--- manual/s_examples/rotating_tank/tank.tex	2004/06/22 15:07:37	1.1
+++ manual/s_examples/rotating_tank/tank.tex	2004/07/27 13:40:09	1.9
@@ -1,39 +1,45 @@
-% $Header: /home/ubuntu/mnt/e9_copy/manual/s_examples/rotating_tank/tank.tex,v 1.1 2004/06/22 15:07:37 afe Exp $
+% $Header: /home/ubuntu/mnt/e9_copy/manual/s_examples/rotating_tank/tank.tex,v 1.9 2004/07/27 13:40:09 afe Exp $
 % $Name:  $
 
 \bodytext{bgcolor="#FFFFFFFF"}
 
 %\begin{center} 
-%{\Large \bf Using MITgcm to Simulate a Rotating Tank in Cylindrical 
+%{\Large \bf Using MITgcm to Simulate a Rotating Tank in Cylindrical
 %Coordinates}
 %
 %\vspace*{4mm}
 %
 %\vspace*{3mm}
-%{\large June 2004}
+%{\large May 2001}
 %\end{center}
 
-This is the first in a series of tutorials describing
-example MITgcm numerical experiments. The example experiments 
-include both straightforward examples of idealized geophysical 
-fluid simulations and more involved cases encompassing
-large scale modeling and
-automatic differentiation. Both hydrostatic and non-hydrostatic 
-experiments are presented, as well as experiments employing
-Cartesian, spherical-polar and cube-sphere coordinate systems.
-These ``case study'' documents include information describing
-the experimental configuration and detailed information on how to
-configure the MITgcm code and input files for each experiment.
+\section{A Rotating Tank in Cylindrical Coordinates}
+\label{sect:eg-tank}
+\label{www:tutorials}
+
+This section illustrates an example of MITgcm simulating a laboratory
+experiment on much smaller scales than those common to geophysical
+fluid dynamics.
 
-\section{Barotropic Ocean Gyre In Cartesian Coordinates}
-\label{sect:eg-baro}
+\subsection{Overview}
 \label{www:tutorials}
+                                                                                
+                                                                                
+This example experiment demonstrates using the MITgcm to simulate
+a laboratory experiment with a rotating tank of water with an ice
+bucket in the center. The simulation is configured for a laboratory
+scale on a
+$3^{\circ}$ $\times$ 20cm
+cyclindrical grid with twenty-nine vertical
+levels.
+\\
+
 
 
+ 
 
 \subsection{Equations Solved}
 \label{www:tutorials}
-The model is configured in hydrostatic form. The implicit free surface form of the
 
 
 \subsection{Discrete Numerical Configuration}
@@ -45,26 +51,24 @@
 that there are sixty grid cells in the $x$ and $y$ directions. Vertically the 
 model is configured with a single layer with depth, $\Delta z$, of $5000$~m. 
 
-\subsubsection{Numerical Stability Criteria}
-\label{www:tutorials}
-
 
 \subsection{Code Configuration}
 \label{www:tutorials}
 \label{SEC:eg-baro-code_config}
 
-The model configuration for this experiment resides under the 
-directory {\it verification/exp0/}.  The experiment files 
+The model configuration for this experiment resides under the
+directory {\it verification/rotatingi\_tank/}.  The experiment files
 \begin{itemize}
 \item {\it input/data}
 \item {\it input/data.pkg}
 \item {\it input/eedata},
-\item {\it input/windx.sin\_y},
-\item {\it input/topog.box},
+\item {\it input/bathyPol.bin},
+\item {\it input/thetaPol.bin},
 \item {\it code/CPP\_EEOPTIONS.h}
 \item {\it code/CPP\_OPTIONS.h},
-\item {\it code/SIZE.h}. 
+\item {\it code/SIZE.h}.
 \end{itemize}
+
 contain the code customizations and parameter settings for this 
 experiments. Below we describe the customizations
 to these files associated with this experiment.
@@ -78,17 +82,23 @@
 
 \begin{itemize}
 
-\item Line 7, \begin{verbatim} viscAh=4.E2, \end{verbatim} this line sets
-the Laplacian friction coefficient to $400 m^2s^{-1}$
+\item Line X, \begin{verbatim} viscAh=5.0E-6, \end{verbatim} this line sets
+the Laplacian friction coefficient to $0.000006 m^2s^{-1}$, which is ususally 
+low because of the small scale, presumably.... qqq
+
+\item Line X, \begin{verbatim}f0=0.5 , \end{verbatim} this line sets the 
+coriolis term, and represents a tank spinning at qqq
 \item Line 10, \begin{verbatim} beta=1.E-11, \end{verbatim} this line sets
 $\beta$ (the gradient of the coriolis parameter, $f$) to $10^{-11} s^{-1}m^{-1}$
 
