Compare commits
4 Commits
tut1-v1.1
...
d898c48619
| Author | SHA1 | Date | |
|---|---|---|---|
| d898c48619 | |||
| 91cf66a544 | |||
| 34769737b0 | |||
| 51718e4749 |
4
.gitignore
vendored
4
.gitignore
vendored
@@ -1,5 +1 @@
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build/
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||||
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src/*/.latexmkrc
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src/*/lib
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src/*/src
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@@ -6,7 +6,6 @@ RUN apt update -y && apt upgrade -y
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RUN apt install make texlive latexmk texlive-pictures -y
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RUN apt install texlive-publishers texlive-science texlive-fonts-extra texlive-latex-extra -y
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RUN apt install biber texlive-bibtex-extra -y
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RUN apt install texlive-lang-german -y
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RUN apt install python3 python3-pygments -y
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24
Makefile
24
Makefile
@@ -1,21 +1,11 @@
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PRESENTATIONS := $(patsubst src/%/presentation.tex,build/presentation_%.pdf,$(wildcard src/*/presentation.tex))
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HANDOUTS := $(patsubst build/presentation_%.pdf,build/presentation_%_handout.pdf,$(PRESENTATIONS))
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all:
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mkdir -p build/build
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.PHONY: all
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all: $(PRESENTATIONS) $(HANDOUTS)
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TEXINPUTS=./lib/cel-slides-template-2025:$$TEXINPUTS latexmk src/template/presentation.tex
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mv build/presentation.pdf build/presentation_template.pdf
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build/presentation_%.pdf: src/%/presentation.tex build/prepared
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TEXINPUTS=./lib/cel-slides-template-2025:$$TEXINPUTS latexmk $<
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mv build/presentation.pdf $@
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build/presentation_%_handout.pdf: src/%/presentation.tex build/prepared
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TEXINPUTS=./lib/cel-slides-template-2025:$$TEXINPUTS latexmk -pdflatex='pdflatex %O "\def\ishandout{1}\input{%S}"' $<
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mv build/presentation.pdf $@
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build/prepared:
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mkdir -p build
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touch build/prepared
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.PHONY: clean
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TEXINPUTS=./lib/cel-slides-template-2025:$$TEXINPUTS latexmk src/2025-11-07/presentation.tex
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mv build/presentation.pdf build/presentation_2025-11-07.pdf
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clean:
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rm -rf build
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18
README.md
18
README.md
@@ -1,18 +0,0 @@
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# WT Tutorial Presentations
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This repository contains the latex source files for the WT Tutorial slides.
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## Build
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### Local Environment
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```bash
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$ make
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```
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### With Docker
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```bash
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$ docker build . -t wt-tut
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$ docker run --rm -u `id -u`:`id -g` -w $PWD -v $PWD:$PWD wt-tut make
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```
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@@ -1,8 +1,4 @@
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\ifdefined\ishandout
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\documentclass[de, handout]{CELbeamer}
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\else
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\documentclass[de]{CELbeamer}
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\fi
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%
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%
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@@ -30,7 +26,8 @@
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\input{lib/latex-common/common.tex}
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\pgfplotsset{colorscheme/rocket}
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\newcommand{\res}{src/2025-11-07/res}
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%TODO: Fix path
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\newcommand{\res}{src/template/res}
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% \tikzstyle{every node}=[font=\small]
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% \captionsetup[sub]{font=small}
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@@ -60,7 +57,7 @@
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\title{WT Tutorium 1}
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\author[Tsouchlos]{Andreas Tsouchlos}
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\date[]{7. November 2025}
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\date[]{\today}
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%
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%
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@@ -74,177 +71,74 @@
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\titlepage
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\end{frame}
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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\section{Struktur des Tutoriums}
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\begin{frame}
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\frametitle{Struktur des Tutoriums}
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\begin{itemize}
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\item Ziele
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\begin{itemize}
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\item Üben/Verstehen der Herangehensweisen Aufgaben zu lösen
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\item Wiederholung der für die Aufgaben wichtigsten Teile
