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edit approved Jun 26, 2022 at 9:03
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edit approved Jun 26, 2022 at 9:03
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Resources on the stationary SchrodingerSchrödinger equation with the soliton potential

I am studying the following LameLamé equation in the Jacobi form \begin{equation}\label{sol} -\frac{d^2 v}{dx^2} - (2k^2 cn^{2}\left [x\;|\;k\right ])v = \lambda v \end{equation}\begin{equation} -\frac{d^2 v}{dx^2} - \left(2k^2 \operatorname{cn}^{2}\left [x\;|\;k\right ]\right)v = \lambda v, \end{equation} where $k\in(0, 1)$ is parameter related to the elliptic modulus of the Jacobi elliptic functions. In order to better understand this equation I am first taking the soliton limit when $k\rightarrow 1$ to obtain the following differential equation \begin{equation}\label{SL} -\frac{d^2 v}{dx^2} - 2sech^2{(x)}v = \lambda v \end{equation}\begin{equation} -\frac{d^2 v}{dx^2} - 2\operatorname{sech}^2{(x)}v = \lambda v, \end{equation} for which analytic solutions exist depending on the values of the parameter $\lambda$. For different behaviour of eigenfunction $v$ is observed for $\lambda=-1,$ $\lambda\in(-\infty,-1)\cup(-1,0)$ and $\lambda\geq 0.$ I believe I obtained the correct solutions,solutions; however, I am having hard time finding them explicitly in the literature. Does anyone know good resources on the latter equation, or if it is known under a special name? My ultimate goal is to use these solutions in the context of the KdV equation, which is a compatibility condition for the stationary SchrodingerSchrödinger equation \begin{equation}\label{SE} -\frac{d^2 v}{dx^2} - u(x,t) v = \lambda v \end{equation}

Resources on the stationary Schrodinger equation with the soliton potential

I am studying the following Lame equation in the Jacobi form \begin{equation}\label{sol} -\frac{d^2 v}{dx^2} - (2k^2 cn^{2}\left [x\;|\;k\right ])v = \lambda v \end{equation} where $k\in(0, 1)$ is parameter related to the elliptic modulus of the Jacobi elliptic functions. In order to better understand this equation I am first taking the soliton limit when $k\rightarrow 1$ to obtain the following differential equation \begin{equation}\label{SL} -\frac{d^2 v}{dx^2} - 2sech^2{(x)}v = \lambda v \end{equation} for which analytic solutions exist depending on the values of the parameter $\lambda$. For different behaviour of eigenfunction $v$ is observed for $\lambda=-1,$ $\lambda\in(-\infty,-1)\cup(-1,0)$ and $\lambda\geq 0.$ I believe I obtained the correct solutions, however I am having hard time finding them explicitly in literature. Does anyone know good resources on the latter equation, or if it is known under a special name? My ultimate goal is to use these solutions in the context of the KdV equation, which is a compatibility condition for the stationary Schrodinger equation \begin{equation}\label{SE} -\frac{d^2 v}{dx^2} - u(x,t) v = \lambda v \end{equation}

Resources on the stationary Schrödinger equation with the soliton potential

I am studying the following Lamé equation in the Jacobi form \begin{equation} -\frac{d^2 v}{dx^2} - \left(2k^2 \operatorname{cn}^{2}\left [x\;|\;k\right ]\right)v = \lambda v, \end{equation} where $k\in(0, 1)$ is parameter related to the elliptic modulus of the Jacobi elliptic functions. In order to better understand this equation I am first taking the soliton limit when $k\rightarrow 1$ to obtain the following differential equation \begin{equation} -\frac{d^2 v}{dx^2} - 2\operatorname{sech}^2{(x)}v = \lambda v, \end{equation} for which analytic solutions exist depending on the values of the parameter $\lambda$. For different behaviour of eigenfunction $v$ is observed for $\lambda=-1,$ $\lambda\in(-\infty,-1)\cup(-1,0)$ and $\lambda\geq 0.$ I believe I obtained the correct solutions; however, I am having hard time finding them explicitly in the literature. Does anyone know good resources on the latter equation, or if it is known under a special name? My ultimate goal is to use these solutions in the context of the KdV equation, which is a compatibility condition for the stationary Schrödinger equation \begin{equation}\label{SE} -\frac{d^2 v}{dx^2} - u(x,t) v = \lambda v \end{equation}

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Resources on the stationary Schrodinger equation with the soliton potential

I am studying the following Lame equation in the Jacobi form \begin{equation}\label{sol} -\frac{d^2 v}{dx^2} - (2k^2 cn^{2}\left [x\;|\;k\right ])v = \lambda v \end{equation} where $k\in(0, 1)$ is parameter related to the elliptic modulus of the Jacobi elliptic functions. In order to better understand this equation I am first taking the soliton limit when $k\rightarrow 1$ to obtain the following differential equation \begin{equation}\label{SL} -\frac{d^2 v}{dx^2} - 2sech^2{(x)}v = \lambda v \end{equation} for which analytic solutions exist depending on the values of the parameter $\lambda$. For different behaviour of eigenfunction $v$ is observed for $\lambda=-1,$ $\lambda\in(-\infty,-1)\cup(-1,0)$ and $\lambda\geq 0.$ I believe I obtained the correct solutions, however I am having hard time finding them explicitly in literature. Does anyone know good resources on the latter equation, or if it is known under a special name? My ultimate goal is to use these solutions in the context of the KdV equation, which is a compatibility condition for the stationary Schrodinger equation \begin{equation}\label{SE} -\frac{d^2 v}{dx^2} - u(x,t) v = \lambda v \end{equation}