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--- manual/s_overview/text/manual.tex 2004/03/23 15:29:39 1.18
+++ manual/s_overview/text/manual.tex 2004/03/23 16:47:04 1.19
@@ -1,4 +1,4 @@
-% $Header: /home/ubuntu/mnt/e9_copy/manual/s_overview/text/manual.tex,v 1.18 2004/03/23 15:29:39 afe Exp $
+% $Header: /home/ubuntu/mnt/e9_copy/manual/s_overview/text/manual.tex,v 1.19 2004/03/23 16:47:04 afe Exp $
% $Name: $
%tci%\documentclass[12pt]{book}
@@ -34,7 +34,7 @@
% Section: Overview
-% $Header: /home/ubuntu/mnt/e9_copy/manual/s_overview/text/manual.tex,v 1.18 2004/03/23 15:29:39 afe Exp $
+% $Header: /home/ubuntu/mnt/e9_copy/manual/s_overview/text/manual.tex,v 1.19 2004/03/23 16:47:04 afe Exp $
% $Name: $
This document provides the reader with the information necessary to
@@ -49,7 +49,7 @@
\section{Introduction}
\begin{rawhtml}
-<!-- CMIREDIR:innovations -->
+<!-- CMIREDIR:innovations: -->
\end{rawhtml}
@@ -137,7 +137,7 @@
We begin by briefly showing some of the results of the model in action to
give a feel for the wide range of problems that can be addressed using it.
-% $Header: /home/ubuntu/mnt/e9_copy/manual/s_overview/text/manual.tex,v 1.18 2004/03/23 15:29:39 afe Exp $
+% $Header: /home/ubuntu/mnt/e9_copy/manual/s_overview/text/manual.tex,v 1.19 2004/03/23 16:47:04 afe Exp $
% $Name: $
\section{Illustrations of the model in action}
@@ -155,7 +155,7 @@
\subsection{Global atmosphere: `Held-Suarez' benchmark}
\begin{rawhtml}
-<!-- CMIREDIR:atmospheric_example -->
+<!-- CMIREDIR:atmospheric_example: -->
\end{rawhtml}
@@ -196,10 +196,10 @@
\subsection{Ocean gyres}
\begin{rawhtml}
-<!-- CMIREDIR:oceanic_example -->
+<!-- CMIREDIR:oceanic_example: -->
\end{rawhtml}
\begin{rawhtml}
-<!-- CMIREDIR:ocean_gyres -->
+<!-- CMIREDIR:ocean_gyres: -->
\end{rawhtml}
Baroclinic instability is a ubiquitous process in the ocean, as well as the
@@ -228,7 +228,7 @@
\subsection{Global ocean circulation}
\begin{rawhtml}
-<!-- CMIREDIR:global_ocean_circulation -->
+<!-- CMIREDIR:global_ocean_circulation: -->
\end{rawhtml}
Figure \ref{fig:large-scale-circ} (top) shows the pattern of ocean currents at
@@ -249,7 +249,7 @@
\subsection{Convection and mixing over topography}
\begin{rawhtml}
-<!-- CMIREDIR:mixing_over_topography -->
+<!-- CMIREDIR:mixing_over_topography: -->
\end{rawhtml}
@@ -272,7 +272,7 @@
\subsection{Boundary forced internal waves}
\begin{rawhtml}
-<!-- CMIREDIR:boundary_forced_internal_waves -->
+<!-- CMIREDIR:boundary_forced_internal_waves: -->
\end{rawhtml}
The unique ability of MITgcm to treat non-hydrostatic dynamics in the
@@ -294,7 +294,7 @@
\subsection{Parameter sensitivity using the adjoint of MITgcm}
\begin{rawhtml}
-<!-- CMIREDIR:parameter_sensitivity -->
+<!-- CMIREDIR:parameter_sensitivity: -->
\end{rawhtml}
Forward and tangent linear counterparts of MITgcm are supported using an
@@ -317,7 +317,7 @@
\subsection{Global state estimation of the ocean}
\begin{rawhtml}
-<!-- CMIREDIR:global_state_estimation -->
+<!-- CMIREDIR:global_state_estimation: -->
\end{rawhtml}
@@ -338,7 +338,7 @@
\subsection{Ocean biogeochemical cycles}
\begin{rawhtml}
-<!-- CMIREDIR:ocean_biogeo_cycles -->
+<!-- CMIREDIR:ocean_biogeo_cycles: -->
\end{rawhtml}
MITgcm is being used to study global biogeochemical cycles in the ocean. For
@@ -356,7 +356,7 @@
\subsection{Simulations of laboratory experiments}
\begin{rawhtml}
-<!-- CMIREDIR:classroom_exp -->
+<!-- CMIREDIR:classroom_exp: -->
\end{rawhtml}
Figure \ref{fig:lab-simulation} shows MITgcm being used to simulate a
@@ -372,12 +372,12 @@
\input{part1/lab_figure}
%%CNHend
-% $Header: /home/ubuntu/mnt/e9_copy/manual/s_overview/text/manual.tex,v 1.18 2004/03/23 15:29:39 afe Exp $
+% $Header: /home/ubuntu/mnt/e9_copy/manual/s_overview/text/manual.tex,v 1.19 2004/03/23 16:47:04 afe Exp $
% $Name: $
\section{Continuous equations in `r' coordinates}
\begin{rawhtml}
-<!-- CMIREDIR:z-p_isomorphism -->
+<!-- CMIREDIR:z-p_isomorphism: -->
\end{rawhtml}
To render atmosphere and ocean models from one dynamical core we exploit
@@ -656,7 +656,7 @@
\subsection{Hydrostatic, Quasi-hydrostatic, Quasi-nonhydrostatic and
Non-hydrostatic forms}
\begin{rawhtml}
-<!-- CMIREDIR:non_hydrostatic -->
+<!-- CMIREDIR:non_hydrostatic: -->
\end{rawhtml}
@@ -1118,7 +1118,7 @@
Tangent linear and adjoint counterparts of the forward model are described
in Chapter 5.
-% $Header: /home/ubuntu/mnt/e9_copy/manual/s_overview/text/manual.tex,v 1.18 2004/03/23 15:29:39 afe Exp $
+% $Header: /home/ubuntu/mnt/e9_copy/manual/s_overview/text/manual.tex,v 1.19 2004/03/23 16:47:04 afe Exp $
% $Name: $
\section{Appendix ATMOSPHERE}
@@ -1245,7 +1245,7 @@
\frac{D\theta }{Dt} &=&\frac{\mathcal{Q}}{\Pi }
\end{eqnarray}
-% $Header: /home/ubuntu/mnt/e9_copy/manual/s_overview/text/manual.tex,v 1.18 2004/03/23 15:29:39 afe Exp $
+% $Header: /home/ubuntu/mnt/e9_copy/manual/s_overview/text/manual.tex,v 1.19 2004/03/23 16:47:04 afe Exp $
% $Name: $
\section{Appendix OCEAN}
@@ -1461,7 +1461,7 @@
_{nh}=0$ form of these equations that are used throughout the ocean modeling
community and referred to as the primitive equations (HPE).
-% $Header: /home/ubuntu/mnt/e9_copy/manual/s_overview/text/manual.tex,v 1.18 2004/03/23 15:29:39 afe Exp $
+% $Header: /home/ubuntu/mnt/e9_copy/manual/s_overview/text/manual.tex,v 1.19 2004/03/23 16:47:04 afe Exp $
% $Name: $
\section{Appendix:OPERATORS}
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