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<!-- CMIREDIR:sectionexf: --> |
<!-- CMIREDIR:sectionexf: --> |
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Authors: Patrick Heimbach and Dimitris Menemenlis |
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\subsubsection{Introduction |
\subsubsection{Introduction |
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\label{sec:pkg:exf:intro}} |
\label{sec:pkg:exf:intro}} |
22 |
CPP options enable or disable different aspects of the package |
CPP options enable or disable different aspects of the package |
23 |
(Section \ref{sec:pkg:exf:config}). |
(Section \ref{sec:pkg:exf:config}). |
24 |
Runtime options, flags, filenames and field-related dates/times are |
Runtime options, flags, filenames and field-related dates/times are |
25 |
set in \texttt{data.exf} and \texttt{data.exf\_clim} |
set in \texttt{data.exf} |
26 |
(Section \ref{sec:pkg:exf:runtime}). |
(Section \ref{sec:pkg:exf:runtime}). |
27 |
A description of key subroutines is given in Section |
A description of key subroutines is given in Section |
28 |
\ref{sec:pkg:exf:subroutines}. |
\ref{sec:pkg:exf:subroutines}. |
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|
|
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\paragraph{Compile-time options |
\paragraph{Compile-time options |
38 |
\label{sec:pkg:exf:config}} |
\label{sec:pkg:exf:config}} |
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|
~ |
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|
41 |
As with all MITgcm packages, EXF can be turned on or off at compile time |
As with all MITgcm packages, EXF can be turned on or off at compile time |
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using the \texttt{packages.conf} file or the \texttt{genmake2} |
% |
43 |
\texttt{-enable=exf} or \texttt{-disable=exf} switches. |
\begin{itemize} |
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|
% |
45 |
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\item |
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using the \texttt{packages.conf} file by adding \texttt{exf} to it, |
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% |
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\item |
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or using \texttt{genmake2} adding |
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\texttt{-enable=exf} or \texttt{-disable=exf} switches |
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% |
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\item |
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\textit{required packages and CPP options}: \\ |
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EXF requires the calendar package \texttt{cal} to be enabled; |
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no additional CPP options are required. |
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% |
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\end{itemize} |
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(see Section \ref{sect:buildingCode}). |
59 |
|
|
60 |
Parts of the exf code can be enabled or disabled at compile time |
Parts of the EXF code can be enabled or disabled at compile time |
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via CPP preprocessor flags. These options are set in either |
via CPP preprocessor flags. These options are set in either |
62 |
\texttt{EXF\_OPTIONS.h} or in \texttt{ECCO\_CPPOPTIONS.h}. |
\texttt{EXF\_OPTIONS.h} or in \texttt{ECCO\_CPPOPTIONS.h}. |
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Table \ref{tab:pkg:exf:cpp} summarizes these options. |
Table \ref{tab:pkg:exf:cpp} summarizes these options. |
