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9 Commits
tut3-v1.3 ... tut4-v1.1

Author SHA1 Message Date
Andreas Tsouchlos
088d448e50 Put numbers in tables in math mode 2025-12-17 15:21:49 +01:00
Andreas Tsouchlos
b815a88361 Replace Z with X for the standart normal distribution 2025-12-17 15:16:56 +01:00
Andreas Tsouchlos
7bea062e6a Fix spacing 2025-12-17 01:09:56 +01:00
Andreas Tsouchlos
5bf78e09e1 Add theory for part 2 2025-12-17 01:03:47 +01:00
Andreas Tsouchlos
aae0aae77b Finish theory for part 1 2025-12-16 23:13:53 +01:00
Andreas Tsouchlos
c0992e9690 Continue adding stuff 2025-12-16 17:42:26 +01:00
Andreas Tsouchlos
6942d2386e Add pauses; Fix decimal point -> decimal comma 2025-12-16 17:07:34 +01:00
Andreas Tsouchlos
4e39722899 tut4: Add some formulas for theory on part 2; Add TODOs 2025-12-16 00:46:14 +01:00
Andreas Tsouchlos
f0c22852be tut4: Started adding theory for exercise 1 2025-12-16 00:18:12 +01:00
1 changed files with 328 additions and 22 deletions
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src/2025-12-19/presentation.tex
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@@ -81,7 +81,118 @@
\subsection{Theorie Wiederholung} \subsection{Theorie Wiederholung}
\begin{frame} \begin{frame}
\frametitle{sasdf} \frametitle{Stetige Zufallsvariablen I}
\vspace*{-10mm}
\begin{lightgrayhighlightbox}
Erinnerung: Diskrete Zufallsvariablen
\begin{align*}
\text{\normalfont Verteilung: }& P_X(x) = P(X = x) \\
\text{\normalfont Verteilungsfunktion: }& F_X(x) = P(X \le x) =
\sum_{n: x_n \le y} P_X(x)
\end{align*}
\vspace{-10mm}
\end{lightgrayhighlightbox}
\begin{columns}[t]
\pause\column{\kitthreecolumns}
\centering
\begin{itemize}
\item Verteilungsfunktion $F_X(x)$ einer stetiger ZV
\begin{gather*}
F_X(x) = P(X \le x)
\end{gather*}
\end{itemize}
\pause\column{\kitthreecolumns}
\centering
\begin{itemize}
\item Wahrscheinlichkeitsdichte $f_X(x)$ einer stetiger ZV
\begin{gather*}
F_X(x) = \int_{-\infty}^{x} f_X(u) du
\end{gather*}
\end{itemize}
\end{columns}
\begin{columns}[t]
\pause \column{\kitthreecolumns}
\centering
\begin{gather*}
\text{Eigenschaften:} \\[3mm]
\lim_{x\rightarrow -\infty} F_X(x) = 0 \\
\lim_{x\rightarrow +\infty} F_X(x) = 1 \\
x_1 \le x_2 \Rightarrow F_X(x_1) \le F_X(x_2)\\
F_X(x+) = \lim_{h\rightarrow 0^+} F_X (x+h) = F_X(x)
\end{gather*}
\pause \column{\kitthreecolumns}
\centering
\begin{gather*}
\text{Eigenschaften:} \\[3mm]
f_X(x) \ge 0 \\
\int_{-\infty}^{\infty} f_X(x) dx = 1
\end{gather*}
\end{columns}
\end{frame}
\begin{frame}
\frametitle{Stetige Zufallsvariablen II}
\begin{minipage}{0.6\textwidth}
\begin{itemize}
\item Wichtige Kenngrößen
\begin{align*}
\begin{array}{rlr}
\text{Erwartungswert: } \hspace{5mm} & E(X) =
\displaystyle\int_{-\infty}^{\infty} x f_X(x) dx
& \hspace{5mm} \big( = \mu \big) \\[3mm]
\text{Varianz: } \hspace{5mm} & V(X) = E\mleft(
\mleft( X - E(X) \mright)^2 \mright) \\[3mm]
\text{Standardabweichung: } \hspace{5mm} &
\sqrt{V(X)} & \hspace{5mm} \big( = \sigma \big)
\end{array}
\end{align*}
\end{itemize}
\end{minipage}
