s_examples/text/model_examples.tex

% $Header: /u/gcmpack/manual/part3/tutorials.tex,v 1.13 2006/06/27 22:34:09 edhill Exp $
% $Name:  $

\section[MITgcm Example Experiments]{Example experiments}
\label{sect:modelExamples}
\begin{rawhtml}
<!-- CMIREDIR:modelExamples: -->
\end{rawhtml}

%% a set of pre-configured numerical experiments

The full MITgcm distribution comes with a set of pre-configured
numerical experiments.  Some of these example experiments are tests of
individual parts of the model code, but many are fully fledged
numerical simulations. Full tutorials exist for a few of the examples,
and are documented in sections \ref{sect:eg-baro} -
\ref{sect:eg-tank}. The other examples follow the same general
structure as the tutorial examples. However, they only include brief
instructions in a text file called {\it README}.  The examples are
located in subdirectories under the directory \texttt{verification}.
Each example is briefly described below.

\subsection{Full list of model examples}

\begin{enumerate}
  
\item \texttt{tutorial\_barotropic\_gyre}

\item \texttt{tutorial\_barotropic\_gyre} - single layer, ocean double
  gyre (barotropic with free-surface). This experiment is described in
  detail in section \ref{sect:eg-baro}.

\item \texttt{tutorial\_baroclinic\_gyre} - Four layer, ocean double
  gyre. This experiment is described in detail in section
  \ref{sect:eg-fourlayer}.

\item \texttt{tutorial\_global\_oce\_latlon} - 4x4 degree global ocean
  simulation with steady climatological forcing. This experiment is
  described in detail in section \ref{sect:eg-global}.

\item \texttt{exp4} - Flow over a Gaussian bump in open-water or
  channel with open boundaries.
  
\item \texttt{tutorial\_deep\_convection} - Inhomogenously forced
  ocean convection in a doubly periodic box. This experiment is
  described in detail in section \ref{sect:eg-bconv}.

\item \texttt{front\_relax} - Relaxation of an ocean thermal front
  (test for Gent/McWilliams scheme). 2D (Y-Z).

\item \texttt{internal\_wave} - Ocean internal wave forced by open
  boundary conditions.
  
\item \texttt{natl\_box} - Eastern subtropical North Atlantic with KPP
  scheme; 1 month integration
  
\item \texttt{hs94.1x64x5} - Zonal averaged atmosphere using Held and
  Suarez '94 forcing.
  
\item \texttt{hs94.128x64x5} - 3D atmosphere dynamics using Held and
  Suarez '94 forcing.
  
\item \texttt{tutorial\_held\_suarez\_cs} - 3D atmosphere dynamics
  using Held and Suarez (1994) forcing on the cubed sphere.  This
  experiment is described in detail in section \ref{sect:eg-hs}.
  
\item \texttt{aim.5l\_zon-ave} - Intermediate Atmospheric physics.
  Global Zonal Mean configuration, 1x64x5 resolution.
  
\item \texttt{aim.5l\_XZ\_Equatorial\_Slice} - Intermediate
  Atmospheric physics, equatorial Slice configuration.  2D (X-Z).
  
\item \texttt{aim.5l\_Equatorial\_Channel} - Intermediate Atmospheric
  physics. 3D Equatorial Channel configuration.
  
\item \texttt{aim.5l\_LatLon} - Intermediate Atmospheric physics.
  Global configuration, on latitude longitude grid with 128x64x5 grid
  points ($2.8^\circ$ resolution).
  
\item \texttt{aim.5l\_cs}

\item \texttt{adjustment.128x64x1} Barotropic adjustment problem on
  latitude longitude grid with 128x64 grid points ($2.8^\circ$ resolution).
  
\item \texttt{adjustment.cs-32x32x1} Barotropic adjustment problem on
  cube sphere grid with 32x32 points per face (roughly $2.8^\circ$
  resolution).
  
\item \texttt{advect\_cs} Two-dimensional passive advection test on
  cube sphere grid.
  
\item \texttt{advect\_xy} Two-dimensional (horizontal plane) passive
  advection test on Cartesian grid.
  
\item \texttt{advect\_xz} Two-dimensional (vertical plane) passive
  advection test on Cartesian grid.
  
\item \texttt{tutorial\_tracer\_adjsens} Simple passive tracer
  experiment. Includes derivative calculation. This experiment is
  described in detail in section \ref{sect:eg-simple-tracer}.