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|
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\begin{table}[b!] |
\begin{table}[b!] |
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|
\centering |
67 |
\label{tab:pkg:exf:cpp} |
\label{tab:pkg:exf:cpp} |
68 |
{\footnotesize |
{\footnotesize |
69 |
\begin{tabular}{|l|l|} |
\begin{tabular}{|l|l|} |
86 |
\hline |
\hline |
87 |
\multicolumn{2}{|c|}{\textit{used in conjunction with relaxation to prescribed (climatological) fields}} \\ |
\multicolumn{2}{|c|}{\textit{used in conjunction with relaxation to prescribed (climatological) fields}} \\ |
88 |
\hline |
\hline |
|
\texttt{ALLOW\_CLIMTEMP\_RELAXATION} & |
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relaxation to 3-D temperature climatology \\ |
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\texttt{ALLOW\_CLIMSALT\_RELAXATION} & |
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relaxation to 3-D salinity climatology \\ |
|
89 |
\texttt{ALLOW\_CLIMSST\_RELAXATION} & |
\texttt{ALLOW\_CLIMSST\_RELAXATION} & |
90 |
relaxation to 2-D SST climatology \\ |
relaxation to 2-D SST climatology \\ |
91 |
\texttt{ALLOW\_CLIMSSS\_RELAXATION} & |
\texttt{ALLOW\_CLIMSSS\_RELAXATION} & |
107 |
\subsubsection{Run-time parameters |
\subsubsection{Run-time parameters |
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\label{sec:pkg:exf:runtime}} |
\label{sec:pkg:exf:runtime}} |
109 |
|
|
110 |
Run-time parameters are set in files \texttt{data.pkg}, |
Run-time parameters are set in files |
111 |
and \texttt{data.pkg\_clim} (for relaxation/climatological fields) |
\texttt{data.pkg}, \texttt{data.exf}, and |
112 |
|
\texttt{data.exf\_clim} (for relaxation/climatological fields) |
113 |
which are read in \texttt{exf\_readparms.F}. |
which are read in \texttt{exf\_readparms.F}. |
114 |
Run-time parameters may be broken into 2 categories: |
Run-time parameters may be broken into 3 categories: |
115 |
(i) general flags and parameters, and |
(i) switching on/off the package at runtime, |
116 |
(ii) attributes for each forcing and climatological field. |
(ii) general flags and parameters, and |
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|
(iii) attributes for each forcing and climatological field. |
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|
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\paragraph{General flags and parameters} |
\paragraph{Enabling the package} |
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|
~ \\ |
121 |
~ |
% |
122 |
|
A package is switched on/off at runtime by setting |
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(e.g. for EXF) \texttt{useEXF = .TRUE.} in \texttt{data.pkg}. |
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|
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\paragraph{General flags and parameters} |
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~ \\ |
127 |
|
% |
128 |
\begin{table}[h!] |
\begin{table}[h!] |
129 |
|
\centering |
130 |
\label{tab:pkg:exf:runtime_flags} |
\label{tab:pkg:exf:runtime_flags} |
131 |
{\footnotesize |
{\footnotesize |
132 |
\begin{tabular}{|l|c|l|} |
\begin{tabular}{|l|c|l|} |
148 |
max. allowed wind stress $N/m^2$ \\ |
max. allowed wind stress $N/m^2$ \\ |
149 |
exf\_albedo & \texttt{0.1} & |
exf\_albedo & \texttt{0.1} & |
150 |
surface albedo used to compute downward vs. net radiative fluxes \\ |
surface albedo used to compute downward vs. net radiative fluxes \\ |
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|
climtempfreeze & \texttt{-1.9} & |
152 |
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??? \\ |
153 |
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ocean\_emissivity & \texttt{} & |
