source: palm/trunk/TUTORIAL/SOURCE/canopy_model.tex @ 1667

Last change on this file since 1667 was 1515, checked in by boeske, 10 years ago

several updates in the tutorial

  • Property svn:keywords set to Id
File size: 28.8 KB
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[1080]1%$Id: canopy_model.tex 1515 2015-01-02 11:35:51Z raasch $
2\input{header_tmp.tex}
3%\input{../header_lectures.tex}
4
5%\documentclass{beamer}
6\usepackage[utf8]{inputenc}
7\usepackage{ngerman}
8\usepackage{pgf}
9\usetheme{Dresden}
10\usepackage{subfigure}
11\usepackage{units}
12\usepackage{amsmath}
13\usepackage{multimedia}
14\newcommand{\event}[1]{\newcommand{\eventname}{#1}}
15\usepackage{xmpmulti}
16\usepackage{tikz}
17\usepackage{pdfcomment}
18\usetikzlibrary{shapes,arrows,positioning,calc,decorations.pathmorphing,decorations.pathreplacing,decorations.markings}
19\def\Tiny{\fontsize{4pt}{4pt}\selectfont}
20\usepackage{listings}
21\lstset{language=[90]Fortran,
22  basicstyle=\ttfamily \tiny,
23  keywordstyle=\color{black},
24  commentstyle=\color{black},
25  morecomment=[l]{!\ }% Comment only with space after !
26}
27
[1515]28
29\institute{Institute of Meteorology and Climatology, Leibniz UniversitÀt Hannover}
30\selectlanguage{english}
[1080]31\date{last update: \today}
32\event{PALM Seminar}
33\setbeamertemplate{navigation symbols}{}
34
35\setbeamertemplate{footline}
36  {%
37    \begin{beamercolorbox}[rightskip=-0.1cm]&
38     {\includegraphics[height=0.65cm]{imuk_logo.pdf}\hfill \includegraphics[height=0.65cm]{luh_logo.pdf}}
39    \end{beamercolorbox}
40    \begin{beamercolorbox}[ht=2.5ex,dp=1.125ex,%
41      leftskip=.3cm,rightskip=0.3cm plus1fil]{title in head/foot}%
42      {\leavevmode{\usebeamerfont{author in head/foot}\insertshortauthor} \hfill \eventname \hfill \insertframenumber \; / \inserttotalframenumber}%
43    \end{beamercolorbox}%
44%    \begin{beamercolorbox}[colsep=1.5pt]{lower separation line foot}%
45%    \end{beamercolorbox}
46  }
47%\logo{\includegraphics[width=0.3\textwidth]{luhimuk_logo.png}}
48
49\title[PALM's Canopy Model]{PALM's Canopy Model}
[1515]50\author{PALM group}
[1080]51
52
53% Notes:
54% jede subsection bekommt einen punkt im menu (vertikal ausgerichtet.
55% jeder frame in einer subsection bekommt einen punkt (horizontal ausgerichtet)
56\begin{document}
57
58\begin{frame}
59\titlepage
60\end{frame}
61
62\section{PALM's Canopy Model}
63\subsection{The embedded Canopy Model}
64
65%Folie 01
66\begin{frame}
67   \frametitle{Overview}
68   \begin{itemize}
[1205]69      \item<1->{The canopy model embedded in PALM can be used to study the effect of a plant canopy on e.g.:}
[1080]70      \begin{itemize}
71         \item<2->{mean flow field,}
72         \item<3->{development of coherent turbulence structures,}
73         \item<4->{scalar exchange processes between canopy and atmosphere.}
74      \end{itemize}
[1515]75      \item<5->{Within the canopy model, the plant canopy acts as a sink for momentum and as a source/sink for active (e.g. temperature) and passive (e.g. tracer) scalars.}
76      \item<6->{The canopy model does not account for each plant element, but rather accounts for a volume averaged effect on the flow and scalar concentration, depending on:}
[1080]77      \begin{itemize}
[1205]78         \item<7->{leaf area density,}
[1515]79         \item<8->{drag coefficient.}
[1080]80      \end{itemize}
81   \end{itemize}
82\end{frame}
83
84
85
86%Folie 02
87\begin{frame}
88   \frametitle{Theory (I)}
89   \begin{footnotesize}
90   \begin{itemize}
91      \item<1->{A plant canopy affects the flow by acting as a momentum sink due to form and viscous drag forces.}
92      \item<2->{The effectiveness of momentum absorption depends on the amount of leaf area per unit volume and the aerodynamic drag.}
[1515]93      \item<3->{Due to the aerodynamic drag, the flow is decelerated within the canopy, leading to an inflection point in the vertical profile of the horizontal velocity at the canopy top.