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der Theorie
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\end{itemize}
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\item Struktur der Tutorien
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\begin{table}
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\begin{tabular}{l||c}
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Abschnitt & Dauer \\\hline\hline
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Aufgabe 1: Theorie Wiederholung & $\SI{10}{\minute}$ \\
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Aufgabe 1: Selbstrechenphase & $\SI{20}{\minute}$ \\
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Aufgabe 1: Besprechung der Lösung &
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$\SI{10}{\minute}$ \\\hline
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Aufgabe 2: Theorie Wiederholung & $\SI{10}{\minute}$ \\
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||||
Aufgabe 2: Selbstrechenphase & $\SI{20}{\minute}$ \\
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Aufgabe 2: Besprechung der Lösung &
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$\SI{10}{\minute}$ \\\hline
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Zusammenfassung & $\SI{10}{\minute}$ \\
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\end{tabular}
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\end{table}
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\end{itemize}
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\end{frame}
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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\section{Aufgabe 1}
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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\subsection{Theorie Wiederholung}
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\subsection{Theorie}
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\begin{frame}{Ereignisse \& Laplace}
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\vspace*{-15mm}
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\begin{itemize}
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\item Ereignisse
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\begin{columns}
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\column{\kitthreecolumns}
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\begin{align*}
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\text{Ergebnisraum: } & \hspace{5mm} \Omega =
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\mleft\{ \omega_1, \ldots, \omega_N \mright\}\\
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\text{Ergebnis: } & \hspace{5mm} \omega_i\\
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\text{Ereignis: } & \hspace{5mm} A \subseteq \Omega
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\end{align*}
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\column{\kitthreecolumns}
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\begin{lightgrayhighlightbox}
|
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Beispiel: Würfeln mit einem Würfel
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\begin{align*}
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\Omega &= \mleft\{ 1, \ldots, 6 \mright\}\\
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A &= \mleft\{ 1, 6 \mright\}
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\end{align*}\\[1em]
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\vspace*{-12mm}
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\end{lightgrayhighlightbox}
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\begin{lightgrayhighlightbox}
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Beispiel: Würfeln mit zwei Würfeln
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\begin{align*}
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\Omega &= \mleft\{(i,j): i,j \in \mleft\{
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1,\ldots, 6 \mright\}\mright\} \\
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A &= \mleft\{ (1,1),(2,2), \ldots, (6,6) \mright\}
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\end{align*}
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\vspace*{-12mm}
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\end{lightgrayhighlightbox}
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\vspace*{0mm}
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\end{columns}\pause
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\item Laplace'sches Zufallsexperiment
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% tex-fmt: off
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\begin{gather*}
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\text{Voraussetzungen: }\hspace{5mm} \left\{
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\begin{array}{l}
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\lvert\Omega\rvert \text{ endlich}\\
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P(\omega_i) = \frac{1}{\lvert\Omega\rvert}
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\end{array}
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\right.\\[1em]
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P(A) = \frac{\lvert A \rvert}{\lvert \Omega \rvert} =
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\frac{\text{Anzahl ``günstiger''
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Möglichkeiten}}{\text{Anzahl Möglichkeiten}}
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\end{gather*}
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||||
% tex-fmt: on
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\end{itemize}
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\end{frame}
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% TODO: Replace slide content with relevant stuff
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\begin{frame}
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\frametitle{Relevante Theorie I}
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\begin{frame}{Kombinationen und Hypergeometrische\\ Verteilung}
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\begin{itemize}
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||||
\item Kombinationen: Ziehen ohne zurücklegen, ohne
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Betrachtung der Reihenfolge
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\vspace*{5mm}
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\begin{columns}
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\column{\kitthreecolumns}
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\begin{gather*}
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\lvert C_N^{(K)} \rvert = \binom{N}{K} =
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\frac{N!}{(N-K)!K!}
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\end{gather*}
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\column{\kitthreecolumns}
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||||
\begin{lightgrayhighlightbox}
|
||||
Beispiel: Wie viele mögliche Ergebnisse gibt
|
||||
es beim Lotto ``6 aus 49''?