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longwave ocean-surface emissivity \\ |
155 |
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ice\_emissivity & \texttt{} & |
156 |
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longwave seaice emissivity \\ |
157 |
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snow\_emissivity & \texttt{} & |
158 |
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longwave snow emissivity \\ |
159 |
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exf\_iceCd & \texttt{1.63E-3} & |
160 |
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drag coefficient over sea-ice \\ |
161 |
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exf\_iceCe & \texttt{1.63E-3} & |
162 |
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evaporation transfer coeff. over sea-ice \\ |
163 |
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exf\_iceCh & \texttt{1.63E-3} & |
164 |
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sensible heat transfer coeff. over sea-ice \\ |
165 |
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exf\_scal\_BulkCdn & \texttt{1.} & |
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overall scaling of neutral drag coeff. \\ |
167 |
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useStabilityFct\_overIce & \texttt{.FALSE.} & |
168 |
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compute turbulent transfer coeff. over sea-ice \\ |
169 |
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readStressOnAgrid & \texttt{.FALSE.} & |
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read wind-streess located on model-grid, A-grid point \\ |
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readStressOnCgrid & \texttt{.FALSE.} & |
172 |
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read wind-streess located on model-grid, C-grid point \\ |
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useRelativeWind & \texttt{.FALSE.} & |
174 |
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subtract [U/V]VEL or [U/VICE from U/V]WIND before \\ |
175 |
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~ & ~ & computing [U/V]STRESS \\ |
176 |
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zref & \texttt{10.} & |
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reference height \\ |
178 |
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hu & \texttt{10.} & |
179 |
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height of mean wind \\ |
180 |
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ht & \texttt{2.} & |
181 |
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height of mean temperature and rel. humidity \\ |
182 |
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umin & \texttt{0.5} & |
183 |
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minimum absolute wind speed for computing Cd \\ |
184 |
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atmrho & \texttt{1.2} & |
185 |
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mean atmospheric density [kg/m\^3] \\ |
186 |
|
atmcp & \texttt{1005.} & |
187 |
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mean atmospheric specific heat [J/kg/K] \\ |
188 |
|
cdrag\_[n] & \texttt{???} & |
189 |
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n = 1,2,3; parameters for drag coeff. function \\ |
190 |
|
cstanton\_[n] & \texttt{???} & |
191 |
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n = 1,2; parameters for Stanton number function \\ |
192 |
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cdalton & \texttt{???} & |
193 |
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parameter for Dalton number function \\ |
