Partial-limit solutions and rational solutions with parameter for the Fokas-Lenells equation

Wu, Hua

doi:10.1007/s11071-021-06911-4

Cited by 2 publications

(1 citation statement)

References 34 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…Ø FL• §± , êNLS• §•kaq ) [14] . ù«)OE±ÚÑ• § "ê f) [14,17] . •Ä zc ÍÜ• §|(2), ¿ (q 0 , r 0 )´• §|(2) ˜|).…”

Section: V‚5 Z•{unclassified

Bilinearization-reduction approach to integrable systems

Zhang¹

2023

Acta Phys. Sin.

View full text Add to dashboard Cite

The paper is a review of the bilinearization-reduction method which provides an approach to obtain solutions to integrable systems. Many integrable coupled systems can be bilinearized and their solutions are presented in terms of double Wronskians (or double Casoratians in discrete case). The bilinearization-reduction method is based on bilinear equations and solutions in double Wronskian/Casoratian form. For those integrable equations that are reduced from coupled systems, one can first solve the unreduced coupled system, obtaining their solutions in double Wronskian/Casoratian form, then, implement suitable reduction techniques, so that solutions of the reduced equation can be obtained as reductions of those of the unreduced coupled system. The method proves effective in solving not only classical integrable equations but also the nonlocal ones. The so-called nonlocal integrable equations were introduced by Ablowitz and Musslimani via reductions with reverse-space (or reverse-time, or reverse-space-time). Note that this method particularly provides a convenient bilinear approach to solve nonlocal integrable systems. In this review, the nonlinear Schrödinger hierarchy and the differential-difference nonlinear Schrödinger equation are employed as demonstrative examples to elaborate this method. These two examples will be pedagogically helpful in understanding the reduction technique. The reduction is implemented by imposing suitable constraints on the basic column vectors of the double Wronskian/Casoratian. Realizations of the constraints are converted to solve a set of matrix equations which varies with the constraints. Special solutions of the matrix equations are provided, which are also helpful in understanding the eigenvalue structure of the involved spectral problems corresponding to the considered equations. Other examples include the Fokas-Lenells equation and the nonlinear Schrödinger equation with nontrivial background. Since many nonlinear equations with physical significance are integrable as reductions of integrable coupled systems, the paper provides a review as well as an introduction about the bilinearizationreduction method that can be used to solve these nonlinear integrable models.

show abstract

“…Ø FL• §± , êNLS• §•kaq ) [14] . ù«)OE±ÚÑ• § "ê f) [14,17] . •Ä zc ÍÜ• §|(2), ¿ (q 0 , r 0 )´• §|(2) ˜|).…”

Section: V‚5 Z•{unclassified