\begin{minipage}{0.38\textwidth}
\begin{lightgrayhighlightbox}
Erinnerung
\begin{align*}
\text{\normalfont Erwartungswert: }& E(X) =
\sum_{n=1}^{\infty} x_n P_X(x) \\
\text{\normalfont Varianz: }& V(X) = E\mleft( \mleft(
X - E(X) \mright)^2 \mright)
\end{align*}
\end{lightgrayhighlightbox}
\end{minipage}
\end{frame}
\begin{frame}
\frametitle{Zusammenfassung}
\begin{columns}[t]
\column{\kitthreecolumns}
\centering
\begin{greenblock}{Verteilungsfunktion (kontinuierlich)}
\vspace*{-6mm}
\begin{gather*}
F_X(x) = P(X \le x)\\[4mm]
P(a < X \le b) = F_X(b) - F_X(a) \\[8mm]
\lim_{x\rightarrow -\infty} F_X(x) = 0 \\
\lim_{x\rightarrow +\infty} F_X(x) = 1 \\
x_1 \le x_2 \Rightarrow F_X(x_1) \le F_X(x_2)\\
F_X(x+) = \lim_{h\rightarrow 0^+} F_X (x+h) = F_X(x)
\end{gather*}
\end{greenblock}
\column{\kitthreecolumns}
\centering
\begin{greenblock}{Wahrscheinlichkeitsdichte \phantom{()}}
\vspace*{-6mm}
\begin{gather*}
F_X(x) = \int_{-\infty}^{x} f_X(u) du \\[5mm]
f_X(x) \ge 0 \\
\int_{-\infty}^{\infty} f_X(x) dx = 1
\end{gather*}
\end{greenblock}
\end{columns}
\end{frame} \end{frame}
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
@@ -220,7 +331,6 @@
\begin{gather*} \begin{gather*}
x_1 \le x_2 \Rightarrow F_X(x_1) \le F_X(x_2) \\ x_1 \le x_2 \Rightarrow F_X(x_1) \le F_X(x_2) \\
F_X(x+) = \lim_{h\rightarrow 0^+} F_X (x+h) = F_X(x) F_X(x+) = \lim_{h\rightarrow 0^+} F_X (x+h) = F_X(x)
\hspace{5mm}\forall x\in \mathbb{R}
\end{gather*} \end{gather*}
\column{\kitonecolumn} \column{\kitonecolumn}
\end{columns} \end{columns}
@@ -267,7 +377,7 @@
= P(1 < X \le 2) = F_X(2) - F_X(1) = e^{-a} - e^{-4a} = P(1 < X \le 2) = F_X(2) - F_X(1) = e^{-a} - e^{-4a}
\end{gather*} \end{gather*}
\end{enumerate} \end{enumerate}
% tex-fmt: off % tex-fmt: on
\end{frame} \end{frame}
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
@@ -277,7 +387,203 @@
\subsection{Theorie Wiederholung} \subsection{Theorie Wiederholung}
\begin{frame} \begin{frame}
\frametitle{sasdf} \frametitle{Die Normalverteilung}
\begin{columns}
\column{\kitthreecolumns}
\centering
\begin{gather*}
X \sim \mathcal{N}\mleft( \mu, \sigma^2 \mright)
\end{gather*}%
\vspace{0mm}
\begin{align*}
f_X(x) &= \frac{1}{\sqrt{2\pi \sigma^2}} \exp\left(\frac{(x -
\mu)^2}{2 \sigma^2} \right) \\[2mm]
F_X(x) &=
\vcenter{\hbox{\scalebox{1.5}[2.6]{\vspace*{3mm}$\displaystyle\int$}}}_{\hspace{-0.5em}-\infty}^{\,x}
\frac{1}{\sqrt{2\pi
\sigma^2}} \exp\left(\frac{(u - \mu)^2}{2 \sigma^2} \right) du
\end{align*}
\column{\kitthreecolumns}
\centering
\begin{figure}[H]
\centering
\begin{tikzpicture}
\begin{axis}[
domain=-4:4,
xmin=-4,xmax=4,
width=15cm,
height=5cm,
samples=200,
xlabel={$x$},
ylabel={$f_X(x)$},
xtick={0},
xticklabels={\textcolor{KITblue}{$\mu$}},
ytick={0},
]
\addplot+[mark=none, line width=1pt]
{(1 / sqrt(2*pi)) * exp(-x*x)};
\addplot+ [KITblue, mark=none, line width=1pt]
coordinates {(-0.5, 0.15) (0.5, 0.15)};
\addplot+ [KITblue, mark=none, line width=1pt]
coordinates {(-0.5, 0.12) (-0.5, 0.18)};
\addplot+ [KITblue, mark=none, line width=1pt]