194 |
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flamb & \texttt{2500000.} & |
195 |
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latent heat of evaporation [J/kg] \\ |
196 |
|
flami & \texttt{334000.} & |
197 |
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latent heat of melting of pure ice [J/kg] \\ |
198 |
|
zolmin & \texttt{-100.} & |
199 |
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minimum stability parameter \\ |
200 |
|
cvapor\_fac & \texttt{640380.} & |
201 |
|
~ \\ |
202 |
|
cvapor\_exp & \texttt{5107.4} & |
203 |
|
~ \\ |
204 |
|
cvapor\_fac\_ice & \texttt{11637800.} & |
205 |
|
~ \\ |
206 |
|
cvapor\_fac\_ice & \texttt{5897.8} & |
207 |
|
~ \\ |
208 |
|
humid\_fac & \texttt{0.606} & |
209 |
|
parameter for virtual temperature calculation \\ |
210 |
|
gamma\_blk & \texttt{0.010} & |
211 |
|
adiabatic lapse rate \\ |
212 |
|
saltsat & \texttt{0.980} & |
213 |
|
reduction of saturation vapor pressure over salt-water \\ |
214 |
|
psim\_fac & \texttt{5.} & |
215 |
|
~ \\ |
216 |
|
exf\_monFreq & \texttt{monitorFreq} & |
217 |
|
output frequency [s] \\ |
218 |
exf\_iprec & \texttt{32} & |
exf\_iprec & \texttt{32} & |
219 |
precision of input fields (32-bit or 64-bit) \\ |
precision of input fields (32-bit or 64-bit) \\ |
220 |
exf\_yftype & \texttt{'RL'} & |
exf\_yftype & \texttt{'RL'} & |
226 |
\end{table} |
\end{table} |
227 |
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|
228 |
|
|
229 |
\paragraph{Field attributes} ~ \\ |
\paragraph{Field attributes} |
230 |
|
~ \\ |
231 |
% |
% |
232 |
All EXF fields are listed in Section \ref{sec:pkg:exf:fields_units}. |
All EXF fields are listed in Section \ref{sec:pkg:exf:fields_units}. |
233 |
Each field has a number of attributes which can be customized. |
Each field has a number of attributes which can be customized. |
246 |
% |
% |
247 |
|
|
248 |
\begin{table}[h!] |
\begin{table}[h!] |
249 |
|
\centering |
250 |
\label{tab:pkg:exf:runtime_attributes} |
\label{tab:pkg:exf:runtime_attributes} |
251 |
{\footnotesize |
{\footnotesize |
252 |
\begin{tabular}{|l|c|l|} |
\begin{tabular}{|l|c|l|} |
322 |
|
|
323 |
%---------------------------------------------------------------------- |
%---------------------------------------------------------------------- |
324 |
|
|
325 |
|
\subsubsection{EXF bulk formulae |
326 |
|
\label{sec:pkg:exf:bulk_formulae}} |
327 |
|
|
328 |
|
T.B.D. (cross-ref. to parameter list table) |
329 |
|
|
330 |
|
%---------------------------------------------------------------------- |
331 |
|
|
332 |
\subsubsection{EXF input fields and units |
\subsubsection{EXF input fields and units |
333 |
\label{sec:pkg:exf:fields_units}} |
\label{sec:pkg:exf:fields_units}} |
334 |
|
|
339 |
\textbf{fu}, \textbf{fv}, \textbf{Qnet}, \textbf{Qsw}, \textbf{EmPmR}, |
\textbf{fu}, \textbf{fv}, \textbf{Qnet}, \textbf{Qsw}, \textbf{EmPmR}, |
340 |
and \textbf{pload}. They are defined in \texttt{FFIELDS.h}. |
and \textbf{pload}. They are defined in \texttt{FFIELDS.h}. |
341 |
|
|
342 |
{\scriptsize |
{\footnotesize |
343 |
\begin{verbatim} |
\begin{verbatim} |
344 |
|
|
345 |
c---------------------------------------------------------------------- |
c---------------------------------------------------------------------- |
361 |
c | Southwest C-grid V point |
c | Southwest C-grid V point |
362 |
c | Input field |
c | Input field |
363 |
c---------------------------------------------------------------------- |
c---------------------------------------------------------------------- |
364 |
|
c hs :: sensible heat flux into ocean in W/m^2 |
365 |
|
c | > 0 for increase in theta (ocean warming) |
366 |
|
c---------------------------------------------------------------------- |
