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Ships and Offshore Structures Volume 12, 2017 - Issue 3
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Original Articles

Fourth-order split-step pseudo-spectral method for the modified nonlinear Schrödinger equation

Wenyue LuState Key Laboratory of Ocean Engineering, Shanghai Jiao Tong University, Shanghai, P.R. China;Collaborative Innovation Center for Advanced Ship and Deep-Sea Exploration (CISSE), Shanghai, P.R. ChinaView further author information
,
Jianmin YangState Key Laboratory of Ocean Engineering, Shanghai Jiao Tong University, Shanghai, P.R. China;Collaborative Innovation Center for Advanced Ship and Deep-Sea Exploration (CISSE), Shanghai, P.R. ChinaCorrespondence[email protected]
View further author information
&
Xinliang TianState Key Laboratory of Ocean Engineering, Shanghai Jiao Tong University, Shanghai, P.R. China;Collaborative Innovation Center for Advanced Ship and Deep-Sea Exploration (CISSE), Shanghai, P.R. ChinaView further author information
Pages 424-432 | Received 30 Oct 2015, Accepted 28 Mar 2016, Published online: 31 May 2016

References

  • Adcock TAA, Taylor PH. 2014. The physics of anomalous ('rogue') ocean waves. Rep Prog Phys. 77(10):105901–105917.
  • Akhmediev N, Ankiewicz A, Soto-Crespo JM. 2009. Rogue waves and rational solutions of the nonlinear Schrödinger equation. Phys Rev E. 80(2):026601–026609.
  • Akhmediev N, Eleonskii V, Kulagin N. 1987. Exact first-order solutions of the nonlinear Schrödinger equation. Theor Math Phys. 72(2):809–818.
  • Chabchoub A, Hoffmann N, Onorato M, Akhmediev N. 2012a. Super roguewaves: Observation of a higher-order breather in water waves. Phys Rev X. 2(1):4089–4091.
  • Chabchoub A, Hoffmann NP, Akhmediev N. 2011. Rogue wave observation in a water wave tank. Phys Rev Lett. 106(20):309–313.
  • Chabchoub A, Neumann S, Hoffmann NP, Akhmediev N. 2012b. Spectral properties of the Peregrine soliton observed in a water wave tank. J Geophys Res Oceans 117(C11):C00J03.
  • Chereskin TK, Mollo-Christensen E. 1985. Modulational development of nonlinear gravity-wave groups. J Fluid Mech. 151:337–365.
  • Deng Y, Yang J, Tian X, Li X. 2015. Experimental investigation on rogue waves and their impacts on a vertical cylinder using the Peregrine breather model. Ships Offshore Struct. 1–9.
  • Duree GC, Shultz JL, Salamo GJ, Segev M, Yariv A, Crosignani B, Di Porto P, Sharp EJ, Neurgaonkar RR. 1993. Observation of self-trapping of an optical beam due to the photorefractive effect. Phys Rev Lett. 71(4):533–536.
  • Dysthe K, Krogstad HE, Müller P. 2008. Oceanic rogue waves. Annu Rev Fluid Mech. 40(1):287–310.
  • Dysthe KB. 1979. Note on a modification to the nonlinear Schrodinger equation for application to deep water waves. Proc Roy Soc Lond A Math Phys Sci. 369(1736):105–114.
  • Gao N, Yang J, Zhao W, Li X. 2015. Numerical simulation of deterministic freak wave sequences and wave-structure interaction. Ships Offshore Struct. 1–16.
  • Hasegawa A, Tappert F. 1973. Transmission of stationary nonlinear optical pulses in dispersive dielectric fibers. I. Anomalous dispersion. Appl Phys Lett. 23(3):142–144.
  • Haver S. 2003. Freak wave event at Draupner jacket January 1 1995. Statoil Technical Report PTT-KU-MA. Available from: http://www.ifremer.fr/web-com/stw2004/rogue/pres/Session_3.2/ Haver_Draupner.pdf
  • Jensen JJ. 2008. Extreme value predictions and critical wave episodes for marine structures by FORM. Ships Offshore Struct. 3(4):325–333.
