Soliton Management for ultrashort pulse: dark and anti-dark solitons of Fokas-Lenells equation with a damping like perturbation and a gauge equivalent spin system

arXiv - PHYS - Exactly Solvable and Integrable Systems Pub Date : 2024-02-06 DOI:arxiv-2402.03831

Riki Dutta, Gautam K Saharia, Sagardeep Talukdar, Sudipta Nandy

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Abstract

We investigate the propagation of an ultrashort optical pulse using Fokas-Lenells equation (FLE) under varying dispersion, nonlinear effects and perturbation. Such a system can be said to be under soliton management (SM) scheme. At first, under a gauge transformation, followed by shifting of variables, we transform FLE under SM into a simplified form, which is similar to an equation given by Davydova and Lashkin for plasma waves, we refer to this form as DLFLE. Then, we propose a bilinearization for DLFLE in a non-vanishing background by introducing an auxiliary function which transforms DLFLE into three bilinear equations. We solve these equations and obtain dark and anti-dark one-soliton solution (1SS) of DLFLE. From here, by reverse transformation of the solution, we obtain the 1SS of FLE and explore the soliton behavior under different SM schemes. Thereafter, we obtain dark and anti-dark two-soliton solution (2SS) of DLFLE and determine the shift in phase of the individual solitons on interaction through asymptotic analysis. We then, obtain the 2SS of FLE and represent the soliton graph for different SM scheme. Thereafter, we present the procedure to determine N-soliton solution (NSS) of DLFLE and FLE. Later, we introduce a Lax pair for DLFLE and through a gauge transformation we convert the spectral problem of our system into that of an equivalent spin system which is termed as Landau-Lifshitz (LL) system. LL equation (LLE) holds the potential to provide information about various nonlinear structures and properties of the system.

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超短脉冲的孤子管理：具有类似阻尼扰动的 Fokas-Lenells 方程的暗孤子和反暗孤子以及等价自旋系统

我们利用 Fokas-Lenells 方程（FLE）研究了超短光脉冲在不同色散、非线性效应和扰动条件下的传播。这样的系统可以说是在孤子管理（SM）方案下。首先，在量规变换和变量移动的作用下，我们将 SM 下的 FLE 变换成一种简化形式，它与 Davydova 和 Lashkin 给出的等离子体波方程类似，我们将这种形式称为 DLFLE。然后，我们通过引入一个辅助函数，将 DLFLE 转换为三个双线性方程，从而提出了一种在非消失背景下的 DLFLE 双线性化方法。通过求解这些方程，我们得到了 DLFLE 的暗和反暗单孑子解（1SS）。在此基础上，通过解的反向变换，我们得到了 FLE 的 1SS 并探索了不同 SM 方案下的孤子行为。之后，我们得到了DLFLE的暗双孤子解（2SS）和反暗双孤子解（2SS），并通过渐近分析确定了单个孤子在相互作用时的相位移动。之后，我们介绍了确定DLFLE和FLE的N-孤子解（NSS）的过程。随后，我们为 DLFLE 引入了拉克斯对，并通过量规变换将我们系统的谱问题转换为等价自旋系统的谱问题，该系统被称为兰道-利夫希茨（LL）系统。LL方程（LLE）有可能提供有关系统的各种非线性结构和性质的信息。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - PHYS - Exactly Solvable and Integrable Systems

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