367 |
|
c hl :: latent heat flux into ocean in W/m^2 |
368 |
|
c | > 0 for increase in theta (ocean warming) |
369 |
|
c---------------------------------------------------------------------- |
370 |
c hflux :: Net upward surface heat flux in W/m^2 |
c hflux :: Net upward surface heat flux in W/m^2 |
371 |
c | excluding shortwave (on input) |
c | excluding shortwave (on input) |
372 |
c | hflux = latent + sensible + lwflux |
c | hflux = latent + sensible + lwflux |
403 |
c | Southwest C-grid V point |
c | Southwest C-grid V point |
404 |
c | Input or input/output field |
c | Input or input/output field |
405 |
c---------------------------------------------------------------------- |
c---------------------------------------------------------------------- |
406 |
|
c wspeed :: Surface (10-m) wind speed in m/s |
407 |
|
c | >= 0 sqrt(u^2+v^2) |
408 |
|
c | Typical range: 0 < wspeed < 10 |
409 |
|
c | Input or input/output field |
410 |
|
c---------------------------------------------------------------------- |
411 |
c atemp :: Surface (2-m) air temperature in deg K |
c atemp :: Surface (2-m) air temperature in deg K |
412 |
c | Typical range: 200 < atemp < 300 |
c | Typical range: 200 < atemp < 300 |
413 |
c | Southwest C-grid tracer point |
c | Southwest C-grid tracer point |
437 |
c | Southwest C-grid tracer point |
c | Southwest C-grid tracer point |
438 |
c | Input or input/output field |
c | Input or input/output field |
439 |
c---------------------------------------------------------------------- |
c---------------------------------------------------------------------- |
440 |
|
c snowprecip :: snow in m/s |
441 |
|
c | > 0 for decrease in salt (ocean salinity) |
442 |
|
c | Typical range: 0 < precip < 5e-7 |
443 |
|
c | Input or input/output field |
444 |
|
c---------------------------------------------------------------------- |
445 |
c runoff :: River and glacier runoff in m/s |
c runoff :: River and glacier runoff in m/s |
446 |
c | > 0 for decrease in salt (ocean salinity) |
c | > 0 for decrease in salt (ocean salinity) |
447 |
c | Typical range: 0 < runoff < ???? |
c | Typical range: 0 < runoff < ???? |
479 |
|
|
480 |
Top-level routine: \texttt{exf\_getforcing.F} |
Top-level routine: \texttt{exf\_getforcing.F} |
481 |
|
|
482 |
{\scriptsize |
{\footnotesize |
483 |
\begin{verbatim} |
\begin{verbatim} |
484 |
|
|
485 |
C !CALLING SEQUENCE: |
C !CALLING SEQUENCE: |
487 |
c exf_getforcing (TOP LEVEL ROUTINE) |
c exf_getforcing (TOP LEVEL ROUTINE) |
488 |
c | |
c | |
489 |
c |-- exf_getclim (get climatological fields used e.g. for relax.) |
c |-- exf_getclim (get climatological fields used e.g. for relax.) |
|
c | |--- exf_set_climtemp (relax. to 3-D temperature field) |
|
|
c | |--- exf_set_climsalt (relax. to 3-D salinity field) |
|
490 |
c | |--- exf_set_climsst (relax. to 2-D SST field) |
c | |--- exf_set_climsst (relax. to 2-D SST field) |
491 |
c | |--- exf_set_climsss (relax. to 2-D SSS field) |
c | |--- exf_set_climsss (relax. to 2-D SSS field) |
492 |
c | o |
c | o |
497 |
c | | consecutive in time are read in and interpolated onto |
c | | consecutive in time are read in and interpolated onto |
498 |
c | | current time step). |
c | | current time step). |
499 |
c | | 2. If forcing is atmos. state and control is atmos. state, |
c | | 2. If forcing is atmos. state and control is atmos. state, |
500 |
c | | then the control variable anomalies are read here |
c | | then the control variable anomalies are read here via ctrl_get_gen |
501 |
c | | * ctrl_getatemp |
c | | (atemp, aqh, precip, swflux, swdown, uwind, vwind). |
|
c | | * ctrl_getaqh |
|
|
c | | * ctrl_getuwind |
|
|
c | | * ctrl_getvwind |
|