\item \texttt{flt\_example} Example of using float package.
  
\item \texttt{global\_ocean.90x40x15} Global circulation with GM, flux
  boundary conditions and poles.

\item \texttt{tutorial\_global\_oce\_in\_p} Global circulation in
  pressure coordinate (non-Boussinesq ocean model). Described in
  detail in section \ref{sect:eg-globalpressure}.

\item \texttt{solid-body.cs-32x32x1} Solid body rotation test for cube
  sphere grid.

\item \texttt{tutorial\_plume\_on\_slope} Gravity Plume on a
  continental slope.  This experiment is described in detail in
  section \ref{sect:eg-gravityplume}.

\item \texttt{tutorial\_global\_oce\_biogeo} Ocean model coupled to
  the dissolved inorganic carbon biogeochemistry model. This
  experiment is described in detail in section
  \ref{sect:eg-biogeochem_tutorial}.

\item \texttt{tutorial\_global\_oce\_optim} Global ocean state
  estimation at $4^\circ$ resolution.  This experiment is described in
  detail in section \ref{sect:eg-global_state_estimate}.

\item \texttt{tutorial\_offline} Offline form of the MITgcm to study
  advection of a passive tracer.  This experiment is described in
  detail in section \ref{sect:eg-offline}.

\item \texttt{rotating\_tank} Rotating tank simulation in cylindrical
  coordinates.  This experiment is described in detail in section
  \ref{sect:eg-tank}.

\item \texttt{MLAdjust} Simple test for different viscosity formulations.

\item \texttt{bottom\_ctrl\_5x5} Adjoint test using the bottom
  topography as the control parameter.

\item \texttt{cfc\_example} Global ocean with online computation and
  advection of CFC11 and CFC12.

\item \texttt{dome} Idealized 3D test of a density-driven bottom current.

\item \texttt{exp2} Old version of the global ocean experiment.

\item \texttt{exp5} Deep convection.

\item \texttt{fizhi-cs-32x32x10} Global atmospheric simulation with
  realistic topography, 10 vertical levels, a cubed sphere grid and
  the full atmospheric physics package.

\item \texttt{fizhi-cs-aqualev20} Global atmospheric simulation on an
  aqua planet with full atmospheric physics. Run is perpetual march
  with an analytical SST distribution.  This is the configuration for
  the APE (Aqua Planet Experiment) participation experiment.

\item \texttt{fizhi-gridalt-hs} Global atmospheric simulation
  Held-Suarez (1994) forcing, with the physical forcing and the
  dynamical forcing running on different vertical grids.

\item \texttt{global\_ocean.cs32x15} Global ocean experiment on the
  cubed sphere grid, using thermodynamic sea ice and bulk force
  packages.

\item \texttt{global\_ocean\_ebm} Global ocean experiment on a lat-lon
  grid coupled to an atmospheric energy balance model. Similar to
  global\_ocean.90x40x15 experiment.

\item \texttt{global\_with\_exf} Global ocean experiment on a lat-lon
  grid using the exf package. Similar to global\_ocean.90x40x15
  experiment.

\item \texttt{hs94.cs-32x32x5} 3D atmosphere dynamics using Held and
  Suarez (1994) forcing on the cubed sphere. 5 vertical levels.

\item \texttt{ideal\_2D\_oce} Idealized 2D global ocean simulation on
  an aqua planet.

\item \texttt{inverted\_barometer} Simple test of ocean response to
  atmospheric pressure loading.

\item \texttt{lab\_sea} Regional Labrador Sea simulation on a lat-lon
  grid. Coupled to the sea ice model.

\item \texttt{matrix\_example} Test of experimental method to
  accelerated convergence towards equillibrium.

\item \texttt{tutorial\_cfc\_offline} Offline form of the MITgcm to
  study advection of a passive tracer and CFCs.

\item \texttt{vermix} Simple test in a small domain (3 columns) for
  ocean vertical mixing schemes.

\end{enumerate}

\subsection{Directory structure of model examples}

Each example directory has the following subdirectories:

\begin{itemize}
\item \texttt{code}: contains the code particular to the example. At a
  minimum, this directory includes the following files:

  \begin{itemize}
  \item \texttt{code/packages.conf}: declares the list of packages or
    package groups to be used.  If not included, the default version
    is located in \texttt{pkg/pkg\_default}.  Package groups are
    simply convenient collections of commonly used packages which are
    defined in \texttt{pkg/pkg\_default}.  Some packages may require
    other packages or may require their absence (that is, they are
    incompatible) and these package dependencies are listed in
    \texttt{pkg/pkg\_depend}.