 \item Lines 15 and 16
 \begin{verbatim}
-rigidLid=.FALSE.,
-implicitFreeSurface=.TRUE.,
+rigidLid=.TRUE.,
+implicitFreeSurface=.FALSE.,
 \end{verbatim}
-these lines suppress the rigid lid formulation of the surface
+
+these lines do the opposite of the following: 
+suppress the rigid lid formulation of the surface
 pressure inverter and activate the implicit free surface form
 of the pressure inverter.
 
@@ -100,76 +110,78 @@
 and implicitly suppresses searching for checkpoint files associated
 with restarting an numerical integration from a previously saved state.
 
-\item Line 29,
-\begin{verbatim}
-endTime=12000,
-\end{verbatim}
-this line indicates that the experiment should start finish at $t=12000s$.
-A restart file will be written at this time that will enable the
-simulation to be continued from this point.
-
 \item Line 30,
 \begin{verbatim}
-deltaTmom=1200,
+deltaT=0.1,
 \end{verbatim}
-This line sets the momentum equation timestep to $1200s$.
+This line sets the integration timestep to $0.1s$.  This is an unsually
+small value among the examples due to the small physical scale of the 
+experiment.
 
 \item Line 39,
 \begin{verbatim}
-usingCartesianGrid=.TRUE.,
+usingCylindricalGrid=.TRUE.,
 \end{verbatim}
 This line requests that the simulation be performed in a 
-Cartesian coordinate system.
+cylindrical coordinate system.
 
-\item Line 41,
+\item Line qqq,
 \begin{verbatim}
-delX=60*20E3,
+dXspacing=3,
 \end{verbatim}
-This line sets the horizontal grid spacing between each x-coordinate line
+This line sets the azimuthal grid spacing between each x-coordinate line
 in the discrete grid. The syntax indicates that the discrete grid
-should be comprise of $60$ grid lines each separated by $20 \times 10^{3}m$
-($20$~km).
+should be comprise of $120$ grid lines each separated by $3^{\circ}$.
+                                                                                
+
 
-\item Line 42,
+\item Line qqq,
 \begin{verbatim}
-delY=60*20E3,
+dYspacing=0.01,
 \end{verbatim}
-This line sets the horizontal grid spacing between each y-coordinate line
-in the discrete grid to $20 \times 10^{3}m$ ($20$~km).
+This line sets the radial grid spacing between each $\rho$-coordinate line
+in the discrete grid to $1cm$.
 
 \item Line 43,
 \begin{verbatim}
-delZ=5000,
+delZ=29*0.005,
 \end{verbatim}
 This line sets the vertical grid spacing between each z-coordinate line
 in the discrete grid to $5000m$ ($5$~km).
 
 \item Line 46,
 \begin{verbatim}
-bathyFile='topog.box'
+bathyFile='bathyPol.bin',
 \end{verbatim}
 This line specifies the name of the file from which the domain
-bathymetry is read. This file is a two-dimensional ($x,y$) map of
+``bathymetry'' (tank depth) is read. This file is a two-dimensional 
+($x,y$) map of
 depths. This file is assumed to contain 64-bit binary numbers 
-giving the depth of the model at each grid cell, ordered with the x 
+giving the depth of the model at each grid cell, ordered with the $x$ 
 coordinate varying fastest. The points are ordered from low coordinate
-to high coordinate for both axes. The units and orientation of the
+to high coordinate for both axes.  The units and orientation of the
 depths in this file are the same as used in the MITgcm code. In this
-experiment, a depth of $0m$ indicates a solid wall and a depth
-of $-5000m$ indicates open ocean. The matlab program
-{\it input/gendata.m} shows an example of how to generate a
-bathymetry file.
-
+experiment, a depth of $0m$ indicates an area outside of the tank
+and a depth
+f $-0.145m$ indicates the tank itself. 
 
