| 2 |
% $Name$ |
% $Name$ |
| 3 |
|
|
| 4 |
\section{Spatial discretization of the dynamical equations} |
\section{Spatial discretization of the dynamical equations} |
| 5 |
|
\begin{rawhtml} |
| 6 |
|
<!-- CMIREDIR:spatial_discretization_of_dyn_eq: --> |
| 7 |
|
\end{rawhtml} |
| 8 |
|
|
| 9 |
Spatial discretization is carried out using the finite volume |
Spatial discretization is carried out using the finite volume |
| 10 |
method. This amounts to a grid-point method (namely second-order |
method. This amounts to a grid-point method (namely second-order |
| 13 |
representation of the position of the boundary. We treat the |
representation of the position of the boundary. We treat the |
| 14 |
horizontal and vertical directions as separable and differently. |
horizontal and vertical directions as separable and differently. |
| 15 |
|
|
|
\input{part2/notation} |
|
|
|
|
| 16 |
|
|
| 17 |
\subsection{The finite volume method: finite volumes versus finite difference} |
\subsection{The finite volume method: finite volumes versus finite difference} |
| 18 |
\begin{rawhtml} |
\begin{rawhtml} |
| 139 |
grid for all panels. a) The area of a tracer cell, $A_c$, is bordered |
grid for all panels. a) The area of a tracer cell, $A_c$, is bordered |
| 140 |
by the lengths $\Delta x_g$ and $\Delta y_g$. b) The area of a |
by the lengths $\Delta x_g$ and $\Delta y_g$. b) The area of a |
| 141 |
vorticity cell, $A_\zeta$, is bordered by the lengths $\Delta x_c$ and |
vorticity cell, $A_\zeta$, is bordered by the lengths $\Delta x_c$ and |
| 142 |
$\Delta y_c$. c) The area of a u cell, $A_c$, is bordered by the |
$\Delta y_c$. c) The area of a u cell, $A_w$, is bordered by the |
| 143 |
lengths $\Delta x_v$ and $\Delta y_f$. d) The area of a v cell, $A_c$, |
lengths $\Delta x_v$ and $\Delta y_f$. d) The area of a v cell, $A_s$, |
| 144 |
is bordered by the lengths $\Delta x_f$ and $\Delta y_u$.} |
is bordered by the lengths $\Delta x_f$ and $\Delta y_u$.} |
| 145 |
\label{fig:hgrid} |
\label{fig:hgrid} |
| 146 |
\end{figure} |
\end{figure} |
| 148 |
The model domain is decomposed into tiles and within each tile a |
The model domain is decomposed into tiles and within each tile a |
| 149 |
quasi-regular grid is used. A tile is the basic unit of domain |
quasi-regular grid is used. A tile is the basic unit of domain |
| 150 |
decomposition for parallelization but may be used whether parallelized |
decomposition for parallelization but may be used whether parallelized |
| 151 |
or not; see section \ref{sect:tiles} for more details. Although the |
or not; see section \ref{sect:domain_decomposition} for more details. |
| 152 |
tiles may be patched together in an unstructured manner |
Although the tiles may be patched together in an unstructured manner |
| 153 |
(i.e. irregular or non-tessilating pattern), the interior of tiles is |
(i.e. irregular or non-tessilating pattern), the interior of tiles is |
| 154 |
a structured grid of quadrilateral cells. The horizontal coordinate |
a structured grid of quadrilateral cells. The horizontal coordinate |
| 155 |
system is orthogonal curvilinear meaning we can not necessarily treat |
system is orthogonal curvilinear meaning we can not necessarily treat |
| 367 |
|
|
| 368 |
The above grid (Fig.~\ref{fig:vgrid}a) is known as the cell centered |
The above grid (Fig.~\ref{fig:vgrid}a) is known as the cell centered |
| 369 |
approach because the tracer points are at cell centers; the cell |
approach because the tracer points are at cell centers; the cell |