  \item \texttt{code/CPP\_EEOPTIONS.h}: declares CPP keys relative to
    the ``execution environment'' part of the code. The default
    version is located in \texttt{eesupp/inc}.
  
  \item \texttt{code/CPP\_OPTIONS.h}: declares CPP keys relative to
    the ``numerical model'' part of the code. The default version is
    located in \texttt{model/inc}.
  
  \item \texttt{code/SIZE.h}: declares size of underlying
    computational grid.  The default version is located in
    \texttt{model/inc}.
  \end{itemize}
  
  In addition, other include files and subroutines might be present in
  \texttt{code} depending on the particular experiment. See Section 2
  for more details.
  
\item \texttt{input}: contains the input data files required to run
  the example. At a minimum, the \texttt{input} directory contains the
  following files:

  \begin{itemize}
  \item \texttt{input/data}: this file, written as a namelist,
    specifies the main parameters for the experiment.
  
  \item \texttt{input/data.pkg}: contains parameters relative to the
    packages used in the experiment.
  
  \item \texttt{input/eedata}: this file contains ``execution
    environment'' data. At present, this consists of a specification
    of the number of threads to use in $X$ and $Y$ under multithreaded
    execution.
  \end{itemize}
  
  In addition, you will also find in this directory the forcing and
  topography files as well as the files describing the initial state
  of the experiment.  This varies from experiment to experiment. See
  the verification directories refered to in this chapter for more details.

\item \texttt{results}: this directory contains the output file
  \texttt{output.txt} produced by the simulation example. This file is
  useful for comparison with your own output when you run the
  experiment.

\item \texttt{build}: this directory is where the model is compiled
  and loaded, and where the executable resides.

\end{itemize}

Once you have chosen the example you want to run, you are ready to
compile the code.


\newpage
\input{part3/case_studies/barotropic_gyre/baro.tex}

\newpage
\input{part3/case_studies/fourlayer_gyre/fourlayer.tex}

\newpage
\input{part3/case_studies/climatalogical_ogcm/climatalogical_ogcm.tex}

\newpage
\input{part3/case_studies/ogcm_in_pressure/ogcm_in_pressure.tex}

\newpage
\input{part3/case_studies/held_suarez_cs/held_suarez_cs.tex}

\newpage
\input{part3/case_studies/doubly_periodic_convection/convection.tex}

\newpage
\input{part3/case_studies/plume_on_slope/plume_on_slope.tex}

\newpage
\input{part3/case_studies/carbon_outgassing_sensitivity/co2sens.tex}

\newpage
\input{part3/case_studies/biogeochem_tutorial/biogeochem.tex}

\newpage
\input{part3/case_studies/global_oce_estimation/global_oce_estimation.tex}