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\vspace*{0mm}
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\begin{align*}
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\begin{array}{c}
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N = 49 \\
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K = 6
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\end{array} \hspace{5mm} \rightarrow
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\hspace{5mm} \binom{49}{6} = 13983816
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\end{align*}
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\vspace*{-8mm}
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\end{lightgrayhighlightbox}
|
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\end{columns}
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\pause
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\item Hypergeometrische Verteilung
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\begin{columns}
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\column{\kitthreecolumns}
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\begin{gather*}
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P_r = \frac{\binom{R}{r}\binom{N-R}{n-r}}{\binom{N}{n}}
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\end{gather*}
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\column{\kitthreecolumns}
|
||||
\begin{lightgrayhighlightbox}
|
||||
Beispiel: In einer Urne sind N Kugeln, davon
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R rot. Wie groß ist die Wahrscheinlichkeit
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beim ziehen von n Kugeln (ohne Zurücklegen)
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genau r rote zu erwischen?
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||||
\end{lightgrayhighlightbox}
|
||||
\end{columns}
|
||||
\end{itemize}
|
||||
\end{frame}
|
||||
|
||||
\begin{frame}{Zusammenfassung}
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||||
\begin{columns}
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||||
\column{\kitthreecolumns}
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\begin{greenblock}{Laplace'sches Zufallsexperiment}%
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\begin{greenblock}{Zufallsvariablen (ZV)}%
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\vspace*{-6mm}
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\begin{gather*}
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P(A) = \frac{\lvert A \rvert}{\lvert \Omega \rvert} =
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||||
\frac{\text{Anzahl ``günstiger''
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||||
Möglichkeiten}}{\text{Anzahl Möglichkeiten}}
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||||
f_X(x) := \frac{d}{dx} F_X(x) \\
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||||
P(X \le x) = F_X(x) = \int_{-\infty}^{x} f_X(t) dt \\
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||||
E(X) = \int_{-\infty}^{\infty} x\cdot f_X(x) dx
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||||