coordinates {(0.5, 0.12) (0.5, 0.18)};
\node[KITblue] at (axis cs: 0, 0.2) {$\sigma$};
% \addplot +[scol2, mark=none, line width=1pt]
% coordinates {(4.8, -1) (4.8, 2)};
% \addplot +[scol2, mark=none, line width=1pt]
% coordinates {(5.2, -1) (5.2, 2)};
% \node at (axis cs: 4.8, 3) {$S(1-\delta)$};
% \node at (axis cs: 5.2, 3) {$S(1+\delta)$};
\end{axis}
\end{tikzpicture}
\end{figure}
\begin{figure}[H]
\centering
\begin{tikzpicture}
\begin{axis}[
domain=-4:4,
xmin=-4,xmax=4,
width=15cm,
height=5cm,
samples=200,
xlabel={$x$},
ylabel={$F_X(x)$},
xtick=\empty,
ytick={0, 1},
]
\addplot+[mark=none, line width=1pt]
{1 / (1 + exp(-(1.526*x*(1 + 0.1034*x))))};
\end{axis}
\end{tikzpicture}
\end{figure}
\end{columns}
\end{frame}
\begin{frame}
\frametitle{Rechnen mithilfe der Standardnormalverteilung}
\vspace*{-15mm}
\begin{itemize}
\item Die Standardnormalverteilung
\end{itemize}
\begin{minipage}{0.48\textwidth}
\centering
\begin{gather*}
X \sim \mathcal{N} (0,1) \\[4mm]
\Phi(x) := F_X(x) = P(X \le x) \\
\Phi(-x) = 1 - \Phi(x)
\end{gather*}
\end{minipage}%
\begin{minipage}{0.48\textwidth}
\centering
\begin{tabular}{|c|c||c|c||c|c|}
\hline
$x$ & $\Phi(x)$ & $x$ & $\Phi(x)$ & $x$ & $\Phi(x)$ \\
\hline
\hline
$0{,}00$ & $0{,}500000$ & $0{,}10$ & $0{,}539828$ &
$0{,}20$ & $0{,}579260$ \\
$0{,}02$ & $0{,}507978$ & $0{,}12$ & $0{,}547758$ &
$0{,}22$ & $0{,}587064$ \\
$0{,}04$ & $0{,}515953$ & $0{,}14$ & $0{,}555670$ &
$0{,}24$ & $0{,}594835$ \\
$0{,}06$ & $0{,}523922$ & $0{,}16$ & $0{,}563559$ &
$0{,}26$ & $0{,}602568$ \\
$0{,}08$ & $0{,}531881$ & $0{,}18$ & $0{,}571424$ &
$0{,}28$ & $0{,}610261$ \\
\hline
\end{tabular}\\
\end{minipage}
\pause
\begin{itemize}
\item Standardisierte ZV
\begin{gather*}
\begin{array}{cc}
E(X) &= 0 \\
V(X) &= 1
\end{array}
\hspace{45mm}
\text{Standardisierung: } \hspace{5mm}
\widetilde{X} = \frac{X - E(X)}{\sqrt{V(X)}}
= \frac{X - \mu}{\sigma}
\end{gather*}
\end{itemize}
\vspace*{3mm}
\pause
\begin{lightgrayhighlightbox}
Rechenbeispiel
\begin{gather*}
X \sim \mathcal{N}(\mu = 1, \sigma^2 = 0{,}5^2) \\[2mm]
P\left(X \le 1{,}12 \right)
= P\left(\frac{X - 1}{0{,}5} \le \frac{1{,}12 - 1}{0{,}5}\right)
= P\big(\underbrace{\widetilde{X}}_{\sim
\mathcal{N}(0,1)} \le 0{,}24\big)
= \Phi\left(0{,}24\right) = 0{,}594835
\end{gather*}
\end{lightgrayhighlightbox}
\end{frame}
\begin{frame}
\frametitle{Zusammenfassung}
\vspace*{-15mm}
\begin{columns}[t]
\column{\kitthreecolumns}
\centering
\begin{greenblock}{Standardnormalverteilung}
\vspace*{-10mm}
\begin{gather*}
X \sim \mathcal{N} (0,1) \\[4mm]
\Phi(x) := F_X(x) = P(X \le x) \\
\Phi(-x) = 1 - \Phi(x)
\end{gather*}
\end{greenblock}
\column{\kitthreecolumns}
\centering
\begin{greenblock}{Standardisierung}
\vspace*{-10mm}
\begin{gather*}
\widetilde{X} = \frac{X - E(X)}{\sqrt{V(X)}}
= \frac{X - \mu}{\sigma}
\end{gather*}
\end{greenblock}
\end{columns}
\vspace{5mm}
\begin{table}
\centering
% \cdots
\begin{tabular}{|c|c||c|c||c|c||c|c|}
\hline
$x$ & $\Phi(x)$ & $x$ & $\Phi(x)$ & $x$ & $\Phi(x)$ & $x$
& $\Phi(x)$ \\
\hline
\hline