\newpage
\input{part3/case_studies/sens_airsea_tracer/doc_ad_examples.tex}

\newpage
\input{part3/case_studies/offline/offline_tutorial.tex}

\newpage
\input{part3/case_studies/rotating_tank/tank.tex}
1	molod	1.14	% $Header: /u/gcmpack/manual/part3/tutorials.tex,v 1.13 2006/06/27 22:34:09 edhill Exp $
2	adcroft	1.1	% $Name: $
3
4	molod	1.11	\section[MITgcm Example Experiments]{Example experiments}
5			\label{sect:modelExamples}
6			\begin{rawhtml}
7			<!-- CMIREDIR:modelExamples: -->
8			\end{rawhtml}
9
10			%% a set of pre-configured numerical experiments
11
12	edhill	1.13	The full MITgcm distribution comes with a set of pre-configured
13			numerical experiments. Some of these example experiments are tests of
14			individual parts of the model code, but many are fully fledged
15			numerical simulations. Full tutorials exist for a few of the examples,
16			and are documented in sections \ref{sect:eg-baro} -
17			\ref{sect:eg-tank}. The other examples follow the same general
18			structure as the tutorial examples. However, they only include brief
19			instructions in a text file called {\it README}. The examples are
20			located in subdirectories under the directory \texttt{verification}.
21			Each example is briefly described below.
22	molod	1.11
23			\subsection{Full list of model examples}
24
25			\begin{enumerate}
26
27	molod	1.12	\item \texttt{tutorial\_barotropic\_gyre}
28
29	edhill	1.13	\item \texttt{tutorial\_barotropic\_gyre} - single layer, ocean double
30			gyre (barotropic with free-surface). This experiment is described in
31			detail in section \ref{sect:eg-baro}.
32
33			\item \texttt{tutorial\_baroclinic\_gyre} - Four layer, ocean double
34			gyre. This experiment is described in detail in section
35			\ref{sect:eg-fourlayer}.
36
37			\item \texttt{tutorial\_global\_oce\_latlon} - 4x4 degree global ocean
38			simulation with steady climatological forcing. This experiment is
39			described in detail in section \ref{sect:eg-global}.
40
41			\item \texttt{exp4} - Flow over a Gaussian bump in open-water or
42			channel with open boundaries.
43
44			\item \texttt{tutorial\_deep\_convection} - Inhomogenously forced
45			ocean convection in a doubly periodic box. This experiment is
46			described in detail in section \ref{sect:eg-bconv}.
47	molod	1.11
48	edhill	1.13	\item \texttt{front\_relax} - Relaxation of an ocean thermal front
49			(test for Gent/McWilliams scheme). 2D (Y-Z).
50	molod	1.11
51			\item \texttt{internal\_wave} - Ocean internal wave forced by open
52			boundary conditions.
53
54			\item \texttt{natl\_box} - Eastern subtropical North Atlantic with KPP
55			scheme; 1 month integration
56
57			\item \texttt{hs94.1x64x5} - Zonal averaged atmosphere using Held and
58			Suarez '94 forcing.
59
60			\item \texttt{hs94.128x64x5} - 3D atmosphere dynamics using Held and
61			Suarez '94 forcing.
62
63	edhill	1.13	\item \texttt{tutorial\_held\_suarez\_cs} - 3D atmosphere dynamics
64			using Held and Suarez (1994) forcing on the cubed sphere. This
65			experiment is described in detail in section \ref{sect:eg-hs}.
66	molod	1.11
67			\item \texttt{aim.5l\_zon-ave} - Intermediate Atmospheric physics.
68			Global Zonal Mean configuration, 1x64x5 resolution.
69
70			\item \texttt{aim.5l\_XZ\_Equatorial\_Slice} - Intermediate
71			Atmospheric physics, equatorial Slice configuration. 2D (X-Z).
72
73			\item \texttt{aim.5l\_Equatorial\_Channel} - Intermediate Atmospheric
74			physics. 3D Equatorial Channel configuration.
75
76			\item \texttt{aim.5l\_LatLon} - Intermediate Atmospheric physics.
77			Global configuration, on latitude longitude grid with 128x64x5 grid
78			points ($2.8^\circ$ resolution).
79
80	edhill	1.13	\item \texttt{aim.5l\_cs}
81	molod	1.12
82	molod	1.11	\item \texttt{adjustment.128x64x1} Barotropic adjustment problem on
83			latitude longitude grid with 128x64 grid points ($2.8^\circ$ resolution).
84
85			\item \texttt{adjustment.cs-32x32x1} Barotropic adjustment problem on
86			cube sphere grid with 32x32 points per face (roughly $2.8^\circ$
87			resolution).
88
89			\item \texttt{advect\_cs} Two-dimensional passive advection test on
90			cube sphere grid.
91
92			\item \texttt{advect\_xy} Two-dimensional (horizontal plane) passive
93			advection test on Cartesian grid.
94
95	molod	1.12	\item \texttt{advect\_xz} Two-dimensional (vertical plane) passive
96	molod	1.11	advection test on Cartesian grid.
97
