelling. Part I: Model derivation on a globally flat space. Communications in Computational Physics. 2018; 23(1):1–29.
25. Fedotova Z.I., Khakimzyanov G.S., Gusev O.I., Shokina N.Yu. History of the development and analysis of numerical methods for solving nonlinear dispersive equations of hydrodynamics. II. Two-dimensional models. Computational Technologies. 2017; 22(5):73–109. (In Russ.)
26. Khakimzyanov G.S., Gusev O.I., Beisel S.A., Chubarov L.B., Shokina N.Yu. Simulation of tsunami waves generated by submarine landslides in the Black Sea. Russian Journal of Numerical Analysis and Mathematical Modelling. 2015; 30(4):227–237.
27. Serre F. Contribution a` l’´etude des ´ecoulements permanents et variables dans les canaux. La Houille Blanche. 1953; 3:374–388.
28. Serre F. Contribution a` l’´etude des ´ecoulements permanents et variables dans les canaux. La Houille Blanche. 1953; 3:830–872.
29. Green A.E., Naghdi P.M. A derivation of equations for wave propagation in water of variable depth. Journal of Fluid Mechanics. 1976; (78):237–246.
30. Zheleznyak M.I., Pelinovsky E.N. Physical and mathematical models of the tsunami climbing a beach. Tsunami Climbing a Beach: Sb. nauch. tr. Gor’kiy: IPF AN SSSR; 1985: 8–33. (In Russ.)
31. Khakimzyanov G.S., Dutykh D., Fedotova Z.I. Dispersive shallow water wave modelling. Part III: Model derivation on a globally spherical geometry. Communications in Computational Physics. 2018; 23(2):315–360.
32. Chhay M., Dutykh D., Clamond D. On the multi-symplectic structure of the Serre — Green — Naghdi equations. Journal Phys. A: Math. Gen. 2016; 49(3):03LT01.
33. Fedotova Z.I., Khakimzyanov G.S. On analysis of conditions for derivation of nonlineardispersive equations. Computational Technologies. 2012; 17(5):94–108. (In Russ.)
34. Khakimzyanov G., Dutykh D. Long wave interaction with a partially immersed body. Part I: Mathematical models. Communications in Computational Physics. 2020; 27(2):321–378.
35. Schaffer H.A., Madsen P.A. Discussion of “A formal derivation and numerical modelling of the improved Boussinesq equations for varying depth”. Ocean Engineering. 1998; 25(6):497–500.
36. Bercu G., Wu S. Refinements of certain hyperbolic inequalities via the Pad´e approximation method. Journal of Nonlinear Science and Applications. 2016; (9):5011–5020.
37. Fedotova Z.I., Khakimzyanov G.S. Characteristics of finite-difference methods for dispersive shallow water equations. Russian Journal of Numerical Analysis and Mathematical Modelling. 2016; 31(3):149–158.
38. Khakimzyanov G., Dutykh D., Gusev O., Shokina N. Dispersive shallow water wave modelling. Part II: Numerical simulation on a globally flat space. Communications in Computational Physics. 2018; 23(1):30–92.
39. Benjamin T.B., Bona J.L., Mahony J.J. Model equations for long waves in nonlinear dispersive systems. Philosophical Transactions of the Royal Society of London. A. 1972; (272):47–78.
40. Schaffer H.A., Madsen P.A. Further enhancements of Boussinesq-type equations. Coastal Engineering. 1995; (26):1–14. Bibliography link: Khakimzyanov G.S., Fedotova Z.I., Dutykh D. Two-dimensional model of wave hydrodynamics with high accuracy dispersion relation // Computational technologies. 2020. V. 25. ¹ 5. P. 17-41
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