关于二维Korteweg-de Vries方程的含参数Bcklund变换

本文运用Hirota双线性算子理论推导了一个二维Korteweg-de Vries方程的含参数Bcklund变换,并讨论了该变换与Scale变换的关系,得出了有关分解等式。同时,文中还将上述双线性Bcklund变换转化为通常物理变量形式,讨论了该方程的非线性迭加公式。     

与二阶多项式等谱问题相联系的方程簇的Hirota双线性型

利用 Hirota方法可直接求出非线性发展方程的孤立子解 ,此方法首要是通过一个变换将非线性发展方程约化为新的方程 ,即所谓的 Hirota双线性型 .本文对可积方程簇给出此 Hirota双线性型 ,从而该方程簇的孤立子解是可以求出的 .     

带源的超对称KdV方程的双线性B(a)cklund变换

给出经典带源的KdV方程的一个超对称形式,利用Hirota双线性方法得到它的双线性形式,并从双线性形式出发利用一些双线性算子恒等式构造了它的双线性B(a)cklund变换.     

Bell多项式在经典Boussinesq方程中的应用

本文借助于Bell多项式研究经典Boussinesq方程,将其转换成Hirota双线性形式,构造了带参数的B(a)cklund变换,进而重新导出了其Lax表示.     

mKdV-SineGordon方程的多孤子解

该文首先给出了mKdV-SineGordon方程的双线性形式和双线性Backlund变换,然后利用Hirota方法、Backlund变换方法和Wronskian技巧三种不同的方法分别得到mKdV-SineGordon方程的孤子解,最后验证了这三种解的一致性。     

Camassa-Holm方程的拟周期解及其渐近行为

近20年来,浅水波模型Camassa-Holm（CH）方程受到诸多研究者关注。在之前的工作中,通过Hirota双线性方法得到了CH方程的单周期解.基于此,该文将对N=2时CH方程的拟周期解及其渐近行为进行研究.首先,回顾了坐标变换,扩展的双线性形式和Riemann(黎曼)θ-函数等内容,并在此基础上利用Hirota双线性方法构造了在N=2时CH方程的含有多个参数的拟周期解,并且此拟周期解是由Riemannθ-函数表示的。其次,发现了此拟周期解渐近行为的一个特点,即CH方程的此拟周期解可以退化为其二孤子解.     

超对称柱KdV方程的孤子解

利用直接法将柱KdV方程超对称化.通过适当的变换,利用双线性方法将超对称柱KdV方程双线性化,由超对称Hirota双线性导数法构造出超对称柱KdV方程的单孤子解、双孤子解、三孤子解以及n孤子解的具体表达形式.     

Bcklund变换与n孤子解

本文首先证明了KdV方程与sine-Gordon方程不同形式的Backlund变换是相互等价的;其次从双线性导数形式的Backlund变换出发给出多孤子解的Hirota表示与Wronski行列式表示,并利用Vandermonde行列式说明这两种孤子解的表示是一致的.     

广义(2+1)维Boussinesq方程的孤立波解

首先应用Riccati展开法获得广义(2+1)维Boussinesq方程的96组相互作用解,这类解同时含有三角函数、双曲函数、有理函数、指数函数等,它反映了不同类型非线性波的相互作用.然后应用同宿测试方法结合Hirota双线性形式求得广义(2+1)维Boussinesq方程的周期孤波解,通过相应的时空变换,得到方程其他形式的解.     

扩展形式的修正的Kadomtsev-Petviashvili方程的多重峰波

研究修正的Kadomtsev-Petviashvili(mKP)方程的一个扩展形式.使用由Hereman和Nuseir提出的、一个可以信赖的、Hirota双线性法的简化形式.由该方程(这里称为mKP方程)直接导出多重峰波解.研究还表明,扩展项并不会破坏mKP方程的可积性.     

Solitons of the resonant nonlinear Schrödinger equation with nontrivial boundary conditions: Hirota bilinear method

We use the Hirota bilinear approach to consider physically relevant soliton solutions of the resonant nonlinear Schrödinger equation with nontrivial boundary conditions, recently proposed for describing uniaxial waves in a cold collisionless plasma. By the Madelung representation, the model transforms into the reaction-diffusion analogue of the nonlinear Schrödinger equation, for which we study the bilinear representation, the soliton solutions, and their mutual interactions.     

