Differential operators in cylindrical coordinates: Difference between revisions
m (Apwillis moved page Differential operators in cylindrical geometry to Differential operators in cylindrical coordinates) |
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+ A_z\,\partial_{z}B_z .$ | + A_z\,\partial_{z}B_z .$ | ||
=== Toroidal-poloidal | === Toroidal-poloidal decompositions === | ||
'''Axial form:''' | |||
$\begin{eqnarray*} | $\begin{eqnarray*} | ||
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\end{eqnarray*}$ | \end{eqnarray*}$ | ||
where | |||
$\vec{A}_r = | $\vec{A}_r = | ||
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- \nabla^2_h \phi .$ | - \nabla^2_h \phi .$ | ||
= | $\nabla^2_h f = | ||
(\frac1{r}\,\partial_{r}+\partial_{rr}) f + \frac1{r^2}\,\partial_{\theta\theta} f .$ | |||
'''Radial form:''' | |||
$\begin{eqnarray*} | $\begin{eqnarray*} | ||
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\end{eqnarray*}$ | \end{eqnarray*}$ | ||
where | |||
$\vec{A}_r = | $\vec{A}_r = | ||
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$\vec{A}_z = | $\vec{A}_z = | ||
\phi_0 - \partial_{\theta} \psi + (2+r\partial_{r})\partial_{z} \phi .$ | \phi_0 - \partial_{\theta} \psi + (2+r\partial_{r})\partial_{z} \phi .$ | ||
$\nabla^2_c f = \frac1{r^2}\,\partial_{\theta\theta} f + \partial_{zz} f .$ |
Revision as of 02:28, 15 August 2014
$ \renewcommand{\vec}[1]{ {\bf #1} } \newcommand{\bnabla}{ \vec{\nabla} } \newcommand{\Rey}{Re} \def\vechat#1{ \hat{ \vec{#1} } } \def\mat#1{#1} $
grad, div, curl
$(\bnabla f)_r = \partial_{r}f,
\quad (\bnabla f)_\theta = \frac1{r}\, \partial_{\theta} f, \quad (\bnabla f)_z = \partial_{z} f .$
$\bnabla \cdot \vec{A} = (\frac1{r} + \partial_{r}) A_r
+ \frac1{r}\,\partial_{\theta}A_\theta + \partial_{z} A_z .$
$(\bnabla \wedge \vec{A})_r =
\frac1{r}\,\partial_{\theta} A_z - \partial_{z} A_\theta ,$
$(\bnabla \wedge \vec{A})_\theta =
\partial_{z} A_r - \partial_{r} A_z ,$
$(\bnabla \wedge \vec{A})_z =
(\frac1{r}+\partial_{r}) A_\theta - \frac1{r}\,\partial_{\theta} A_r .$
Laplacian
$\nabla^2 f = (\frac1{r}\partial_{r} + \partial_{rr} ) f
+\frac1{r^2}\,\partial_{\theta\theta} f + \partial_{zz} f .$
$(\nabla^2 \vec{A})_r =
\nabla^2 A_r - \frac{2}{r^2}\,\partial_{\theta}A_\theta - \frac{A_r}{r^2} ,$
$(\nabla^2 \vec{A})_\theta =
\nabla^2 A_\theta + \frac{2}{r^2}\,\partial_{\theta}A_r - \frac{A_\theta}{r^2} ,$
$(\nabla^2 \vec{A})_z =
\nabla^2 A_z .$
Advective operator
$(\vec{A}\cdot\bnabla\,\vec{B})_r =
A_r\,\partial_{r}B_r + \frac{A_\theta}{r}\,\partial_{\theta}B_r + A_z\,\partial_{z}B_r - \frac{A_\theta B_\theta}{r} ,$
$(\vec{A}\cdot\bnabla\,\vec{B})_\theta =
A_r\,\partial_{r}B_\theta + \frac{A_\theta}{r}\,\partial_{\theta}B_\theta + A_z\,\partial_{z}B_\theta + \frac{A_\theta B_r}{r} ,$
$(\vec{A}\cdot\bnabla\,\vec{B})_z =
A_r\,\partial_{r}B_z + \frac{A_\theta}{r}\,\partial_{\theta}B_z + A_z\,\partial_{z}B_z .$
Toroidal-poloidal decompositions
Axial form:
$\begin{eqnarray*}
& \vec{A} = \bnabla \wedge(\vechat{z}\psi) + \bnabla \wedge\bnabla \wedge(\vechat{z}\phi) , & \\ & \psi=\psi(r,\theta,z), \quad \phi=\phi(r,\theta,z). \nonumber & \end{eqnarray*}$
where
$\vec{A}_r =
\frac1{r}\,\partial_{\theta} \psi + \partial_{rz} \phi ,$
$\vec{A}_\theta =
-\partial_{r} \psi + \frac1{r}\,\partial_{\theta z} \phi ,$
$\vec{A}_z =
- \nabla^2_h \phi .$
$\nabla^2_h f =
(\frac1{r}\,\partial_{r}+\partial_{rr}) f + \frac1{r^2}\,\partial_{\theta\theta} f .$
Radial form:
$\begin{eqnarray*}
& \vec{A} = \psi_0\,\vechat{\theta} + \phi_0\,\vechat{z} + \bnabla \wedge(\vec{r}\psi) + \bnabla \wedge\bnabla \wedge(\vec{r}\phi) , & \\ & \psi_0=\psi_0(r), \quad \phi_0=\phi_0(r), \quad \psi=\psi(r,\theta,z), \quad \phi=\phi(r,\theta,z). \nonumber & \end{eqnarray*}$
where
$\vec{A}_r =
-r \nabla^2_c \phi ,$
$\vec{A}_\theta =
\psi_0 + r \partial_{z} \psi + \partial_{r\theta} \phi ,$
$\vec{A}_z =
\phi_0 - \partial_{\theta} \psi + (2+r\partial_{r})\partial_{z} \phi .$
$\nabla^2_c f = \frac1{r^2}\,\partial_{\theta\theta} f + \partial_{zz} f .$