\end{gather*}
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||||
\end{greenblock}
|
||||
|
||||
\column{\kitthreecolumns}
|
||||
\begin{greenblock}{Kombinationen}%
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||||
\begin{greenblock}{Important Equations}%
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||||
\vspace*{-6mm}
|
||||
\begin{gather*}
|
||||
\lvert C_N^{(K)}\rvert = \binom{N}{K} =
|
||||
\frac{N!}{(N-K)!K!}
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||||
f_X(x) := \frac{d}{dx} F_X(x) \\
|
||||
P(X \le x) = F_X(x) = \int_{-\infty}^{x} f_X(t) dt \\
|
||||
E(X) = \int_{-\infty}^{\infty} x\cdot f_X(x) dx
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||||
\end{gather*}
|
||||
\end{greenblock}
|
||||
\end{columns}
|
||||
|
||||
\begin{greenblock}{Normalverteilung}
|
||||
\begin{columns}
|
||||
\column{\kitonecolumn}
|
||||
\column{\kitthreecolumns}
|
||||
\begin{greenblock}{Hypergeometrische Verteilung}%
|
||||
\vspace*{-6mm}
|
||||
\begin{gather*}
|
||||
P_R = \frac{\binom{R}{r}\binom{N-R}{n-r}}{\binom{N}{n}}
|
||||
\text{Normalverteilung:} \hspace{8mm}
|
||||
f_X(x) = \frac{1}{\sqrt{2\pi\sigma^2}}
|
||||
e^{-\frac{(x - \mu)^2}{2\sigma^2}}
|
||||
\end{gather*}
|
||||
\end{greenblock}
|
||||
\column{\kitonecolumn}
|
||||
|
||||
\column{\kitthreecolumns}
|
||||
\begin{figure}
|
||||
\centering
|
||||
\begin{tikzpicture}
|
||||
\begin{axis}[
|
||||
domain=-4:4,
|
||||
samples=100,
|
||||
width=11cm,
|
||||
height=6cm,
|
||||
ticks=none,
|
||||
xlabel={$x$},
|
||||
ylabel={$f_X(x)$}
|
||||
]
|
||||
\addplot+[mark=none, line width=1pt] {exp(-x^2)};
|
||||
\end{axis}
|
||||
\end{tikzpicture}
|
||||
\end{figure}
|
||||
\end{columns}
|
||||
\end{greenblock}
|
||||
\end{frame}
|
||||
|
||||
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
|
||||
\subsection{Aufgabe}
|
||||
|
||||
% TODO: Replace slide content with relevant stuff
|
||||
\begin{frame}
|
||||
\frametitle{Aufgabe 1: Ergebnisraum \&
|
||||
Hypergeometrische\\ Verteilung}
|
||||
\frametitle{Aufgabe 1: Ergebnisraum \& Hypergeometrische\\ Verteilung}
|
||||
|
||||
Bei einem Kartenspiel erhält ein Spieler 5 Karten aus einem Deck
|
||||
von 52 Karten (bestehend aus
|
||||
@@ -261,180 +155,61 @@
|
||||
|
||||
\end{frame}
|
||||
|
||||
\begin{frame}
|
||||
\frametitle{Aufgabe 1: Ergebnisraum \&
|
||||
Hypergeometrische\\ Verteilung}
|
||||
|
||||
Bei einem Kartenspiel erhält ein Spieler 5 Karten aus einem Deck
|
||||
von 52 Karten (bestehend aus
|
||||
13 Arten mit je 4 Farben). Wie groß ist die Wahrscheinlichkeit,
|
||||
dass der Spieler
|
||||
|
||||
% tex-fmt: off
|
||||
\begin{enumerate}[a{)}]
|
||||
\item mindestens ein Ass hat?\pause
|
||||
\begin{gather*}
|
||||
P(\text{mindestens ein Ass}) = 1 - P(\text{kein Ass})
|
||||
= 1 - \frac{\binom{4}{0}\binom{48}{5}}{\binom{52}{5}} \approx 0.341
|
||||
\end{gather*}\pause\vspace*{-5mm}
|
||||
\item genau ein Ass hat?\pause
|
||||
\begin{gather*}
|
||||
P(\text{genau ein Ass}) = \frac{\binom{4}{1}\binom{48}{4}}{\binom{52}{5}} \approx 0.299
|
||||
\end{gather*}\pause
|
||||
