Stability of the differential equation

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Stability of the differential equation

Let $q^ { {\rm *} \, }$ denote the Hermitian conjugate of q. For equation (80) to be stable the energy $q^ { {\rm *} \, } q$ must be either constant or decaying during depth extrapolation.

$\begin{eqnarray} {d\ \over dz }\ ( q^ { {\rm *} \, } q) \ \ \ &\le&\ \ \ 0 \nonu... ...q^ { {\rm *} \, } q_z \ +\ q_z^ { {\rm *} \, } q\ \ \ &\le&\ \ \ 0\end{eqnarray}$

(82)

Substituting equation (80) into equation (82) gives

$\begin{eqnarray} q^{\rm *}\,R\,q\ +\ q^{\rm *} R^{\rm *} \, q\ \ \ &\ge&\ \ \ 0 ... ... q^ { {\rm *} \, } ( R\ +\ R^ { {\rm *} \, } ) q\ \ \ &\ge&\ \ \ 0\end{eqnarray}$

(83)

Equation (83) shows that $R\ +\ R^ { {\rm *} \, }$ must be positive semidefinite for the differential equation to be stable.

Next: Stability of the difference Up: THE BULLETPROOFING OF MUIR Previous: THE BULLETPROOFING OF MUIR

Stanford Exploration Project
10/31/1997

	$\begin{eqnarray} {d\ \over dz }\ ( q^ { {\rm } \, } q) \ \ \ &\le&\ \ \ 0 \nonu... ...q^ { {\rm } \, } q_z \ +\ q_z^ { {\rm *} \, } q\ \ \ &\le&\ \ \ 0\end{eqnarray}$
		(82)

	$\begin{eqnarray} q^{\rm }\,R\,q\ +\ q^{\rm } R^{\rm } \, q\ \ \ &\ge&\ \ \ 0 ... ... q^ { {\rm } \, } ( R\ +\ R^ { {\rm *} \, } ) q\ \ \ &\ge&\ \ \ 0\end{eqnarray}$
		(83)