502 |
c | | If forcing and control are fluxes, then |
c | | If forcing and control are fluxes, then |
503 |
c | | controls are added later. |
c | | controls are added later. |
504 |
c | o |
c | o |
505 |
c | |
c | |
506 |
c |-- exf_check_range |
c |-- exf_radiation |
507 |
c | | 1. Check whether read fields are within assumed range |
c | | Compute net or downwelling radiative fluxes via |
508 |
c | | (may capture mismatches in units) |
c | | Stefan-Boltzmann law in case only one is known. |
509 |
|
c | o |
510 |
|
c |-- exf_wind |
511 |
|
c | | Computes wind speed and stresses, if required. |
512 |
c | o |
c | o |
513 |
c | |
c | |
514 |
c |-- exf_bulkformulae |
c |-- exf_bulkformulae |
515 |
c | | 1. Compute net or downwelling radiative fluxes via |
c | | Compute air-sea buoyancy fluxes from |
516 |
c | | Stefan-Boltzmann law in case only one is known. |
c | | atmospheric state following Large and Pond, JPO, 1981/82 |
|
c | | 2. Compute air-sea momentum and buoyancy fluxes from |
|
|
c | | atmospheric state following Large and Pond, JPO, 1981/82 |
|
517 |
c | o |
c | o |
518 |
c | |
c | |
519 |
c |-- < add time-mean river runoff here, if available > |
c |-- < hflux is sum of sensible, latent, longwave rad. > |
520 |
|
c |-- < sflux is sum of evap. minus precip. minus runoff > |
521 |
|
c | |
522 |
|
c |-- exf_getsurfacefluxes |
523 |
|
c | If forcing and control is flux, then the |
524 |
|
c | control vector anomalies are read here via ctrl_get_gen |
525 |
|
c | (hflux, sflux, ustress, vstress) |
526 |
c | |
c | |
527 |
c |-- < update tile edges here > |
c |-- < update tile edges here > |
528 |
c | |
c | |
529 |
c |-- exf_getsurfacefluxes |
c |-- exf_check_range |
530 |
c | | 1. If forcing and control are fluxes, then |
c | | Check whether read fields are within assumed range |
531 |
c | | controls are added here. |
c | | (may capture mismatches in units) |
532 |
c | o |
c | o |
533 |
c | |
c | |
534 |
c |-- < treatment of hflux w.r.t. swflux > |
c |-- < add shortwave to hflux for diagnostics > |
535 |
c | |
c | |
536 |
c |-- exf_diagnostics_fill |
c |-- exf_diagnostics_fill |
537 |
c | | 1. Do EXF-related diagnostics output here. |
c | | Do EXF-related diagnostics output here. |
538 |
c | o |
c | o |
539 |
c | |
c | |
540 |
c |-- exf_mapfields |
c |-- exf_mapfields |
541 |
c | | 1. Map the EXF variables onto the core MITgcm |
c | | Forcing fields from exf package are mapped onto |
542 |
c | | forcing fields. |
c | | mitgcm forcing arrays. |
543 |
|
c | | Mapping enables a runtime rescaling of fields |
544 |
c | o |
c | o |
545 |
c | |
C o |
|
c |-- exf_bulkformulae |
|
|
c | If ALLOW_BULKFORMULAE, compute fluxes via bulkformulae |
|
|
c | |
|
|
c |-- exf_getsurfacefluxes |
|
|
c | If forcing and control is flux, then the |
|
|
c | control vector anomalies are read here |
|
|
c | * ctrl_getheatflux |
|
|
c | * ctrl_getsaltflux |
|
|
c | * ctrl_getzonstress |
|
|
c | * call ctrl_getmerstress |
|
|
c | |
|
|
c |-- exf_mapfields |
|
|
c | Forcing fields from exf package are mapped onto |
|
|
c | mitgcm forcing arrays. |
|
|
c | Mapping enables a runtime rescaling of fields |
|
|
|
|
546 |
\end{verbatim} |
\end{verbatim} |
547 |
} |
} |
548 |
|
|
549 |
Bulk formula routine: \texttt{exf\_bulkformulae.F} |
Radiation calculation: \texttt{exf\_radiation.F} |
550 |
|
|
551 |
|
Wind speed and stress calculation: \texttt{exf\_wind.F} |
552 |
|
|
553 |
Generic I/O routine: \texttt{exf\_set\_gen.F} |
Bulk formula: \texttt{exf\_bulkformulae.F} |
554 |
|
|
555 |
Interpolation routine: \texttt{exf\_interp.F} |
Generic I/O: \texttt{exf\_set\_gen.F} |
556 |
|
|
557 |
|
Interpolation: \texttt{exf\_interp.F} |
558 |
|
|
559 |
Header routines |
Header routines |