[1080]94         \begin{center}
95            \includegraphics[width=0.5\textwidth]{canopy_model_figures/abb1.png}
96         \end{center}
97      }
98   \end{itemize}
99   \end{footnotesize}
100\end{frame}
101
102
103
104%Folie 03
105\begin{frame}
106   \frametitle{Theory (II)}
107   \begin{footnotesize}
108   \begin{itemize}
[1205]109      \item<1->{The inflection point in the velocity profile introduces instabilities to the flow, leading to the formation of Kelvin-Helmholtz waves near the canopy top (\textcircled{{\tiny 1}}).}
110      \item<2->{Wave breaking induces further instabilities, whereby a longitudinal component is added to the developing turbulence structures (\textcircled{{\tiny 2}} \& \textcircled{{\tiny 3}}).}
111      \item<3->{Due to the persistent instabilities the turbulence structures develop a distinct three-dimensionality (\textcircled{{\tiny 4}}).}
[1080]112      \item<4->{The large turbulence structures developing due to the inflection point instability significantly contribute to the vertical mixing of in-canopy and above-canopy air.
113         \begin{center}
114            \includegraphics[width=0.5\textwidth]{canopy_model_figures/abb2.png}
115         \end{center}
116      }
117   \end{itemize}
118   \end{footnotesize}
119\end{frame}
120
121
122
123%Folie 04
124\begin{frame}
125   \frametitle{Methods (I)}
126   \begin{footnotesize}
127   \begin{itemize}
128      \item<1->{The canopy model in PALM is based on the models used by Shaw and Schumann (1992) and Watanabe (2004).}
129      \item<2->{The aerodynamic effect of the canopy on the turbulent flow is accounted for by an additional term in the momentum equations:\\
130         \begin{align*}
131            \frac{\partial \bar{u}_{i}}{\partial t} = \text{...} - c_{d} a U \bar{u}_{i}
132         \end{align*}
133      }
134      \begin{itemize}
[1515]135         \item<3->{ $c_{d}$ : drag coefficient}
136         \item<4->{ $a $ : leaf area density $[m^{2}m^{-3}]$}
137         \item<5->{ $U$ : $(u^{2} + v^{2} + w^{2})^{1/2}$ $[m s^{-1}]$}
138         \item<6->{ $u_{i}$ : velocity component ($u_{1}=u$, $u_{2}=v$, $u_{3}=w$)}
[1080]139      \end{itemize}
140   \end{itemize}
[1515]141   \uncover<7->{Note: The canopy model does not resolve the effect of single plant elements.}
[1080]142   \end{footnotesize}
143\end{frame}
144
145
146
147%Folie 05
148\begin{frame}
149   \frametitle{Methods (II)}
150   \begin{footnotesize}
151   \begin{itemize}
[1515]152      \item<1->{The effect of the canopy on the subgrid scale turbulence is accounted for by adding a sink term to the prognostic equation for the subgrid scale turbulent kinetic energy:\\
[1080]153         \begin{align*}
154            \frac{\partial e}{\partial t} = \text{...} - 2 c_{d} a U e
155         \end{align*}
156      }
[1515]157      \item<2->{It is assumed that the subgrid scale turbulent kinetic energy is dissipated by the canopy due to the rapid dissipation of wake turbulence in the lee of canopy elements (e.g. Watanabe, 2004).}
[1080]158   \end{itemize}
159   \end{footnotesize}
160\end{frame}
161
162
163
164%Folie 06
165\begin{frame}
166   \frametitle{Methods (III)}
167   \begin{footnotesize}
168   \begin{itemize}
169      \item<1->{If desired, the effect of the canopy on the sensible heat transport can be considered. A source term is added to the prognostic equation for potential temperature:\\
170         \begin{align*}
171            \frac{\partial \bar{\theta}}{\partial t} = \text{...} +  S_{\theta}
172         \end{align*}
173      }
[1515]174      \item<2->{It is assumed that the foliage is warmed by the penetrating solar radiation and, in turn, warms the surrounding air.}
[1205]175      \item<3->{The source strength $S_{\theta}$ is defined as the vertical derivative of the upward kinematic vertical heat flux $Q_{\theta}$, given by (Shaw and Schumann, 1992):\\
[1080]176         \begin{align*}
177            Q_{\theta}(z) = Q_{\theta}(h) exp(-\alpha F) \text{ , } Q_{\theta}(h) \text{ : Heat flux at canopy top}
178         \end{align*}
179      }
180      \begin{itemize}
181         \item<4->{ $\alpha = 0.6$ (extinction coefficient)}
182         \item<5->{ $F = \int\limits_{z}^{h} a \: dz$ (downward cumulative leaf area index)}
183      \end{itemize}
184   \end{itemize}