  • Kharif C, Pelinovsky E. 2003. Physical mechanisms of the rogue wave phenomenon. Eur J Mech, B/Fluids 22(6):603–634.
  • Lamb GL. 1980. Elements of soliton theory. New York: Wiley-Interscience, 1980. 300 p.
  • Liu PC, MacHutchon KR. 2008. Are there different kinds of rogue waves? J Offshore Mech Arct Eng. 130(2):021007.
  • Lo E, Mei CC. 1985. Numerical study of water-wave modulation based on a higher-order nonlinear Schrodinger equation. J Fluid Mech. 150:395–416.
  • Ma YC. 1979. Perturbed plane-wave solutions of the cubic Schrodinger equation. Stud Appl Math. 60(1):43–58.
  • Mollenauer LF, Stolen RH, Gordon JP. 1980. Experimental observation of picosecond pulse narrowing and solitons in optical fibers. Phys Rev Lett. 45(13):1095–1098
  • Mori N, Liu PC, Yasuda T. 2002. Analysis of freak wave measurements in the Sea of Japan. Ocean Eng. 29(11):1399–1414.
  • Muslu GM, Erbay HA. 2005. Higher-order split-step Fourier schemes for the generalized nonlinear Schrödinger equation. Math Comput Simul. 67(6):581–595.
  • Nore C, Abid A, Brachet M. 1996. Small-scale structures in three-dimensional hydrodynamics and magnetohyrodynamic turbulence. Berlin: Springer.
  • Onorato M, Residori S, Bortolozzo U, Montina A, Arecchi F. 2013. Rogue waves and their generating mechanisms in different physical contexts. Phys Rep. 528(2):47–89.
  • Pelinovsky E, Slunyaev A, Lopatoukhin L, Divinsky B, Levin B. 2004. Freak wave event in the black sea: observation and modeling. Dokl Earth Sci2004 A. 395:438–443.
  • Peregrine D. 1983. Water waves, nonlinear Schrödinger equations and their solutions. J Australian Math Soc Ser B Appl Math. 25(01):16–43.
  • Shemer L, Alperovich L. 2013. Peregrine breather revisited. Phys Fluids. 25(5):051701.
  • Shemer L, Kit E, Jiao H. 2002. An experimental and numerical study of the spatial evolution of unidirectional nonlinear water-wave groups. Phys Fluids. 14(10):3380–3390.
  • Shemer L, Kit E, Jiao H, Eitan O. 1998. Experiments on nonlinear wave groups in intermediate water depth. J Waterway, Port, Coastal Ocean Eng. 124(6):320–327.
  • Shrira VI, Geogjaev VV. 2010. What makes the Peregrine soliton so special as a prototype of freak waves? J Eng Math. 67(1):11–22.
  • Slunyaev A, Didenkulova I, Pelinovsky E. 2011. Rogue waters. Contemp Phys. 52(6):571–590.
  • Slunyaev A, Pelinovsky E, Sergeeva A, Chabchoub A, Hoffmann N, Onorato M, Akhmediev N. 2013. Super-rogue waves in simulations based on weakly nonlinear and fully nonlinear hydrodynamic equations. Phys Rev E. 88(1):2252–2279.
  • Tian B, Shan WR, Zhang CY, Wei GM, Gao YT. 2005. Transformations for a generalized variable-coefficient nonlinear Schrödinger model from plasma physics, arterial mechanics and optical fibers with symbolic computation. Eur Phys J B. 47(3):329–332.
  • Trulsen K, Stansberg CT. 2001. Spatial evolution of water surface waves: Numerical simulation and experiment of bichromatic waves.In: 11th (2001) International Offshore and Polar Engineering Conference; Stavanger International Society of Offshore and Polar Engineers; p. 71–77.
  • Xiong H, Yang J, Tian X. 2015. An experimental study on the inline wave force on a truncated vertical cylinder. Ships Offshore Struct. 1–16.
  • Zakharov VE. 1968. Stability of periodic waves of finite amplitude on the surface of a deep fluid. J Appl Mech Tech Phys. 9(2):190–194.

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