\item mindestens zwei Karten der gleichen Art (“Paar”) hat?\pause
|
||||
\begin{align*}
|
||||
P(\text{mindestens zwei gleiche Karten}) &= 1 - P(\text{alle Karten unterschiedlich}) \\
|
||||
&= 1 - \frac{\text{Anzahl Möglichkeiten mit nur unterschiedlichen Karten}}{\text{Anzahl Möglichkeiten}}\\
|
||||
&= 1 - \frac{\binom{13}{5}\cdot 4^5}{\binom{52}{5}} \approx 0.493
|
||||
\end{align*}
|
||||
\end{enumerate}
|
||||
% tex-fmt: on
|
||||
|
||||
\end{frame}
|
||||
|
||||
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
|
||||
\section{Aufgabe 2}
|
||||
|
||||
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
|
||||
\subsection{Theorie Wiederholung}
|
||||
\subsection{Theorie}
|
||||
|
||||
% TODO: Replace slide content with relevant stuff
|
||||
\begin{frame}
|
||||
\frametitle{Kombinatorik}
|
||||
\frametitle{Relevante Theorie II}
|
||||
|
||||
\vspace*{-18mm}
|
||||
|
||||
\begin{itemize}
|
||||
\item Potenzmenge
|
||||
\vspace*{-2mm}
|
||||
\begin{columns}
|
||||
\column{\kitfourcolumns}
|
||||
\begin{align*}
|
||||
\mathcal{P}\mleft( \Omega \mright) = \mleft\{ A:
|
||||
A \subseteq \Omega \mright\} \hspace{10mm}
|
||||
\left(\text{``Menge aller
|
||||
Teilmengen von $\Omega$''}\right)
|
||||
\end{align*}
|
||||
\column{\kittwocolumns}
|
||||
\begin{lightgrayhighlightbox}
|
||||
Beispiel
|
||||
\begin{gather*}
|
||||
\Omega = \{ A, B, C \}
|
||||
\end{gather*}%
|
||||
\vspace*{-15mm}%
|
||||
\begin{align*}
|
||||
\mathcal{P}(\Omega) = \{ &\emptyset,
|
||||
\mleft\{ A \mright\}, \mleft\{ B \mright\},
|
||||
\mleft\{ C \mright\}, \mleft\{ A, B \mright\},\\
|
||||
&\mleft\{ A, C \mright\},
|
||||
\mleft\{ B, C \mright\}, \mleft\{ A, B, C
|
||||
\mright\} \}
|
||||
\end{align*}%
|
||||
\vspace*{-14mm}%
|
||||
\end{lightgrayhighlightbox}
|
||||
\end{columns}
|
||||
\vspace*{-3mm}
|
||||
\item \pause Variationen und Kombinationen
|
||||
\setlength\extrarowheight{2mm}
|
||||
\begin{table}
|
||||
\begin{tabular}{r||l|l}
|
||||
& Mit Zurücklegen & Ohne Zurücklegen
|
||||
\\\hline\hline Mit Reihenfolge
|
||||
(\textit{Variationen}) & $\lvert
|
||||
\widetilde{V}_N^{(K)} \rvert = N^K$ & $\lvert
|
||||
V_N^{(K)}\rvert = \frac{N!}{(N-K)!} $ \\\hline
|
||||
Ohne Reihenfolge (\textit{Kombinationen}) &
|
||||
$\lvert \widetilde{C}_N^{(K)} \rvert =
|
||||
\binom{N+K-1}{K} $ & $\lvert C_N^{(K)} \rvert
|
||||
= \binom{N}{K} $
|
||||
\end{tabular}
|
||||
\end{table}
|
||||
\item \pause Permutationen
|
||||
\begin{columns}
|
||||
\column{\kitfourcolumns}
|
||||
\begin{gather*}
|
||||
\Pi_N = \mleft\{ \mleft( a_1, \ldots, a_N
|
||||
\mright) \in \Omega : a_i \neq a_j, i \neq j
|
||||
\mright\}\\
|
||||
\begin{array}{r}
|
||||
\text{Alle Elemente von $\Omega$ unterscheidbar:} \\
|
||||
\text{Jeweils $L_1, L_2, \ldots, L_M$ der Elemente
|
||||
sind gleich:}
|
||||
\end{array}
|
||||
\hspace{5mm}
|
||||
\begin{array}{rl}
|
||||
\lvert \Pi_N \rvert &= N! \\
|
||||
\lvert \Pi_N^{(L_1,
|
||||
L_2, \ldots, L_M)} \rvert &=
|
||||
\frac{N!}{L_1!L_2!\cdots L_M!}
|
||||
\end{array}
|
||||
f_X(x) := \frac{d}{dx} F_X(x) \\
|
||||
P(X \le x) = F_X(x) = \int_{-\infty}^{x} f_X(t) dt \\