185   \end{footnotesize}
186\end{frame}
187
188
189
190%Folie 07
191\begin{frame}
192   \frametitle{Methods (IV)}
193   \begin{footnotesize}
194   \begin{itemize}
195      \item<1->{The canopy might act as a sink or source for other scalars $q$ (e.g. humidity, passive tracer). Therefore, an additional term is added to the scalar transport equation:\\
196         \begin{align*}
197            \frac{\partial \bar{q}}{\partial t} = \text{...} - c_{q} a U (\bar{q} - q_{c})
198         \end{align*}
199      }
200      \begin{itemize}
201         \item<2->{ $c_{q}$ : scalar exchange coefficient}
202         \item<3->{ $q_{c}$ : scalar concentration at leaf surface}
203      \end{itemize}
204   \end{itemize}
205   \end{footnotesize}
206\end{frame}
207
208
209
210%Folie 08
211\begin{frame}
212   \frametitle{Basics (I)}
213   \begin{itemize}
[1515]214      \item<1->{The canopy model is switched on by setting the parameter {\small \texttt{plant\_canopy = .TRUE.}} within the \&inipar {\small \texttt{NAMELIST}} in the parameter file ({\small \texttt{PARIN}}).}
[1080]215      \item<2->{All parameters for steering the canopy model are described in:\\
[1515]216      {\scriptsize Documentation $\rightarrow$ Model steering $\rightarrow$ Parameters $\rightarrow$ Initialization $\rightarrow$ Canopy}\\
[1080]217      (http://palm.muk.uni-hannover.de)
218      }
[1515]219      \item<3->{The following slides will describe how to set up a simulation with a simple horizontally homogeneous canopy block covering the entire model domain surface. In this case, {\small \texttt{canopy\_mode = 'block'}} must be set in \&inipar {\small \texttt{NAMELIST}}.}
[1080]220   \end{itemize}
221\end{frame}
222
223
224
225%Folie 09
226\begin{frame}
[1515]227   \frametitle{Basic canopy parameter (I)}
228   The parameters for steering the canopy model have to be added to the \&inipar {\small \texttt{NAMELIST}} in the parameter file ({\small \texttt{PARIN}}).\\
[1080]229    \begin{itemize}
[1515]230       \item<1->{Step I: Define the upper boundary of the plant canopy layer using the parameter {\small \texttt{pch\_index (grid point index, default 0)}}. {\small \texttt{pch\_index}} specifies the number of grid points resolving the canopy layer in the vertical direction.}
[1080]231    \end{itemize}
232   \vspace{10pt}
233
234   \tikzstyle{background} = [rectangle, fill=gray!10, text width=1\textwidth, text centered, rounded corners, minimum height=10em]
235   \tikzstyle{Key1} = [rectangle, draw, fill=gray!70, text width=0.05, minimum size=0.05, font=\tiny]
236   \tikzstyle{Key2} = [rectangle, draw, fill=green!90, text width=0.05, minimum size=0.05, font=\tiny]
237   \tikzstyle{Key3} = [rectangle, text width=3.0cm, minimum size=16pt, font=\tiny]
238
239\begin{tikzpicture}[>=latex']
240        %%% Edit the following coordinate to change the shape of your
241        %%% cuboid
242
243        %% Vanishing points for perspective handling
244        \coordinate (P1) at (-4cm,1.5cm); % left vanishing point (To pick)
245        \coordinate (P2) at (10cm,1.5cm); % right vanishing point (To pick)
246
247        %% (A1) and (A2) defines the 2 central points of the cuboid
248        \coordinate (A1) at (0cm,0cm); % central top point (To pick)
249        \coordinate (A2) at (0cm,-2cm); % central bottom point (To pick)
250       
251        %% (A3) to (A8) are computed given a unique parameter (or 2) .8
252        % You can vary .8 from 0 to 1 to change perspective on left side
253        \coordinate (A3) at ($(P1)!.8!(A2)$); % To pick for perspective
254        \coordinate (A4) at ($(P1)!.8!(A1)$);
255
256        % You can vary .8 from 0 to 1 to change perspective on right side
257        \coordinate (A7) at ($(P2)!.7!(A2)$);
258        \coordinate (A8) at ($(P2)!.7!(A1)$);
259
260        %% Automatically compute the last 2 points with intersections
261        \coordinate (A5) at
262          (intersection cs: first line={(A8) -- (P1)},
263                            second line={(A4) -- (P2)});
264        \coordinate (A6) at
265          (intersection cs: first line={(A7) -- (P1)},
266                            second line={(A3) -- (P2)});
267
268        %% Drawing the canopy layer
269        \coordinate (A9) at (0em,-1.7cm); % central bottom point (To pick)