560 |
|
|
569 |
Table \ref{tab:pkg:exf:diagnostics}. |
Table \ref{tab:pkg:exf:diagnostics}. |
570 |
|
|
571 |
\begin{table}[h!] |
\begin{table}[h!] |
572 |
|
\centering |
573 |
\label{tab:pkg:exf:diagnostics} |
\label{tab:pkg:exf:diagnostics} |
574 |
{\footnotesize |
{\footnotesize |
575 |
\begin{verbatim} |
\begin{verbatim} |
576 |
------------------------------------------------------ |
---------+----+----+----------------+----------------- |
577 |
<-Name->|Levs|grid|<-- Units -->|<- Tile (max=80c) |
<-Name->|Levs|grid|<-- Units -->|<- Tile (max=80c) |
578 |
------------------------------------------------------ |
---------+----+----+----------------+----------------- |
579 |
|
EXFhs | 1 | SM | W/m^2 | Sensible heat flux into ocean, >0 increases theta |
580 |
|
EXFhl | 1 | SM | W/m^2 | Latent heat flux into ocean, >0 increases theta |
581 |
|
EXFlwnet| 1 | SM | W/m^2 | Net upward longwave radiation, >0 decreases theta |
582 |
|
EXFswnet| 1 | SM | W/m^2 | Net upward shortwave radiation, >0 decreases theta |
583 |
EXFlwdn | 1 | SM | W/m^2 | Downward longwave radiation, >0 increases theta |
EXFlwdn | 1 | SM | W/m^2 | Downward longwave radiation, >0 increases theta |
584 |
EXFswdn | 1 | SM | W/m^2 | Downward shortwave radiation, >0 increases theta |
EXFswdn | 1 | SM | W/m^2 | Downward shortwave radiation, >0 increases theta |
585 |
EXFqnet | 1 | SM | W/m^2 | Net upward heat flux (turb+rad), >0 decreases theta |
EXFqnet | 1 | SM | W/m^2 | Net upward heat flux (turb+rad), >0 decreases theta |
587 |
EXFtauy | 1 | SV | N/m^2 | meridional surface wind stress, >0 increases vVel |
EXFtauy | 1 | SV | N/m^2 | meridional surface wind stress, >0 increases vVel |
588 |
EXFuwind| 1 | SM | m/s | zonal 10-m wind speed, >0 increases uVel |
EXFuwind| 1 | SM | m/s | zonal 10-m wind speed, >0 increases uVel |
589 |
EXFvwind| 1 | SM | m/s | meridional 10-m wind speed, >0 increases uVel |
EXFvwind| 1 | SM | m/s | meridional 10-m wind speed, >0 increases uVel |
590 |
|
EXFwspee| 1 | SM | m/s | 10-m wind speed modulus ( >= 0 ) |
591 |
EXFatemp| 1 | SM | degK | surface (2-m) air temperature |
EXFatemp| 1 | SM | degK | surface (2-m) air temperature |
592 |
EXFaqh | 1 | SM | kg/kg | surface (2-m) specific humidity |
EXFaqh | 1 | SM | kg/kg | surface (2-m) specific humidity |
593 |
EXFevap | 1 | SM | m/s | evaporation, > 0 increases salinity |
EXFevap | 1 | SM | m/s | evaporation, > 0 increases salinity |
594 |
EXFpreci| 1 | SM | m/s | evaporation, > 0 decreases salinity |
EXFpreci| 1 | SM | m/s | evaporation, > 0 decreases salinity |
595 |
|
EXFsnow | 1 | SM | m/s | snow precipitation, > 0 decreases salinity |
596 |
EXFempmr| 1 | SM | m/s | net upward freshwater flux, > 0 increases salinity |
EXFempmr| 1 | SM | m/s | net upward freshwater flux, > 0 increases salinity |
597 |
EXFpress| 1 | SM | N/m^2 | atmospheric pressure field |
EXFpress| 1 | SM | N/m^2 | atmospheric pressure field |
598 |
\end{verbatim} |
\end{verbatim} |
602 |
|
|
603 |
%---------------------------------------------------------------------- |
%---------------------------------------------------------------------- |
604 |
|
|
605 |
\subsubsection{Reference experiments} |
\subsubsection{Experiments and tutorials that use exf} |
606 |
|
\label{sec:pkg:exf:experiments} |
|
global\_with\_exf: |
|
607 |
|
|
608 |
lab\_sea: |
\begin{itemize} |
609 |
|
\item{Global Ocean experiment, in global\_with\_exf verification directory } |
610 |
|
\item{Labrador Sea experiment, in lab\_sea verification directory } |
611 |
|
\end{itemize} |
612 |
|
|
613 |
%---------------------------------------------------------------------- |
%---------------------------------------------------------------------- |
614 |
|
|