Eckhaus equation
In mathematical physics, the Eckhaus equation – or the Kundu–Eckhaus equation – is a nonlinear partial differential equations within the nonlinear Schrödinger class:[1]
The equation was independently introduced by Wiktor Eckhaus and by Anjan Kundu to model the propagation of waves in dispersive media.[2][3] The Kundu–Eckhaus equation admits many different types of analytical solutions – just like the nonlinear Schrödinger equation – including but not limited to rational rogue wave solutions.[4] Behavior of its stochastic rogue wave solutions and their spectra may be used for early detection purposes.[5]
Linearization
The Eckhaus equation can be linearized to the linear Schrödinger equation:[6]
through the non-linear transformation:[7]
The inverse transformation is:
This linearization also implies that the Eckhaus equation is integrable.
Notes
References
- Ablowitz, M.J.; Ahrens, C.D.; De Lillo, S. (2005), "On a "quasi" integrable discrete Eckhaus equation", Journal of Nonlinear Mathematical Physics, 12 (Supplement 1): 1–12, Bibcode:2005JNMP...12S...1A, doi:10.2991/jnmp.2005.12.s1.1
- Calogero, F.; De Lillo, S. (1987), "The Eckhaus PDE iψt + ψxx+ 2(|ψ|2)x ψ + |ψ|4 ψ = 0", Inverse Problems, 3 (4): 633–682, Bibcode:1987InvPr...3..633C, doi:10.1088/0266-5611/3/4/012
- Eckhaus, W. (1985), The long-time behaviour for perturbed wave-equations and related problems, Department of Mathematics, University of Utrecht, Preprint no. 404.
Published in part in: Eckhaus, W. (1986), "The long-time behaviour for perturbed wave-equations and related problems", in Kröner, E.; Kirchgässner, K., Trends in applications of pure mathematics to mechanics, Lecture Notes in Physics, 249, Berlin: Springer, pp. 168–194, ISBN 978-3-540-16467-8, doi:10.1007/BFb0016391 - Bayindir, C. (2016a), "Rogue waves of the Kundu–Eckhaus equation in a chaotic wavefield", Physical Review E, 93 (032201), doi:10.1103/PhysRevE.93.032201
- Bayindir, C. (2016b), "Rogue wave spectra of the Kundu–Eckhaus equation", Physical Review E, 93 (062215), doi:10.1103/PhysRevE.93.062215
- Kundu, A. (1984), "Landau–Lifshitz and higher-order nonlinear systems gauge generated from nonlinear Schrödinger-type equations", Journal of Mathematical Physics, 25: 3433–3438, Bibcode:1984JMP....25.3433K, doi:10.1063/1.526113
- Taghizadeh, N.; Mirzazadeh, M.; Tascan, F. (2012), "The first-integral method applied to the Eckhaus equation", Applied Mathematics Letters, 25 (5): 798–802, doi:10.1016/j.aml.2011.10.021
- Zwillinger, D. (1998), Handbook of differential equations (3rd ed.), Academic Press, ISBN 978 0 12 784396 4