270        \coordinate (A10) at ($(P2)!.7!(A9)$);
271        \coordinate (A12) at ($(P1)!.8!(A9)$); % To pick for perspective
272        \coordinate (A11) at
273          (intersection cs: first line={(A10) -- (P1)},
274                            second line={(A12) -- (P2)});
275
276        %%% Depending of what you want to display, you can comment/edit
277        %%% the following lines
278
279        {\node [background, right=-0.8cm of A12] (background) {};}
280
281        %% Possibly draw back faces
282
283        \fill[gray!70] (A2) -- (A3) -- (A6) -- (A7) -- cycle; % face 6
284        \node at (barycentric cs:A2=1,A3=1,A6=1,A7=1) {\tiny };
285       
286        \fill[gray!30] (A3) -- (A4) -- (A5) -- (A6) -- cycle; % face 3
287        \node at (barycentric cs:A3=1,A4=1,A5=1,A6=1) {\tiny };
288       
289        \fill[gray!10] (A5) -- (A6) -- (A7) -- (A8) -- cycle; % face 4
290        \node at (barycentric cs:A5=1,A6=1,A7=1,A8=1) {\tiny };
291       
292       
293        \fill[green!90] (A9) -- (A10) -- (A11) -- (A12) -- cycle; % face 7
294        \node at (barycentric cs:A9=1,A10=1,A11=1,A12=1) {\tiny };
295       
296        \fill[green!100] (A9) -- (A12) -- (A3) -- (A2) -- cycle; % face 8
297        \node at (barycentric cs:A9=1,A12=1,A3=1,A2=1) {\tiny };
298       
299        \fill[green!100] (A9) -- (A10) -- (A7) -- (A2) -- cycle; % face 9
300        \node at (barycentric cs:A9=1,A10=1,A7=1,A2=1) {\tiny };
301       
302        \draw[thin,dashed] (A5) -- (A6);
303        \draw[thin,dashed] (A3) -- (A6);
304        \draw[thin,dashed] (A7) -- (A6);
305
306        \draw[thin,dashed] (A11) -- (A12);
307        \draw[thin,dashed] (A10) -- (A11);
308       
309        %% Possibly draw front faces
310
311        % \fill[orange] (A1) -- (A8) -- (A7) -- (A2) -- cycle; % face 1
312        % \node at (barycentric cs:A1=1,A8=1,A7=1,A2=1) {\tiny f1};
313        \fill[gray!50,opacity=0.2] (A1) -- (A2) -- (A3) -- (A4) -- cycle; % f2
314        \node at (barycentric cs:A1=1,A2=1,A3=1,A4=1) {\tiny };
315        \fill[gray!90,opacity=0.2] (A1) -- (A4) -- (A5) -- (A8) -- cycle; % f5
316        \node at (barycentric cs:A1=1,A4=1,A5=1,A8=1) {\tiny };
317
318        %% Possibly draw front lines
319        \draw[thin] (A1) -- (A2);
320        \draw[thin] (A3) -- (A4);
321        \draw[thin] (A7) -- (A8);
322        \draw[thin] (A1) -- (A4);
323        \draw[thin] (A1) -- (A8);
324        \draw[thin] (A2) -- (A3);
325        \draw[thin] (A2) -- (A7);
326        \draw[thin] (A4) -- (A5);
327        \draw[thin] (A8) -- (A5);
328       
329        \draw[thin] (A9) -- (A10);
330        \draw[thin] (A9) -- (A12);
331       
332        % Possibly draw points
333        % (it can help you understand the cuboid structure)
334        \foreach \i in {1,2,...,12}
335        {
336        %  \draw[fill=black] (A\i) circle (0.05em)
337        %    node[above right] {\tiny \i};
338        }
339        % \draw[fill=black] (P1) circle (0.1em) node[below] {\tiny p1};
340        % \draw[fill=black] (P2) circle (0.1em) node[below] {\tiny p2};
341       
342        %Key   
343        \coordinate (K1) at (0.5cm,-2.3cm);
344        \coordinate (K2) at (0.5cm,-2.7cm);
345       
346       
347        \node [Key1, right=0.0cm of K1] (key1) {};
348        \node [Key2, right=0.0cm of K2] (key2) {};
349        \node [Key3, right=0.4cm of K1] (key11) {Total model domain};
350        \node [Key3, right=0.4cm of K2] (key21) {Plant canopy volume};
351       
352        %% frame specific elements
353        \node [Key3, right=0.45cm of A10] (label1) {\texttt{zw(pch\_index)} = canopy top};
354        \node [Key3, right=0.05cm of A10] (label0) {};
355       
356        \draw[<-] (label0) -- (label1);
357\end{tikzpicture}
358
359
360\end{frame}
361
362
363
364%Folie 10
365\begin{frame}
[1515]366   \frametitle{Basic canopy parameter (II)}
[1080]367    \begin{itemize}
368       \item<1->{ Step II: Construct the vertical profile of the leaf area density (lad) to prescribe the distribution of leaf area within the plant canopy volume.\\
[1515]369       The canopy top is located between {\small \texttt{zu(pch\_index)}} and {\small \texttt{zu(pch\_index + 1)}} because this is the transition between the in-canopy grid point and the above-canopy grid point.