BCKLUND TRANSFORMATION AND LAX REPRESENTATION FOR A NONLINEAR DIFFERENTIAL EQUATION

In this paper, the Hirota bilinear method is applied to a nonlinear equation which is a deformation to a KdV equation with a source. Using the Hirota’s bilinear operator, we obtain its bilinear form and construct its bilinear Bcklund transformation. And then we obtain the Lax representation for the equation from the bilinear Bcklund transformation and testify the Lax representation by the compatibility condition.     

Bilinear form and new interaction solutions for the sixth-order Ramani equation

By using the Hirota’s bilinear method, the bilinear form of the sixth-order Ramani equation is succinctly obtained. With the aid of the obtained bilinear form, some new interaction solutions which include interaction solutions between exponential and trigonometric functions, interaction solutions between exponential and hyperbolic functions, and interaction solutions between trigonometric and hyperbolic functions are also presented by employing the three wave method.     

An efficient algorithm of logarithmic transformation to Hirota bilinear form of KdV-type bilinear equation

In this paper, an efficient algorithm of logarithmic transformation to Hirota bilinear form of the KdV-type bilinear equation is established. In the algorithm, some properties of Hirota operator and logarithmic transformation are successfully applied, which helps to prove that the linear terms of the nonlinear partial differential equation play a crucial role in finding the Hirota bilinear form. Experimented with various integro-differential equations, our algorithm is proven to be more efficient than the algorithm referred by Zhou, Fu, and Li in getting the Hirota bilinear form, especially in achieving the coefficient of the logarithmic transformation.     

New exact solitary wave and multiple soliton solutions of quantum Zakharov-Kuznetsov equation

By employing auxiliary equation method and Hirota bilinear method, the quantum Zakharov-Kuznetsov equation which arises in quantum magnetoplasma is investigated. With the aid of symbolic computation, both solitary wave solutions and multiple-soliton solutions are obtained. These new exact solutions will extend previous results and help us explain the properties of multidimensional nonlinear ion-acoustic waves in dense magnetoplasma.     

Complexiton solutions to the Hirota‐Satsuma‐Ito equation

The Hirota bilinear method is a powerful tool for solving nonlinear evolution equations. Together with the linear superposition principle, it can be used to find a special class of explicit solutions that correspond to complex eigenvalues of associated characteristic problems. These solutions are known as complexiton solutions or simply complexitons. In this article, we study complexiton solutions of the the Hirota‐Satsuma‐Ito equation which is a (2 + 1)‐dimensional extension of the Hirota‐Satsuma shallow water wave equation known to describe propagation of unidirectional shallow water waves. We first construct hyperbolic function solutions and consequently derive the so‐called complexitons via the Hirota bilinear method and the linear superposition principle. In particular, we find nonsingular complexiton solutions to the Hirota‐Satsuma‐Ito equation. Finally, we give some illustrative examples and a few concluding remarks.     

一个2+1维变形Boussinesq方程的N孤子解

研究了一个2＋1维变形Boussinesq非线性发展方程：utt-uxx-uyy-3（u^2）xx-uxxxx=0,运用Hirota双线性方法得到它的N孤子解.     

Hirota-Satsuma方程的N-孤子解(英文)

In this work,using the Hirota bilinear method,N-soliton solution is obtained for Hirota-Satsuma nonlinear evolution equation:u_t - u_xxt - 3u_xu_t + u_x = 0.     

On completely integrable coupled Burgers and coupled Korteweg–de Vries systems

In this work, we study two completely integrable equations, namely, coupled Burgers and Korteweg–de Vries systems. The modified form of Hirota’s bilinear method, established by Hereman, is employed to formally derive multiple-soliton solutions and multiple-singular-soliton solutions for each system. Hirota’s bilinear method is reliable and effective and can also be applied to solve other types of higher-dimensional integrable and non-integrable systems.     

SOLITON SOLUTIONS TO AN EQUATION IN 2+1 DIMENSIONS

This paper considers a 2+1 dimensional equation. A bilinear form for the equation and its 3-soliton solutions are obtained by the Hirota method. The N-soliton solution is given in the form of pfaffian. At the same time the proof of the solutions are given.