Difference between revisions of "Inverse scattering, half-axis case"

In Step 1, one can find $f ( k )$ by a different method: Solve the Riemann problem

\begin{equation} \tag{a5} \varphi_{+} ( k ) = S ( - k ) \varphi _ { - } ( k ), \end{equation}

\begin{equation*} k \in \mathbf{R} , \varphi _ { \pm } ( \infty ) = 1. \end{equation*}

If $\operatorname{ind} S ( k ) = 0$, this problem has the unique solution $\{ \varphi_+ ( k ) , \varphi_- ( k ) \}$. One has $\varphi _ { + } ( k ) = f ( k )$, $\varphi_{-} ( k ) = f ( - k )$.

Note that the data $\mathcal{S}$ allow one to find a unique $f ( k )$ by solving the Riemann problem (a5) with the additional conditions: $\varphi_{+} ( k )$ has $J$ simple zeros at the points $i k_j$ if $\kappa = - 2 J$ and, if $\kappa = - 2 J - 1$, $\varphi_{+} ( k )$ has, in addition, a simple zero at $k = 0$. Thus, the data $\mathcal{S}$ is equivalent to the data $\{ f ( k ) , s _j 1 \leq j \leq J \}$.

An inverse problem of recovery of $q ( x )$ from incomplete scattering data but with an a priori assumption that $q ( x )$ has compact support is investigated in [a8] [a9]. It is proved that if $q \in L _ { 1 , 1} $ is compactly supported and if $\delta ( k )$ is known for a sequence $k = k _ { n } > 0$ which has a finite limit point inside $( 0 , \infty )$, then $q ( x )$ is determined uniquely. An algorithm for finding a compactly supported $q ( x )$ from $\delta ( k )$ (that is, from $\mathcal{S} ( k )$) known for all $k > 0$ is given in [a8]. A uniqueness theorem for the problem of finding a compactly supported $q ( x )$ from the knowledge of $f ^ { \prime } ( 0 , k )$, $\forall k > 0$, is proved in [a13].

In [a7], [a12] an algorithm for recovery of $q ( x )$ from the $I$-function is given, where the $I$-function is identical with the Weyl function.

For $q \in L _ { 1 , 1} $ to belong to $L ^ { 2 } ( \mathbf{R} _ { + } )$ it is necessary and sufficient [a6] that

\begin{equation} \tag{a6} k \left[ 1 - S ( k ) + \frac { Q } { i k } \right] \in L ^ { 2 } ( \mathbf{R} ), \end{equation}

where

\begin{equation*} Q : = \int _ { 0 } ^ { \infty } q ( t ) d t = - 2 i \operatorname { lim } _ { k \rightarrow \infty } \{ k [ f ( k ) - 1 ] \}. \end{equation*}

If $q ( x ) \in L _ { 1,1 } \cap L ^ { 2 } ( \mathbf{R} _ { + } )$, $q = 0$ for $x \geq a$, is compactly supported, then $f ( k )$ is an entire function of exponential type $\leq 2 a$. Its zeros in $\mathbf{C} _ { - } : = \{ k : \operatorname { Im } k < 0 \}$ are called resonances.

If $q ( x ) \not\equiv 0$, $\int _ { 0 } ^ { \infty } x ^ { n } | q ( x ) | d x = o ( n ^ { b n } )$, $0 \leq b < 1$, then there are infinitely many resonances [a6].

There exists a $q ( x ) \in C _ { 0 } ^ { \infty } ( \mathbf{R} + )$, $q ( x ) = 0$ for $x \geq \epsilon$, where $\epsilon > 0$ is arbitrary small, which generates infinitely many purely imaginary resonances [a6].

If $q ( x ) \in L _ { 1,1 }$, $q ( x ) = 0$ for $x \geq a$ and $q ( x )$ does not change sign in an interval $( a - \delta , a )$, where $\delta > 0$ is arbitrarily small, then $q ( x )$ generates only finitely many purely imaginary resonances (a6).

If $q \in L _ { 1 , 1} $, then the following estimate (see [a5]) is useful:

\begin{equation*} \left| F ^ { \prime } ( 2 x ) - \frac { q ( x ) } { 4 } + \frac { 1 } { 4 } \left( \int _ { x } ^ { \infty } q ( t ) d t \right)^2 \right| \leq c \sigma ^ { 2 } ( x ), \end{equation*}

\begin{equation*} \sigma ( x ) : = \int _ { x } ^ { \infty } | q ( t ) | d t. \end{equation*}

The Jost solution $f ( x , k )$ can be written as $f ( x , k ) = e ^ { i k x } + \int _ { x } ^ { \infty } A ( x , y ) e ^ { i k y } d y$, where $A ( x , y )$ is the kernel of the transformation operator. If $q \in L _ { 1 , 1} $, then

\begin{equation*} | F ( 2 x ) + A ( x , x ) | \leq c \sigma ( x ), \end{equation*}

\begin{equation*} | F ( 2 x ) | \leq c \sigma ( x ) , | A ( x , y ) | \leq c \sigma \left( \frac { x + y } { 2 } \right) , \end{equation*}

\begin{equation*} \left| \frac { \partial A ( x , y ) } { \partial x } + \frac { 1 } { 4 } q \left( \frac { x + y } { 2 } \right) \right| \leq c \sigma ( x ) \sigma \left( \frac { x + y } { 2 } \right) , \left| \frac { \partial A ( x , y ) } { \partial y } + \frac { 1 } { 4 } q ( \frac { x + y } { 2 } ) \right| \leq c \sigma ( x ) \sigma \left( \frac { x + y } { 2 } \right), \end{equation*}

where $c > 0$ is a constant. The function $A ( x , y )$ solves the Volterra-type equation

\begin{equation*} A ( x , y ) = \frac { 1 } { 2 } \int _ { ( x + y ) / 2 } ^ { \infty } q ( t ) d t + \end{equation*}

\begin{equation*} + \int _ { \frac { x + y } { 2 } } ^ { \infty } d s \int _ { 0 } ^ { \frac { y - x } { 2 } } q ( s - t ) A ( s - t , s + t ) d t. \end{equation*}

If $q \in L _ { 1 , 1} $ and $q ( x ) = 0$ for $x > a$, then $A ( x , y ) = 0$ for $y \geq x \geq a$, $F ( x ) = 0$ for $x = 2 a$, and $A ( y ) : = A ( 0 , y ) = 0$ for $y \geq 2 a$. Since $f ( k ) = 1 + \int _ { 0 } ^ { \infty } A ( y ) e ^ { i k y } d y$, it follows that $f ( k )$ is an entire function of order $1$ and type $\leq 2 a$, and $S ( k ) = f ( - k ) / f ( k )$ is meromorphic on the whole complex $k$-plane (cf. also Meromorphic function).

Conversely, if the scattering data $\mathcal{S}$ correspond to a $q \in L _ { 1 , 1} $ (necessary and sufficient conditions for this were given above) and generate (by solving the Riemann problem mentioned above) the function $f ( k )$ which is an entire function of exponential type $\leq 2 a$, then $q ( x ) = 0$ for $x > a$, (see [a6]).

References