370       }
[1080]371    \end{itemize}
372   \vspace{10pt}
373
374   \tikzstyle{background} = [rectangle, fill=gray!10, text width=1\textwidth, text centered, rounded corners, minimum height=10em]
375   \tikzstyle{Key1} = [rectangle, draw, fill=gray!70, text width=0.05, minimum size=0.05, font=\tiny]
376   \tikzstyle{Key2} = [rectangle, draw, fill=green!90, text width=0.05, minimum size=0.05, font=\tiny]
377   \tikzstyle{Key3} = [rectangle, text width=4.5cm, minimum size=16pt, font=\tiny]
378   \tikzstyle{label} = [rectangle, text width=2.0cm, align=center, minimum size=16pt, font=\tiny]
379
380\begin{tikzpicture}[>=latex']
381        %%% Edit the following coordinate to change the shape of your
382        %%% cuboid
383
384        %% Vanishing points for perspective handling
385        \coordinate (P1) at (-4cm,1.5cm); % left vanishing point (To pick)
386        \coordinate (P2) at (10cm,1.5cm); % right vanishing point (To pick)
387
388        %% (A1) and (A2) defines the 2 central points of the cuboid
389        \coordinate (A1) at (0cm,0cm); % central top point (To pick)
390        \coordinate (A2) at (0cm,-2cm); % central bottom point (To pick)
391       
392        %% (A3) to (A8) are computed given a unique parameter (or 2) .8
393        % You can vary .8 from 0 to 1 to change perspective on left side
394        \coordinate (A3) at ($(P1)!.8!(A2)$); % To pick for perspective
395        \coordinate (A4) at ($(P1)!.8!(A1)$);
396
397        % You can vary .8 from 0 to 1 to change perspective on right side
398        \coordinate (A7) at ($(P2)!.7!(A2)$);
399        \coordinate (A8) at ($(P2)!.7!(A1)$);
400
401        %% Automatically compute the last 2 points with intersections
402        \coordinate (A5) at
403          (intersection cs: first line={(A8) -- (P1)},
404                            second line={(A4) -- (P2)});
405        \coordinate (A6) at
406          (intersection cs: first line={(A7) -- (P1)},
407                            second line={(A3) -- (P2)});
408
409        %% Drawing the canopy layer
410        \coordinate (A9) at (0em,-1.7cm); % central bottom point (To pick)
411        \coordinate (A10) at ($(P2)!.7!(A9)$);
412        \coordinate (A12) at ($(P1)!.8!(A9)$); % To pick for perspective
413        \coordinate (A11) at
414          (intersection cs: first line={(A10) -- (P1)},
415                            second line={(A12) -- (P2)});
416
417        %%% Depending of what you want to display, you can comment/edit
418        %%% the following lines
419
420        {\node [background, right=-0.8cm of A12] (background) {};}
421
422        %% Possibly draw back faces
423
424        \fill[gray!70] (A2) -- (A3) -- (A6) -- (A7) -- cycle; % face 6
425        \node at (barycentric cs:A2=1,A3=1,A6=1,A7=1) {\tiny };
426       
427        \fill[gray!30] (A3) -- (A4) -- (A5) -- (A6) -- cycle; % face 3
428        \node at (barycentric cs:A3=1,A4=1,A5=1,A6=1) {\tiny };
429       
430        \fill[gray!10] (A5) -- (A6) -- (A7) -- (A8) -- cycle; % face 4
431        \node at (barycentric cs:A5=1,A6=1,A7=1,A8=1) {\tiny };
432       
433       
434        \fill[green!90] (A9) -- (A10) -- (A11) -- (A12) -- cycle; % face 7
435        \node at (barycentric cs:A9=1,A10=1,A11=1,A12=1) {\tiny };
436       
437        \fill[green!100] (A9) -- (A12) -- (A3) -- (A2) -- cycle; % face 8
438        \node at (barycentric cs:A9=1,A12=1,A3=1,A2=1) {\tiny };
439       
440        \fill[green!100] (A9) -- (A10) -- (A7) -- (A2) -- cycle; % face 9
441        \node at (barycentric cs:A9=1,A10=1,A7=1,A2=1) {\tiny };
442       
443        \draw[thin,dashed] (A5) -- (A6);
444        \draw[thin,dashed] (A3) -- (A6);
445        \draw[thin,dashed] (A7) -- (A6);
446
447        \draw[thin,dashed] (A11) -- (A12);
448        \draw[thin,dashed] (A10) -- (A11);
449       
450        %% Possibly draw front faces
451
452        % \fill[orange] (A1) -- (A8) -- (A7) -- (A2) -- cycle; % face 1
453        % \node at (barycentric cs:A1=1,A8=1,A7=1,A2=1) {\tiny f1};
454        \fill[gray!50,opacity=0.2] (A1) -- (A2) -- (A3) -- (A4) -- cycle; % f2
455        \node at (barycentric cs:A1=1,A2=1,A3=1,A4=1) {\tiny };
456        \fill[gray!90,opacity=0.2] (A1) -- (A4) -- (A5) -- (A8) -- cycle; % f5
457        \node at (barycentric cs:A1=1,A4=1,A5=1,A8=1) {\tiny };
458
459        %% Possibly draw front lines
460        \draw[thin] (A1) -- (A2);
461        \draw[thin] (A3) -- (A4);
462        \draw[thin] (A7) -- (A8);
463        \draw[thin] (A1) -- (A4);
464        \draw[thin] (A1) -- (A8);
465        \draw[thin] (A2) -- (A3);
466        \draw[thin] (A2) -- (A7);
467        \draw[thin] (A4) -- (A5);
468        \draw[thin] (A8) -- (A5);
469       
470        \draw[thin] (A9) -- (A10);
471        \draw[thin] (A9) -- (A12);
472       
473        % Possibly draw points
474        % (it can help you understand the cuboid structure)
475        \foreach \i in {1,2,...,12}
476        {
477        %  \draw[fill=black] (A\i) circle (0.05em)
478        %    node[above right] {\tiny \i};
479        }
