# Generalised reversible transformations and the inhomogeneous nonlinear   Schr\"odinger equation hierarchy

**Authors:** Sudipta Nandy, Abhijit Barthakur

arXiv: 1907.03554 · 2024-02-13

## TL;DR

This paper introduces a generalized reversible transformation linking various nonlinear Schrödinger equation hierarchies, enabling analysis of inhomogeneous and higher-order equations within a unified framework, with implications for physics applications.

## Contribution

It proposes a novel reversible transformation connecting inhomogeneous and homogeneous NLSE hierarchies, expanding the mathematical tools for studying nonlinear wave equations.

## Key findings

- Derived extended dark and bright solitons without inverse scattering
- Identified constraints among dispersion and nonlinear coefficients
- Unified inhomogeneous and homogeneous NLSE analysis

## Abstract

Under investigation is the nonlinear Schr\"odinger equation hierarchies and the reversible transformations. We propose a generalized reversible transformation between the the generalized NLSE hierarchy with focussing and defocussing nonlinearity and the NLSE hierarchy forced with a linear potential term. The corresponding extended concept of classical dark and bright solitons of the forced hierarchy, accelerating due to linear potential as well as due to the dispersion are obtained directly without resolving the nonisospectral inverse scattering problem. We have identified a set of new constraints among the dispersion and the nonlinear coefficients in the inhomogeneous NLSE hierarchy, which are preserved after the transformations. The reversible transformations allow us to encompass inhomogeneous NLS, HNLS and higher order equations belonging to the class of nonisospectral family of inverse scattering problems to the isospectral NLS class of equations and study them under a general mathematical framework. We hope that our analysis provides a mathematical platform to study inhomogeneous NLSEs as well as open up the possibility of new applications in physics.

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Source: https://tomesphere.com/paper/1907.03554