| 370 |
centers are mid-way between the cell interfaces. An alternative, the |
centers are mid-way between the cell interfaces. |
| 371 |
vertex or interface centered approach, is shown in |
This discretization is selected when the thickness of the |
| 372 |
|
levels are provided ({\bf delR}, parameter file {\em data}, |
| 373 |
|
namelist {\em PARM04}) |
| 374 |
|
An alternative, the vertex or interface centered approach, is shown in |
| 375 |
Fig.~\ref{fig:vgrid}b. Here, the interior interfaces are positioned |
Fig.~\ref{fig:vgrid}b. Here, the interior interfaces are positioned |
| 376 |
mid-way between the tracer nodes (no longer cell centers). This |
mid-way between the tracer nodes (no longer cell centers). This |
| 377 |
approach is formally more accurate for evaluation of hydrostatic |
approach is formally more accurate for evaluation of hydrostatic |
| 378 |
pressure and vertical advection but historically the cell centered |
pressure and vertical advection but historically the cell centered |
| 379 |
approach has been used. An alternative form of subroutine {\em |
approach has been used. An alternative form of subroutine {\em |
| 380 |
INI\_VERTICAL\_GRID} is used to select the interface centered approach |
INI\_VERTICAL\_GRID} is used to select the interface centered approach |
| 381 |
but no run time option is currently available. |
This form requires to specify $Nr+1$ vertical distances {\bf delRc} |
| 382 |
|
(parameter file {\em data}, namelist {\em PARM04}, e.g. |
| 383 |
|
{\em verification/ideal\_2D\_oce/input/data}) |
| 384 |
|
corresponding to surface to center, $Nr-1$ center to center, and center to |
| 385 |
|
bottom distances. |
| 386 |
|
%but no run time option is currently available. |
| 387 |
|
|
| 388 |
\fbox{ \begin{minipage}{4.75in} |
\fbox{ \begin{minipage}{4.75in} |
| 389 |
{\em S/R INI\_VERTICAL\_GRID} ({\em |
{\em S/R INI\_VERTICAL\_GRID} ({\em |
| 401 |
|
|
| 402 |
|
|
| 403 |
\subsection{Topography: partially filled cells} |
\subsection{Topography: partially filled cells} |
| 404 |
|
\begin{rawhtml} |
| 405 |
|
<!-- CMIREDIR:topo_partial_cells: --> |
| 406 |
|
\end{rawhtml} |
| 407 |
|
|
| 408 |
\begin{figure} |
\begin{figure} |
| 409 |
\begin{center} |
\begin{center} |
| 474 |
|
|
| 475 |
|
|
| 476 |
\section{Continuity and horizontal pressure gradient terms} |
\section{Continuity and horizontal pressure gradient terms} |
| 477 |
|
\begin{rawhtml} |
| 478 |
|
<!-- CMIREDIR:continuity_and_horizontal_pressure: --> |
| 479 |
|
\end{rawhtml} |
| 480 |
|
|
| 481 |
|
|
| 482 |
The core algorithm is based on the ``C grid'' discretization of the |
The core algorithm is based on the ``C grid'' discretization of the |
| 483 |
continuity equation which can be summarized as: |
continuity equation which can be summarized as: |
| 516 |
evaporation and only enters the top-level of the {\em ocean} model. |
evaporation and only enters the top-level of the {\em ocean} model. |
| 517 |
|
|
| 518 |
\section{Hydrostatic balance} |
\section{Hydrostatic balance} |
| 519 |
|
\begin{rawhtml} |
| 520 |
|
<!-- CMIREDIR:hydrostatic_balance: --> |
| 521 |
|
\end{rawhtml} |
| 522 |
|
|
| 523 |
The vertical momentum equation has the hydrostatic or |
The vertical momentum equation has the hydrostatic or |
| 524 |
quasi-hydrostatic balance on the right hand side. This discretization |
quasi-hydrostatic balance on the right hand side. This discretization |
Parent Directory
| 
Revision Log
| 
Revision Graph
| 
Patch