 \item Line 49,
 \begin{verbatim}
-zonalWindFile='windx.sin_y'
+hydrogThetaFile='thetaPol.bin',
 \end{verbatim}
-This line specifies the name of the file from which the x-direction
-surface wind stress is read. This file is also a two-dimensional
-($x,y$) map and is enumerated and formatted in the same manner as the 
-bathymetry file. The matlab program {\it input/gendata.m} includes example 
-code to generate a valid {\bf zonalWindFile} file.  
+This line specifies the name of the file from which the initial values 
+of $\theta$ 
+are read. This file is a three-dimensional
+($x,y,z$) map and is enumerated and formatted in the same manner as the 
+bathymetry file. 
+
+\item Line qqq
+\begin{verbatim}
+ tCyl  = 0
+\end{verbatim}
+This line specifies the temperature in degrees Celsius of the interior
+wall of the tank -- usually a bucket of ice water.
+
 
 \end{itemize}
 
@@ -177,9 +189,9 @@
 that are described in the MITgcm Getting Started and MITgcm Parameters
 notes.
 
-%%\begin{small}
-%%\input{part3/case_studies/barotropic_gyre/input/data}
-%%\end{small}
+\begin{small}
+\input{part3/case_studies/rotating_tank/input/data}
+\end{small}
 
 \subsubsection{File {\it input/data.pkg}}
 \label{www:tutorials}
@@ -193,28 +205,21 @@
 This file uses standard default values and does not contain
 customizations for this experiment.
 
-\subsubsection{File {\it input/windx.sin\_y}}
+\subsubsection{File {\it input/thetaPol.bin}}
 \label{www:tutorials}
 
-The {\it input/windx.sin\_y} file specifies a two-dimensional ($x,y$) 
-map of wind stress ,$\tau_{x}$, values. The units used are $Nm^{-2}$.
-Although $\tau_{x}$ is only a function of $y$n in this experiment
-this file must still define a complete two-dimensional map in order
-to be compatible with the standard code for loading forcing fields 
-in MITgcm. The included matlab program {\it input/gendata.m} gives a complete
-code for creating the {\it input/windx.sin\_y} file.
+The {\it input/thetaPol.bin} file specifies a three-dimensional ($x,y,z$) 
+map of initial values of $\theta$ in degrees Celsius.
 
-\subsubsection{File {\it input/topog.box}}
+\subsubsection{File {\it input/bathyPol.bin}}
 \label{www:tutorials}
 
 
-The {\it input/topog.box} file specifies a two-dimensional ($x,y$) 
+The {\it input/bathyPol.bin} file specifies a two-dimensional ($x,y$) 
 map of depth values. For this experiment values are either
-$0m$ or {\bf -delZ}m, corresponding respectively to a wall or to deep
-ocean. The file contains a raw binary stream of data that is enumerated
+$0m$ or {\bf -delZ}m, corresponding respectively to outside or inside of
+the tank. The file contains a raw binary stream of data that is enumerated
 in the same way as standard MITgcm two-dimensional, horizontal arrays.
-The included matlab program {\it input/gendata.m} gives a complete
-code for creating the {\it input/topog.box} file.
 
 \subsubsection{File {\it code/SIZE.h}}
 \label{www:tutorials}
@@ -224,19 +229,19 @@
 \begin{itemize}
 
 \item Line 39, 
-\begin{verbatim} sNx=60, \end{verbatim} this line sets
+\begin{verbatim} sNx=120, \end{verbatim} this line sets
 the lateral domain extent in grid points for the
 axis aligned with the x-coordinate.
 
 \item Line 40, 
-\begin{verbatim} sNy=60, \end{verbatim} this line sets
+\begin{verbatim} sNy=31, \end{verbatim} this line sets
 the lateral domain extent in grid points for the
 axis aligned with the y-coordinate.
 
 \end{itemize}
 
 \begin{small}
-\input{part3/case_studies/barotropic_gyre/code/SIZE.h}
+\input{part3/case_studies/rotating_tank/code/SIZE.h}
 \end{small}
 
 \subsubsection{File {\it code/CPP\_OPTIONS.h}}