|
||||
E(X) = \int_{-\infty}^{\infty} x\cdot f_X(x) dx
|
||||
\end{gather*}
|
||||
\column{\kittwocolumns}
|
||||
\begin{lightgrayhighlightbox}
|
||||
Beispiel:
|
||||
\begin{gather*}
|
||||
\Omega = {A, B, C}\\
|
||||
\Pi_N = \{ (A,B,C), (A,C,B), (B,A,C),\\
|
||||
(B,C,A), (C,A,B), (C,B,A)\}
|
||||
\end{gather*}
|
||||
\vspace*{-14mm}%
|
||||
\end{lightgrayhighlightbox}
|
||||
\end{columns}
|
||||
\end{itemize}
|
||||
\end{frame}
|
||||
|
||||
\begin{frame}
|
||||
\frametitle{Zusammenfassung}
|
||||
\begin{figure}
|
||||
\centering
|
||||
|
||||
\begin{columns}
|
||||
\column{\kitthreecolumns}
|
||||
\begin{greenblock}{Potenzmenge}
|
||||
\vspace*{-6mm}
|
||||
\begin{subfigure}[c]{0.5\textwidth}
|
||||
\centering
|
||||
\begin{gather*}
|
||||
\mathcal{P}\mleft( \Omega \mright) = \mleft\{ A:
|
||||
A \subseteq \Omega \mright\}
|
||||
\text{Normalverteilung:} \hspace{8mm}
|
||||
f_X(x) = \frac{1}{\sqrt{2\pi\sigma^2}}
|
||||
e^{-\frac{(x - \mu)^2}{2\sigma^2}}
|
||||
\end{gather*}
|
||||
\end{greenblock}
|
||||
\column{\kitthreecolumns}
|
||||
\begin{greenblock}{Permutationen}
|
||||
\vspace*{-6mm}
|
||||
\begin{align*}
|
||||
\lvert \Pi_N \rvert &= N! \\
|
||||
\lvert \Pi_N^{(L_1, L_2, \ldots, L_M)} \rvert &=
|
||||
\frac{N!}{L_1!L_2!\cdots L_M!}
|
||||
\end{align*}
|
||||
\end{greenblock}
|
||||
\end{columns}
|
||||
\begin{columns}
|
||||
\column{\kitonecolumn}
|
||||
\column{\kitfourcolumns}
|
||||
\begin{greenblock}{Variationen \& Kombinationen }
|
||||
\begin{table}
|
||||
\begin{tabular}{r||l|l}
|
||||
& Mit Zurücklegen & Ohne Zurücklegen
|
||||
\\\hline\hline Mit Reihenfolge
|
||||
(\textit{Variationen}) & $\lvert
|
||||
\widetilde{V}_N^{(K)} \rvert = N^K$ & $\lvert
|
||||
V_N^{(K)}\rvert = \frac{N!}{(N-K)!} $ \\\hline
|
||||
Ohne Reihenfolge (\textit{Kombinationen}) &
|
||||
$\lvert \widetilde{C}_N^{(K)} \rvert =
|
||||
\binom{N+K-1}{K} $ & $\lvert C_N^{(K)} \rvert
|
||||
= \binom{N}{K} $
|
||||
\end{tabular}
|
||||
\end{table}
|
||||
\end{greenblock}
|
||||
\column{\kitonecolumn}
|
||||
\end{columns}
|
||||
\end{subfigure}%
|
||||
\begin{subfigure}[c]{0.4\textwidth}
|
||||
\centering
|
||||
\begin{tikzpicture}
|
||||
\begin{axis}[
|
||||
domain=-4:4,
|
||||
samples=100,
|
||||
width=\textwidth,
|
||||
height=0.5\textwidth,
|
||||
ticks=none,
|
||||
xlabel={$x$},
|
||||
ylabel={$f_X(x)$}
|
||||
]
|
||||
\addplot+[mark=none, line width=1pt] {exp(-x^2)};
|
||||
\end{axis}
|
||||
\end{tikzpicture}
|
||||
\end{subfigure}
|
||||
\end{figure}
|
||||
\end{frame}
|
||||
|
||||
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
|
||||
\subsection{Aufgabe}
|
||||
|
||||
% TODO: Replace slide content with relevant stuff
|
||||
\begin{frame}
|
||||
\frametitle{Aufgabe 2: Variationen \& Permutationen}
|
||||
|
||||
Aufgabe 2: Variationen \& Permutationen
|
||||
Ein Burgerrestaurant bietet verschiedene Burger mit den
|
||||
Zutaten Salat
|
||||
Ein Burgerrestaurant bietet verschiedene Burger mit den Zutaten Salat
|
||||
(S), Käse (K), Tomate (T)
|
||||
und Patty (P) an. Diese werden zufällig für die Zubereitung eines
|
||||
Burgers ausgewählt.