480        % \draw[fill=black] (P1) circle (0.1em) node[below] {\tiny p1};
481        % \draw[fill=black] (P2) circle (0.1em) node[below] {\tiny p2};
482       
483        %Key   
484        \coordinate (K1) at (0.5cm,-2.3cm);
485        \coordinate (K2) at (0.5cm,-2.7cm);
486       
487       
488        \node [Key1, right=0.0cm of K1] (key1) {};
489        \node [Key2, right=0.0cm of K2] (key2) {};
490        \node [Key3, right=0.4cm of K1] (key11) {Total model domain};
491        \node [Key3, right=0.4cm of K2] (key21) {Plant canopy volume};
492       
493        %% frame specific elements
494       
495        %% boundary layer profile 2D
496        \coordinate (B1) at (4.0cm,0.3cm);
497        \coordinate (B2) at (4.0cm,-2.5cm);
498       
499        \coordinate (B3) at (4.0cm,0.6cm);
500        \coordinate (B4) at (6.6cm,-2.5cm);
501       
502        \draw[thin, dotted] (A10) -- (B1);
503        \draw[thin, dotted] (A7) -- (B2);
504        \draw[<-] (B3) -- (B2);
505        \draw[<-] (B4) -- (B2);
506       
507        \coordinate (xlab) at (5.3cm,-2.5cm);
508        \coordinate (ylab) at (4.0cm,-1.1cm);
509        \node [label, below=0.0cm of xlab] (xlabel) {lad $[m^{2}m^{-3}]$};
510        \node [label, rotate=90, above=0.0cm of ylab] (ylabel) {z$[m]$};
511       
512       
513        \coordinate (B5) at (4.5cm,-2.5cm);
514%       \draw [-,color=red] (B1) to [out=-10,in=90,looseness=2.0, relative=false] .. controls (4,0) and (5,0) .. (B5);
515        \draw {(B1) .. controls (8.0,-0.2) and (4.5,-1.0) .. (B5)};
516       
517        \draw [decorate, decoration={markings,
518                mark=at position 00mm with{\draw[fill=black] (0,0) circle (0.1em);},
519                mark=at position 04mm with{\draw[fill=black] (0,0) circle (0.1em);},
520                mark=at position 08mm with{\draw[fill=black] (0,0) circle (0.1em);},
521                mark=at position 12mm with{\draw[fill=black] (0,0) circle (0.1em);},
522                mark=at position 16mm with{\draw[fill=black] (0,0) circle (0.1em);},
523                mark=at position 20mm with{\draw[fill=black] (0,0) circle (0.1em);},
524                mark=at position 24mm with{\draw[fill=black] (0,0) circle (0.1em);},
525                mark=at position 28mm with{\draw[fill=black] (0,0) circle (0.1em);},
526                mark=at position 32mm with{\draw[fill=black] (0,0) circle (0.1em);},
527                mark=at position 36mm with{\draw[fill=black] (0,0) circle (0.1em);},
528                mark=at position 40mm with{\draw[fill=black] (0,0) circle (0.1em);},
529                mark=at position 44mm with{\draw[fill=black] (0,0) circle (0.1em);},
530                }]
531                {(B5) .. controls (4.5,-1.0) and (8.0,-0.2) .. (B1)};
532
533        \node [Key3, right=1.1cm of B1] (label1) {\texttt{zu(pch\_index + 1)}: lad = 0.0 (default)};
534        \node [Key3, left=0.1cm of B1] (label0) {};
535        \draw[-, dashed] (label0) -- (label1);
536       
537        \coordinate (curvelabel00) at (4.65cm,-2.45cm);
538        \coordinate (curvelabel01) at (5.0cm,-2.25cm);
539        \draw[<-] (curvelabel00) -- (curvelabel01);
540        \node [Key3, right=0.0cm of curvelabel01] (curvelabel02) {\texttt{lad\_surface} (default 0.0)};
541       
542        \coordinate (curvelabel10) at (5.4cm,-1.3cm);
543        \coordinate (curvelabel11) at (5.6cm,-1.6cm);
544        \draw[<-] (curvelabel10) -- (curvelabel11);
545        \node [Key3, right=0.0cm of curvelabel11] (curvelabel12) {\texttt{lad\_vertical\_gradient\_level} (5)};
546       
547        \coordinate (curvelabel10) at (5.47cm,-1.05cm);
548        \coordinate (curvelabel11) at (5.8cm,-1.3cm);
549        \draw[<-] (curvelabel10) -- (curvelabel11);
550        \node [Key3, right=0.0cm of curvelabel11] (curvelabel12) {\texttt{lad\_vertical\_gradient} (5)};
551       
552        \coordinate (curvelabel10) at (5.7cm,-0.93cm);
553        \coordinate (curvelabel11) at (5.9cm,-1.0cm);
554        \draw[<-] (curvelabel10) -- (curvelabel11);
555        \node [Key3, right=0.0cm of curvelabel11] (curvelabel12) {\texttt{lad\_vertical\_gradient\_level} (6)};
556\end{tikzpicture}
557
558
559\end{frame}
560
561
562
[1515]563%Folie 11
[1080]564\begin{frame}
[1515]565   \frametitle{Basic canopy parameter (III)}
[1080]566   \begin{footnotesize}
567    \begin{itemize}
[1515]568       \item<1->{Step III: Prescribe a value for the parameter {\small \texttt{drag\_coefficient (default 0.0)}}. The drag coefficient is a dimensionless factor describing the magnitude of the form drag by the canopy working against the flow. A larger form drag results in a greater momentum reduction.}
[1080]569    \end{itemize}
570   
571
572   \begin{minipage}{0.47\textwidth}
573      \begin{center}
574         \includegraphics[width=1\textwidth]{canopy_model_figures/large.png}\\
575      \end{center}
576   \end{minipage}
577   \hfill
578   \begin{minipage}{0.47\textwidth}
579      \begin{center}
580         \includegraphics[width=1\textwidth]{canopy_model_figures/small.png}\\