98	edhill	1.13	\item \texttt{tutorial\_tracer\_adjsens} Simple passive tracer
99			experiment. Includes derivative calculation. This experiment is
100			described in detail in section \ref{sect:eg-simple-tracer}.
101	molod	1.11
102			\item \texttt{flt\_example} Example of using float package.
103
104			\item \texttt{global\_ocean.90x40x15} Global circulation with GM, flux
105			boundary conditions and poles.
106
107	edhill	1.13	\item \texttt{tutorial\_global\_oce\_in\_p} Global circulation in
108			pressure coordinate (non-Boussinesq ocean model). Described in
109			detail in section \ref{sect:eg-globalpressure}.
110	molod	1.11
111			\item \texttt{solid-body.cs-32x32x1} Solid body rotation test for cube
112			sphere grid.
113
114	edhill	1.13	\item \texttt{tutorial\_plume\_on\_slope} Gravity Plume on a
115			continental slope. This experiment is described in detail in
116			section \ref{sect:eg-gravityplume}.
117
118			\item \texttt{tutorial\_global\_oce\_biogeo} Ocean model coupled to
119			the dissolved inorganic carbon biogeochemistry model. This
120			experiment is described in detail in section
121			\ref{sect:eg-biogeochem_tutorial}.
122
123			\item \texttt{tutorial\_global\_oce\_optim} Global ocean state
124			estimation at $4^\circ$ resolution. This experiment is described in
125			detail in section \ref{sect:eg-global_state_estimate}.
126
127			\item \texttt{tutorial\_offline} Offline form of the MITgcm to study
128			advection of a passive tracer. This experiment is described in
129			detail in section \ref{sect:eg-offline}.
130
131			\item \texttt{rotating\_tank} Rotating tank simulation in cylindrical
132			coordinates. This experiment is described in detail in section
133			\ref{sect:eg-tank}.
134	molod	1.11
135	molod	1.12	\item \texttt{MLAdjust} Simple test for different viscosity formulations.
136
137	edhill	1.13	\item \texttt{bottom\_ctrl\_5x5} Adjoint test using the bottom
138			topography as the control parameter.
139	molod	1.12
140	edhill	1.13	\item \texttt{cfc\_example} Global ocean with online computation and
141			advection of CFC11 and CFC12.
142	molod	1.12
143			\item \texttt{dome} Idealized 3D test of a density-driven bottom current.
144
145			\item \texttt{exp2} Old version of the global ocean experiment.
146
147			\item \texttt{exp5} Deep convection.
148
149	edhill	1.13	\item \texttt{fizhi-cs-32x32x10} Global atmospheric simulation with
150			realistic topography, 10 vertical levels, a cubed sphere grid and
151			the full atmospheric physics package.
152
153			\item \texttt{fizhi-cs-aqualev20} Global atmospheric simulation on an
154			aqua planet with full atmospheric physics. Run is perpetual march
155			with an analytical SST distribution. This is the configuration for
156			the APE (Aqua Planet Experiment) participation experiment.
157
158			\item \texttt{fizhi-gridalt-hs} Global atmospheric simulation
159			Held-Suarez (1994) forcing, with the physical forcing and the
160			dynamical forcing running on different vertical grids.
161
162			\item \texttt{global\_ocean.cs32x15} Global ocean experiment on the
163			cubed sphere grid, using thermodynamic sea ice and bulk force
164			packages.
165
166			\item \texttt{global\_ocean\_ebm} Global ocean experiment on a lat-lon
167			grid coupled to an atmospheric energy balance model. Similar to
168			global\_ocean.90x40x15 experiment.
169	molod	1.12
170	edhill	1.13	\item \texttt{global\_with\_exf} Global ocean experiment on a lat-lon
171			grid using the exf package. Similar to global\_ocean.90x40x15
172			experiment.
173	molod	1.12
174	edhill	1.13	\item \texttt{hs94.cs-32x32x5} 3D atmosphere dynamics using Held and
175			Suarez (1994) forcing on the cubed sphere. 5 vertical levels.
176	molod	1.12
177	edhill	1.13	\item \texttt{ideal\_2D\_oce} Idealized 2D global ocean simulation on
178			an aqua planet.
179	molod	1.12
180	edhill	1.13	\item \texttt{inverted\_barometer} Simple test of ocean response to
181			atmospheric pressure loading.
182	molod	1.12
183	edhill	1.13	\item \texttt{lab\_sea} Regional Labrador Sea simulation on a lat-lon
184			grid. Coupled to the sea ice model.
185	molod	1.12
186	edhill	1.13	\item \texttt{matrix\_example} Test of experimental method to
187			accelerated convergence towards equillibrium.
188	molod	1.12
189	edhill	1.13	\item \texttt{tutorial\_cfc\_offline} Offline form of the MITgcm to
190			study advection of a passive tracer and CFCs.
191	molod	1.12
192	edhill	1.13	\item \texttt{vermix} Simple test in a small domain (3 columns) for