|
||||
@@ -460,66 +235,48 @@
|
||||
|
||||
\end{frame}
|
||||
|
||||
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
|
||||
\section{Zusammenfassung}
|
||||
|
||||
% TODO: Replace slide content with relevant stuff
|
||||
\begin{frame}
|
||||
\frametitle{Aufgabe 2: Variationen \& Permutationen}
|
||||
\frametitle{Zusammenfassung}
|
||||
|
||||
Aufgabe 2: Variationen \& Permutationen
|
||||
Ein Burgerrestaurant bietet verschiedene Burger mit den
|
||||
Zutaten Salat
|
||||
(S), Käse (K), Tomate (T)
|
||||
und Patty (P) an. Diese werden zufällig für die Zubereitung eines
|
||||
Burgers ausgewählt.
|
||||
|
||||
% tex-fmt: off
|
||||
\begin{enumerate}[a{)}]
|
||||
\item Die Ergebnismenge sei $\Omega = \{S, K, T, P\}$. Wie lautet die
|
||||
Potenzmenge $P(\Omega)$?\pause
|
||||
\begin{align*}
|
||||
\mathcal{P}(\Omega) = \{ &\emptyset, \mleft\{ S \mright\}, \mleft\{ K \mright\}, \mleft\{ T \mright\}, \mleft\{ P \mright\},\\
|
||||
&\mleft\{ S, K \mright\}, \mleft\{ S, T \mright\}, \mleft\{ S, P \mright\}, \mleft\{ K, T \mright\}, \mleft\{ K,P \mright\}, \mleft\{ T, P \mright\}, \\
|
||||
&\mleft\{ S, K, T \mright\}, \mleft\{ S, K, P \mright\}, \mleft\{ S, T, P \mright\}, \mleft\{ K, T, P \mright\}, \mleft\{ S, K, T, P \mright\}\}
|
||||
\end{align*}%
|
||||
\item \pause Für einen normalen Burger werden 3 der 4 möglichen Zutaten
|
||||
ausgewählt und in einer
|
||||
bestimmten Reihenfolge auf das Burgerbrötchen gelegt. Wie viele
|
||||
verschiedene normale
|
||||
Burger gibt es?\pause
|
||||
\begin{gather*}
|
||||
\lvert V_N^{(K)} \rvert = \frac{4!}{1!} = 24
|
||||
f_X(x) := \frac{d}{dx} F_X(x) \\
|
||||
P(X \le x) = F_X(x) = \int_{-\infty}^{x} f_X(t) dt \\
|
||||
E(X) = \int_{-\infty}^{\infty} x\cdot f_X(x) dx
|
||||
\end{gather*}
|
||||
\end{enumerate}
|
||||
% tex-fmt: on
|
||||
\end{frame}
|
||||
|
||||
\begin{frame}
|
||||
\frametitle{Aufgabe 2: Variationen \& Permutationen}
|
||||
\begin{figure}
|
||||
\centering
|
||||
|
||||
Aufgabe 2: Variationen \& Permutationen
|
||||
Ein Burgerrestaurant bietet verschiedene Burger mit den
|
||||
Zutaten Salat
|
||||
(S), Käse (K), Tomate (T)
|
||||
und Patty (P) an. Diese werden zufällig für die Zubereitung eines
|
||||
Burgers ausgewählt.