581      \end{center}
582   \end{minipage}
583   
584   \begin{minipage}{0.47\textwidth}
585      \begin{center}
586         Strong trees offer a larger form drag to the flow.
587      \end{center}
588   \end{minipage}
589   \hfill
590   \begin{minipage}{0.47\textwidth}
591      \begin{center}
592         Young / small trees offer a smaller form drag to the flow because they are more flexible.
593      \end{center}
594   \end{minipage}
595   
596   \end{footnotesize}
597
598\end{frame}
599
600
601
[1515]602%Folie 12
[1080]603\begin{frame}
[1515]604   \frametitle{Basic canopy parameter (IV)}
[1080]605   \begin{itemize}
[1515]606      \item<1->{For steering the effect of the canopy sensible heat transfer, prescribe a value for the sensible heat flux at the canopy top, using the parameter \texttt{cthf} (see Methods (III)).}
607      \item<2->{The sink/source effect of the canopy on other scalar quantities, such as humidity or a passive tracer can be steered by the parameters \texttt{leaf\_surface\_concentration} and \texttt{scalar\_exchange\_coefficient} (see Methods (IV)).}
[1080]608   \end{itemize}
609\end{frame}
610
611
612
[1515]613%Folie 13
[1080]614\begin{frame}
615   \frametitle{User-defined canopy}
616   \begin{footnotesize}
617   Do you want to simulate a more customized canopy, which e.g. covers only half the model surface?\\
618    \begin{itemize}
[1205]619       \item<2->{Step I: Copy the file \texttt{user\_init\_plant\_canopy.f90} from {\small \texttt{trunk/SOURCE}} to the directory {\small \texttt{\$Home/palm/current\_version/USER\_CODE/<enter job name>}} and make the desired changes for {\small \texttt{CASE ('user\_defined\_canopy\_1')}}.}
[1080]620       \item<3->{Step II: In your parameter file set: {\scriptsize \texttt{canopy\_mode = 'user\_defined\_canopy\_1'}}}
621    \end{itemize}
622   \end{footnotesize}
623   \vspace{7pt}
[1205]624
[1080]625   \tikzstyle{background} = [rectangle, fill=gray!10, text width=1\textwidth, text centered, rounded corners, minimum height=10em]
626   \tikzstyle{Key1} = [rectangle, draw, fill=gray!70, text width=0.05, minimum size=0.05, font=\tiny]
627   \tikzstyle{Key2} = [rectangle, draw, fill=green!90, text width=0.05, minimum size=0.05, font=\tiny]
628   \tikzstyle{Key3} = [rectangle, text width=2.0cm, minimum size=4pt, font=\tiny]
629   \tikzstyle{text1} = [rectangle, text width=0.4\textwidth, minimum height=10em]
630\begin{tikzpicture}[>=latex']
631        %%% Edit the following coordinate to change the shape of your
632        %%% cuboid
633     
634        %% Vanishing points for perspective handling
635        \coordinate (P1) at (-4cm,1.5cm); % left vanishing point (To pick)
636        \coordinate (P2) at (10cm,1.5cm); % right vanishing point (To pick)
637
638        %% (A1) and (A2) defines the 2 central points of the cuboid
639        \coordinate (A1) at (0cm,0cm); % central top point (To pick)
640        \coordinate (A2) at (0cm,-2cm); % central bottom point (To pick)
641
642        %% (A3) to (A8) are computed given a unique parameter (or 2) .8
643        % You can vary .8 from 0 to 1 to change perspective on left side
644        \coordinate (A3) at ($(P1)!.8!(A2)$); % To pick for perspective
645        \coordinate (A4) at ($(P1)!.8!(A1)$);
646
647        % You can vary .8 from 0 to 1 to change perspective on right side
648        \coordinate (A7) at ($(P2)!.7!(A2)$);
649        \coordinate (A8) at ($(P2)!.7!(A1)$);
650
651        %% Automatically compute the last 2 points with intersections
652        \coordinate (A5) at
653          (intersection cs: first line={(A8) -- (P1)},
654                            second line={(A4) -- (P2)});
655        \coordinate (A6) at
656          (intersection cs: first line={(A7) -- (P1)},
657                            second line={(A3) -- (P2)});
658
659        %% Drawing the canopy layer
660        \coordinate (A9) at (0em,-1.7cm); % central bottom point (To pick)
661        \coordinate (A10) at ($(P2)!.7!(A9)$);
662        \coordinate (A12) at ($(P1)!.8!(A9)$); % To pick for perspective
663        \coordinate (A11) at
664          (intersection cs: first line={(A10) -- (P1)},
665                            second line={(A12) -- (P2)});