193			ocean vertical mixing schemes.
194	molod	1.12
195	molod	1.11	\end{enumerate}
196
197			\subsection{Directory structure of model examples}
198
199			Each example directory has the following subdirectories:
200
201			\begin{itemize}
202			\item \texttt{code}: contains the code particular to the example. At a
203			minimum, this directory includes the following files:
204
205			\begin{itemize}
206			\item \texttt{code/packages.conf}: declares the list of packages or
207			package groups to be used. If not included, the default version
208			is located in \texttt{pkg/pkg\_default}. Package groups are
209			simply convenient collections of commonly used packages which are
210			defined in \texttt{pkg/pkg\_default}. Some packages may require
211			other packages or may require their absence (that is, they are
212			incompatible) and these package dependencies are listed in
213			\texttt{pkg/pkg\_depend}.
214
215			\item \texttt{code/CPP\_EEOPTIONS.h}: declares CPP keys relative to
216			the ``execution environment'' part of the code. The default
217			version is located in \texttt{eesupp/inc}.
218
219			\item \texttt{code/CPP\_OPTIONS.h}: declares CPP keys relative to
220			the ``numerical model'' part of the code. The default version is
221			located in \texttt{model/inc}.
222
223			\item \texttt{code/SIZE.h}: declares size of underlying
224			computational grid. The default version is located in
225			\texttt{model/inc}.
226			\end{itemize}
227
228			In addition, other include files and subroutines might be present in
229			\texttt{code} depending on the particular experiment. See Section 2
230			for more details.
231
232			\item \texttt{input}: contains the input data files required to run
233			the example. At a minimum, the \texttt{input} directory contains the
234			following files:
235
236			\begin{itemize}
237			\item \texttt{input/data}: this file, written as a namelist,
238			specifies the main parameters for the experiment.
239
240			\item \texttt{input/data.pkg}: contains parameters relative to the
241			packages used in the experiment.
242
243			\item \texttt{input/eedata}: this file contains ``execution
244			environment'' data. At present, this consists of a specification
245			of the number of threads to use in $X$ and $Y$ under multithreaded
246			execution.
247			\end{itemize}
248
249			In addition, you will also find in this directory the forcing and
250			topography files as well as the files describing the initial state
251			of the experiment. This varies from experiment to experiment. See
252	molod	1.14	the verification directories refered to in this chapter for more details.
253	molod	1.11
254			\item \texttt{results}: this directory contains the output file
255			\texttt{output.txt} produced by the simulation example. This file is
256			useful for comparison with your own output when you run the
257			experiment.
258	molod	1.14
259			\item \texttt{build}: this directory is where the model is compiled
260			and loaded, and where the executable resides.
261
262	molod	1.11	\end{itemize}
263
264			Once you have chosen the example you want to run, you are ready to
265			compile the code.
266
267
268			\newpage
269	adcroft	1.1	\input{part3/case_studies/barotropic_gyre/baro.tex}
270
271			\newpage
272			\input{part3/case_studies/fourlayer_gyre/fourlayer.tex}
273
274			\newpage
275			\input{part3/case_studies/climatalogical_ogcm/climatalogical_ogcm.tex}
276	mlosch	1.3
277			\newpage
278			\input{part3/case_studies/ogcm_in_pressure/ogcm_in_pressure.tex}
279	adcroft	1.1
280			\newpage
281	jmc	1.8	\input{part3/case_studies/held_suarez_cs/held_suarez_cs.tex}
282	adcroft	1.1
283			\newpage
284			\input{part3/case_studies/doubly_periodic_convection/convection.tex}
285
286			\newpage
287			\input{part3/case_studies/plume_on_slope/plume_on_slope.tex}
288
289			\newpage
290			\input{part3/case_studies/carbon_outgassing_sensitivity/co2sens.tex}
291	afe	1.5
292	edhill	1.6	\newpage
293			\input{part3/case_studies/biogeochem_tutorial/biogeochem.tex}
294
295	dfer	1.7	\newpage
296			\input{part3/case_studies/global_oce_estimation/global_oce_estimation.tex}
297
298	edhill	1.9	\newpage
299	molod	1.11	\input{part3/case_studies/sens_airsea_tracer/doc_ad_examples.tex}
300
301			\newpage
302	edhill	1.9	\input{part3/case_studies/offline/offline_tutorial.tex}
303
304	afe	1.5	\newpage
305			\input{part3/case_studies/rotating_tank/tank.tex}