source: trunk/LMDZ.TITAN/DOC/rcm1d.tex @ 3026

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  • User manual (+ sources) added in DOC.
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1\chapter{1D version of the generic model}
2
3\label{sc:rcm1d}
4
5The physical part of the model can be used to run 1D radiative-convective simulations (one atmospheric column / globally averaged climate). In practice, the simulation is controlled from a main program called \verb+ rcm1d.F+ which, after initialization, then calls the master subroutine of the physics \verb+ physiq.F90+ described in the previous chapters.
6
7\section{Compilation}
8{\bf -} For example, to compile the generic model in 1D with 25 layers, type (in compliance with the makegcm function manual described in section \ref{sc:compil1})
9
10\begin{verbatim}
11makegcm -d 25 -t 1 -b 32x36 -p std rcm1d
12\end{verbatim}
13
14You can find executable {\bf rcm1d.e} (the compiled model)
15in the directory from which you ran the makegcm command.
16
17\section{1-D runs and input files}
18
19The 1D model does not use an initial state file (the simulation must be long enough to obtain a balanced state). Thus, to generate a simulation simply type:
20
21\begin{verbatim}
22> rcm1d.e
23\end{verbatim}
24
25The following example files are available in the {\tt deftank} directory
26(copy them into your working directory first):
27
28- {\bf callphys.def}~: controls the options in the physics,
29  just like for the 3D GCM.
30
31- {\bf z2sig.def}~:
32 controls the vertical discretization
33 (no change needed, in general), functions as with the 3D GCM.
34
35- {\bf traceur.def}~:
36 controls the tracer names (this file may not be present, as long
37 as you run without tracers (option {\tt tracer=.false.} in
38 callphys.def)
39
40- {\bf run.def}~: controls the 1D run parameters and initializations
41(this is actually file {\tt run.def.1d} the {\tt deftank} directory,
42which must be renamed {\tt run.def} to be read by the program).\\
43
44The last file is different from the 3D GCM's {\tt run.def} input file,
45as it contains options specific to the 1D model, as shown in the example
46below:
47\input{input/run.def.1d.tex}
48Note that, just as for the 3D GCM {\tt run.def} file, input
49parameters may be given in any order, or even not given at all
50(in which case default values are used by the program).
51
52
53\section{Output data}
54
55During the entire 1D simulation, you can obtain output data for any
56variable from any physical subroutine by using subroutine \verb+ writeg1d+.
57This subroutine creates file \verb+ g1d.nc+ that can be read by GRADS.
58This subroutine is typically called at the end of subroutine
59\verb+ physiq +. \\
60
61Example of a call to subroutine {\tt writeg1d} requesting
62temperature output:
63(\verb+ ngrid+ horizontal point, \verb+ nlayer + layers, variable
64\verb+ pt + called ``T'' in K units):
65
66\begin{verbatim}
67      CALL writeg1d(ngrid,nlayer,pt,'T','K')
68\end{verbatim}
69
70
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