source: trunk/DOC/documentation/dissip_horiz.tex @ 3557

Last change on this file since 3557 was 108, checked in by slebonnois, 14 years ago

Sebastien Lebonnois: sponge layer et dissip horizontale.

File size: 4.3 KB
Line 
1\documentclass[a4paper,10pt]{article}
2%\usepackage{graphicx}
3\usepackage{natbib}  % si appel à bibtex
4%\usepackage[francais]{babel}
5%\usepackage[latin1]{inputenc}  % accents directs (é...), avec babel
6%\usepackage{rotating}
7
8\setlength{\hoffset}{-1.in}
9\setlength{\oddsidemargin}{3.cm}
10\setlength{\textwidth}{15.cm}
11\setlength{\marginparsep}{0.mm}
12\setlength{\marginparwidth}{0.mm}
13
14\setlength{\voffset}{-1.in}
15\setlength{\topmargin}{0.mm}
16\setlength{\headheight}{0.mm}
17\setlength{\headsep}{30.mm}
18\setlength{\textheight}{24.cm}
19\setlength{\footskip}{1.cm}
20
21\setlength{\parindent}{0.mm}
22\setlength{\parskip}{1 em}
23\newcommand{\ten}[1]{$\times 10^{#1}$~} 
24\renewcommand{\baselinestretch}{1.}
25
26\begin{document}
27\pagestyle{plain}
28
29\begin{center}
30{\bf \LARGE 
31Documentation for LMDZ, Planets version
32
33\vspace{1cm}
34\Large
35The horizontal dissipation
36}
37
38\vspace{1cm}
39S\'ebastien Lebonnois
40
41\vspace{1cm}
42Latest version: \today
43\end{center}
44
45\section{Theoretical aspects}
46
47To be written
48
49\section{Pratical aspects in the code}
50
51The horizontal dissipation parameters are chosen in \textsf{gcm.def}.
52
53{\bf Parameters related to the operators}
54
55\begin{itemize}
56\item \textsf{idissip}: timestep for dissipation.
57Should be equal to \textsf{iperiod}.
58\item \textsf{lstardis}: boolean that indicates
59whether to use a star operator (or not). Usually set to {\em True}.
60\item \textsf{nitergdiv}: number of iterations for the {\em gradiv} operator
61\item \textsf{nitergrot}: number of iterations for the {\em nxgradrot} operator
62\item \textsf{niterh}:  number of iterations for the {\em divgrad} operator
63\end{itemize}
64 
65{\bf Parameters related to timescales}
66
67\begin{itemize}
68\item \textsf{tetagdiv}: time scale (in s) for the {\em gradiv} operator.
69It corresponds to the attenuation of the smallest wavelengths for u and v
70perturbations.
71\item \textsf{tetagrot}: time scale (in s) for the {\em nxgradrot} operator.
72It corresponds to the attenuation of the smallest wavelengths for u and v
73perturbations.
74\item \textsf{tetatemp}: time scale (in s) for the {\em divgrad} operator.
75It corresponds to the attenuation of the smallest wavelengths for h
76perturbations.
77\end{itemize}
78These timescales are the one for the deep atmosphere.
79However, they are modified by some factors as the pressure decreases.
80For these factors, two steps are implemented: \textsf{dissip\_fac\_mid} and
81\textsf{dissip\_fac\_up} (also chosen in \textsf{gcm.def}).
82The first step is always applied, the second is
83applied only when \textsf{ok\_strato} is set to {\em True}.
84Timescales are divided by the factor $f$ computed as detailed below.
85
86For \textsf{dissip\_fac\_mid} (which is usually equal to 2.), transition is
87computed with:
88\[
89         x = 1. - \frac{{\rm preff}}{p}
90\]
91\[
92         f_1 = {\rm dissip\_fac\_mid} -
93           \frac{{\rm dissip\_fac\_mid}-1.}{1.+x^2}
94\]
95
96When applied (\textsf{ok\_strato} set to {\em True}), the transition from
97\textsf{dissip\_fac\_mid} to \textsf{dissip\_fac\_up} is done with a
98$\tanh$ function, using further parameters:
99\begin{itemize}
100\item \textsf{dissip\_deltaz}: altitude range (in km) for the transition.
101\item \textsf{dissip\_hdelta}: scale height (in km) at the altitude of the transition.
102\item \textsf{dissip\_pupstart}: pressure (in Pa) corresponding to the bottom
103of the transition region.
104\end{itemize}
105The function used is:
106\[
107         f_2 = \left[ 1+
108     \left( \frac{{\rm dissip\_fac\_up}}{{\rm dissip\_fac\_mid}} - 1. \right)
109     \times \left( 1 - \frac{1 + \tanh X}{2} \right) \right]
110\]
111with
112\[
113    X = \frac{6.\times {\rm dissip\_hdelta}}{{\rm dissip\_deltaz}}
114      \log \frac{p}{{\rm dissip\_pupstart} \times 
115     \exp \left( \frac{-{\rm dissip\_deltaz}}{2 {\rm dissip\_hdelta}} \right)}
116%      = \frac{6.\times {\rm dissip\_hdelta}}{{\rm dissip\_deltaz}}
117%      \log \frac{p}{{\rm dissip\_pupstart}} + 3.
118\]
119
120{\bf A last parameter\dots}
121
122There is one last coefficient in \textsf{gcm.def} related to dissipation:
123\textsf{coefdis}.
124It is used in \textsf{inigeom.F} to compute \textsf{gamdi\_gdiv, gamdi\_grot,
125gamdi\_h}. Usually put to 0... Should be explained here...
126
127
128
129
130%\begin{thebibliography}{2}
131%\providecommand{\natexlab}[1]{#1}
132%\expandafter\ifx\csname urlstyle\endcsname\relax
133%  \providecommand{\doi}[1]{doi:\discretionary{}{}{}#1}\else
134%  \providecommand{\doi}{doi:\discretionary{}{}{}\begingroup
135%  \urlstyle{rm}\Url}\fi
136
137%\end{thebibliography}
138
139\end{document}
Note: See TracBrowser for help on using the repository browser.