666       
667        \coordinate (A13) at ($(A9)!.54!(A10)$);
668        \coordinate (A14) at ($(A2)!.54!(A7)$);
669       
670        \coordinate (A15) at
671                  (intersection cs: first line={(A13) -- (P1)},
672                                    second line={(A12) -- (P2)});
673        \coordinate (A16) at
674                  (intersection cs: first line={(A14) -- (P1)},
675                                    second line={(A3) -- (P2)});
676        %%% Depending of what you want to display, you can comment/edit
677        %%% the following lines
678       
679        {\node [background, right=-0.8cm of A12] (background) {};}
680
681        %% Possibly draw back faces
682
683        \fill[gray!70] (A2) -- (A3) -- (A6) -- (A7) -- cycle; % face 6
684        \node at (barycentric cs:A2=1,A3=1,A6=1,A7=1) {\tiny };
685       
686        \fill[gray!30] (A3) -- (A4) -- (A5) -- (A6) -- cycle; % face 3
687        \node at (barycentric cs:A3=1,A4=1,A5=1,A6=1) {\tiny };
688       
689        \fill[gray!10] (A5) -- (A6) -- (A7) -- (A8) -- cycle; % face 4
690        \node at (barycentric cs:A5=1,A6=1,A7=1,A8=1) {\tiny };
691       
692       
693        \fill[green!90] (A13) -- (A10) -- (A11) -- (A15) -- cycle; % face 4
694        \node at (barycentric cs:A9=1,A10=1,A11=1,A12=1) {\tiny };
695       
696        \fill[green!100] (A13) -- (A15) -- (A16) -- (A14) -- cycle; % face 4
697        \node at (barycentric cs:A9=1,A12=1,A3=1,A2=1) {\tiny };
698       
699        \fill[green!100] (A13) -- (A10) -- (A7) -- (A14) -- cycle; % face 4
700        \node at (barycentric cs:A9=1,A10=1,A7=1,A2=1) {\tiny };
701       
702        \draw[thin,dashed] (A5) -- (A6);
703        \draw[thin,dashed] (A3) -- (A6);
704        \draw[thin,dashed] (A7) -- (A6);
705
706        \draw[thin,dashed] (A11) -- (A15);
707        \draw[thin,dashed] (A10) -- (A11);
708       
709        %% Possibly draw front faces
710
711        % \fill[orange] (A1) -- (A8) -- (A7) -- (A2) -- cycle; % face 1
712        % \node at (barycentric cs:A1=1,A8=1,A7=1,A2=1) {\tiny f1};
713        \fill[gray!50,opacity=0.2] (A1) -- (A2) -- (A3) -- (A4) -- cycle; % f2
714        \node at (barycentric cs:A1=1,A2=1,A3=1,A4=1) {\tiny };
715        \fill[gray!90,opacity=0.2] (A1) -- (A4) -- (A5) -- (A8) -- cycle; % f5
716        \node at (barycentric cs:A1=1,A4=1,A5=1,A8=1) {\tiny };
717
718        %% Possibly draw front lines
719        \draw[thin] (A1) -- (A2);
720        \draw[thin] (A3) -- (A4);
721        \draw[thin] (A7) -- (A8);
722        \draw[thin] (A1) -- (A4);
723        \draw[thin] (A1) -- (A8);
724        \draw[thin] (A2) -- (A3);
725        \draw[thin] (A2) -- (A7);
726        \draw[thin] (A4) -- (A5);
727        \draw[thin] (A8) -- (A5);
728       
729        \draw[thin] (A13) -- (A10);
730        \draw[thin] (A13) -- (A15);
731        \draw[thin] (A14) -- (A16);
732        \draw[thin] (A13) -- (A14);
733        \draw[thin] (A15) -- (A16);
734       
735        % Possibly draw points
736        % (it can help you understand the cuboid structure)
737        \foreach \i in {1,2,...,16}
738        {
739        %  \draw[fill=black] (A\i) circle (0.05em)
740        %    node[above right] {\tiny \i};
741        }
742        % \draw[fill=black] (P1) circle (0.1em) node[below] {\tiny p1};
743        % \draw[fill=black] (P2) circle (0.1em) node[below] {\tiny p2};
744       
745        %Key   
746        \coordinate (K1) at (0.5cm,-2.3cm);
747        \coordinate (K2) at (0.5cm,-2.7cm);
748       
749       
750        \node [Key1, right=0.0cm of K1] (key1) {};
751        \node [Key2, right=0.0cm of K2] (key2) {};
752        \node [Key3, right=0.4cm of K1] (key11) {Total model domain};
753        \node [Key3, right=0.4cm of K2] (key21) {Plant canopy volume};
754       
755        % % Text
[1515]756        \uncover<4->{\node [text1, right=0.7cm of A7] (text1) {{\footnotesize Note: You might have to make changes in other parts of your {\small \texttt{USER\_CODE}} according to the changes / used parameters in: \texttt{user\_init\_plant\_canopy.f90}}};}
[1080]757\end{tikzpicture}
758
759
760\end{frame}
761
762\end{document}
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