The Kundu equation is a general form of integrable system that is gauge-equivalent to the mixed nonlinear Schrödinger equation. It was proposed by Anjan Kundu aswith arbitrary function
\theta(t,x)
\thetax=-\kappa|q|2
\alpha,c,\kappa
\gamma=\kappa(4\kappa+\alpha).
The Kundu equation is a completely integrable system, allowing Lax pair representation, exact solutions, and higher conserved quantity.Along with its different particular cases, this equation has been investigated for finding its exact travelling wave solutions, exact solitary wave solutions via bilinearization, and Darboux transformation together with the orbital stability for such solitary wave solutions.
The Kundu equation has been applied to various physical processes such as fluid dynamics, plasma physics, and nonlinear optics. It is linked to the mixed nonlinear Schrödinger equation through a gauge transformation and is reducible to a variety of known integrable equations such as the nonlinear Schrödinger equation (NLSE), derivative NLSE, higher nonlinear derivative NLSE, Chen–Lee–Liu, Gerjikov-Vanov, and Kundu–Eckhaus equations, for different choices of the parameters.
A generalization of the nonlinear Schrödinger equation with additional quintic nonlinearity and a nonlinear dispersive term was proposed in the formwhich may be obtained from the Kundu Equation, when restricted to
\alpha=0
c=0,
The Kundu-Ekchaus equation is associated with a Lax pair, higher conserved quantity, exact soliton solution, rogue wave solution etc. Over the years various aspects of this equation, its generalizations and link with other equations have been studied. In particular, relationship of Kundu-Ekchaus equation with the Johnson's hydrodynamic equation near criticality is established, its discretizations, reduction via Lie symmetry, complex structure via Bernoulli subequation, bright and dark soliton solutions via Bäcklund transformation and Darboux transformation with the associated rogue wave solutions, are studied.
A multi-component generalisation of the Kundu-Ekchaus equation, known as Radhakrishnan, Kundu and Laskshmanan (RKL) equation was proposed in nonlinear optics for fiber optics communication through soliton pulses in a birefringent non-Kerr medium and analysed subsequently for its exact soliton solution and other aspects in a series of papers.
Though the Kundu-Ekchaus equation (3) is gauge equivalent to the nonlinear Schrödinger equation, they differ with respect to their Hamiltonian structures and field commutation relations. The Hamiltonian operator of the Kundu-Ekchaus equation quantum field model given by
{H} =\intdx\left[:\left(
| \dagger | |
| (\psi | |
| x |
\psix+c\rho2 +i\kappa\rho(\psi\dagger\psix-
| \dagger | |
| \psi | |
| x |
\psi)\right): +\kappa2 (\psi\dagger\rho2\psi)\right], \rho\equiv(\psi\dagger\psi)
[\psi(x),\psi\dagger(y)]=\delta(x-y)
: :
\delta
However, under a nonlinear transformation of the field below:
\tilde\psi(x)=
| |||||||||
| e |
\psi(x)
the model can be transformed to:
\tildeH=\intdx\vdots\left(\tilde
| \dagger | |
| \psi | |
| x |
\tilde\psix +c(\tilde\psi\dagger\tilde\psi)2\right)\vdots ,
i.e. in the same form as the quantum model of the Nonlinear Schrödinger equation (NLSE), though it differs from the NLSE in its contents, since now the fields involved are no longer bosonic operators but exhibit anion like properties.
\tilde\psi\dagger(x1)\tilde\psi\dagger
| i\kappa\epsilon(x1-x2) | |
| (x | |
| 2)=e |
\tilde\psi\dagger(x2)\tilde\psi\dagger(x1), \tilde\psi(x1)\tilde\psi\dagger
| -i\kappa\epsilon(x1-x2) | |
| (x | |
| 2)=e |
\tilde\psi\dagger(x2)\tilde\psi(x1)+\delta(x1-x2)
\epsilon(x-y)=+ ,-,0 ~
~x>y, x<y, x=y,
though at the coinciding points the bosonic commutation relation still holds. In analogy with the Lieb Limiger model of
\delta
\delta