|
||||
|
||||
% tex-fmt: off
|
||||
\begin{enumerate}[a{)}]
|
||||
\setcounter{enumi}{2}
|
||||
\item Ein Burger ``Spezial'' besteht ebenfalls aus 3 Zutaten. Jedoch
|
||||
können Tomate und Salat
|
||||
doppelt vorkommen. Wie viele verschiedene Burger „Spezial“ gibt es?\pause
|
||||
\begin{align*}
|
||||
n_\text{Burger} &= n_\text{Burger,alle Unterschiedlich} + n_{\text{Burger,2}\times\text{Salat}} + n_{\text{Burger,2}\times\text{Tomate}} \\
|
||||
&= 24 + 3\cdot 3 + 3\cdot 3 = 42
|
||||
\end{align*}
|
||||
\item \pause Der Burger „Jumbo“ enthält die folgende Menge an Zutaten: $\{S, S,
|
||||
T, T, K, K, K, P, P, P\}$
|
||||
die alle verwendet werden. Wie viele mögliche Belegungen des Burgers
|
||||
``Jumbo'' gibt es?\pause
|
||||
\begin{subfigure}[c]{0.5\textwidth}
|
||||
\centering
|
||||
\begin{gather*}
|
||||
\lvert \Pi_N^{L_1,L_2,L_3,L_4} \rvert = \frac{10!}{2!2!3!3!} = 25200
|
||||
\text{Normalverteilung:} \hspace{8mm}
|
||||
f_X(x) = \frac{1}{\sqrt{2\pi\sigma^2}}
|
||||
e^{-\frac{(x - \mu)^2}{2\sigma^2}}
|
||||
\end{gather*}
|
||||
\end{enumerate}
|
||||
% tex-fmt: on
|
||||
\end{subfigure}%
|
||||
\begin{subfigure}[c]{0.4\textwidth}
|
||||
\centering
|
||||
\begin{tikzpicture}
|
||||
\begin{axis}[
|
||||
domain=-4:4,
|
||||
samples=100,
|
||||
width=\textwidth,
|
||||
height=0.5\textwidth,
|
||||
ticks=none,
|
||||
xlabel={$x$},
|
||||
ylabel={$f_X(x)$}
|
||||
]
|
||||
\addplot+[mark=none, line width=1pt] {exp(-x^2)};
|
||||
\end{axis}
|
||||
\end{tikzpicture}
|
||||
\end{subfigure}
|
||||
\end{figure}
|
||||
\end{frame}
|
||||
|
||||
\end{document}
|
||||
|
||||
|
||||
3
src/template/.latexmkrc
Normal file
3
src/template/.latexmkrc
Normal file
@@ -0,0 +1,3 @@
|
||||
$pdflatex="pdflatex -shell-escape -interaction=nonstopmode -synctex=1 %O %S -cd ./../..";
|
||||
$out_dir = "build";
|
||||
$pdf_mode = 1;
|
||||
1
src/template/lib
Symbolic link
1
src/template/lib
Symbolic link
@@ -0,0 +1 @@
|
||||
/home/andreas/Documents/kit/wt-tut/presentations/lib
|
||||
@@ -1,8 +1,4 @@
|
||||
\ifdefined\ishandout
|
||||
\documentclass[de, handout]{CELbeamer}
|
||||
\else
|
||||
\documentclass[de]{CELbeamer}
|
||||
\fi
|
||||
|
||||
%
|
||||
%
|
||||
|
||||
1
src/template/src
Symbolic link
1
src/template/src
Symbolic link
@@ -0,0 +1 @@
|
||||
/home/andreas/Documents/kit/wt-tut/presentations/src
|
||||
Reference in New Issue
Block a user