$1{,}40$ & $0{,}919243$ & $2{,}80$ & $0{,}997445$ &
$3{,}00$ & $0{,}998650$ & $4{,}20$ & $0{,}999987$ \\
$1{,}42$ & $0{,}922196$ & $2{,}82$ & $0{,}997599$ &
$3{,}02$ & $0{,}998736$ & $4{,}22$ & $0{,}999988$ \\
$1{,}44$ & $0{,}925066$ & $2{,}84$ & $0{,}997744$ &
$3{,}04$ & $0{,}998817$ & $4{,}24$ & $0{,}999989$ \\
$1{,}46$ & $0{,}927855$ & $2{,}86$ & $0{,}997882$ &
$3{,}06$ & $0{,}998893$ & $4{,}26$ & $0{,}999990$ \\
$1{,}48$ & $0{,}930563$ & $2{,}88$ & $0{,}998012$ &
$3{,}08$ & $0{,}998965$ & $4{,}28$ & $0{,}999991$ \\
\hline
\end{tabular}
% \cdots
\end{table}
\end{frame} \end{frame}
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
@@ -329,16 +635,16 @@
\column{\kitthreecolumns} \column{\kitthreecolumns}
\centering \centering
\pause \begin{gather*} \pause \begin{gather*}
X \sim \mathcal{N} \mleft( \mu = 0{,}5, \sigma = 0{,}07^2 \mright) X \sim \mathcal{N} \mleft( \mu = 0{,}5, \sigma^2 = 0{,}07^2 \mright)
\end{gather*} \end{gather*}
\begin{align*} \begin{align*}
P(E_\text{a}) &= P \Big( \big( X < S(1-\delta) \big) P(E_\text{a}) &= P \Big( \big( X < S(1-\delta) \big)
\cup \big( X > S(1 + \delta) \big) \Big) \\ \cup \big( X > S(1 + \delta) \big) \Big) \\
&= P(X < S(1 - \delta)) + P(X > S(1 + \delta)) \\[2mm] &= P(X < S(1 - \delta)) + P(X > S(1 + \delta)) \\[2mm]
&= P\left(Z < \frac{S(1 - \delta) - \mu}{\sigma}\right) &\overset{\widetilde{X} := \frac{X - \mu}{\sigma} }{=\joinrel=\joinrel=\joinrel=} P\left(\widetilde{X} < \frac{S(1 - \delta) - \mu}{\sigma}\right)
+ P\left(Z > \frac{S(1 + \delta) - \mu}{\sigma}\right) \\[2mm] + P\left(\widetilde{X} > \frac{S(1 + \delta) - \mu}{\sigma}\right) \\[2mm]
&\approx \Phi(-2.86) + \left(1 - \Phi(2.86)\right) \\ &\approx \Phi(-2{,}86) + \left(1 - \Phi(2{,}86)\right) \\
&= 2 - 2\Phi(2.86) \approx 0{,}424\text{\%} &= 2 - 2\Phi(2{,}86) \approx 0{,}424\text{\%}
\end{align*} \end{align*}
\column{\kitthreecolumns} \column{\kitthreecolumns}
\centering \centering
@@ -359,8 +665,8 @@
\addplot+[mark=none, line width=1pt] \addplot+[mark=none, line width=1pt]
{1 / sqrt(2*3.1415*0.07*0.07) * exp(-(x - 5)*(x-5)/(2*0.07*0.07))}; {1 / sqrt(2*3.1415*0.07*0.07) * exp(-(x - 5)*(x-5)/(2*0.07*0.07))};
\addplot +[scol2, mark=none, line width=1pt] coordinates {(4.8, -1) (4.8, 2)}; \addplot +[KITblue, mark=none, line width=1pt] coordinates {(4.8, -1) (4.8, 2)};
\addplot +[scol2, mark=none, line width=1pt] coordinates {(5.2, -1) (5.2, 2)}; \addplot +[KITblue, mark=none, line width=1pt] coordinates {(5.2, -1) (5.2, 2)};
\node at (axis cs: 4.8, 3) {$S(1-\delta)$}; \node at (axis cs: 4.8, 3) {$S(1-\delta)$};
\node at (axis cs: 5.2, 3) {$S(1+\delta)$}; \node at (axis cs: 5.2, 3) {$S(1+\delta)$};
@@ -384,17 +690,17 @@
dass nur noch halb so viele Ladegeräte wie in a) aussortiert dass nur noch halb so viele Ladegeräte wie in a) aussortiert
werden. Auf welchen Wert müsste er dazu $\sigma$ senken? werden. Auf welchen Wert müsste er dazu $\sigma$ senken?
\pause\begin{gather*} \pause\begin{gather*}
P(E_\text{b}) = \frac{1}{2} P(E_\text{a}) \approx 0.212\text{\%} \\ P(E_\text{b}) = \frac{1}{2} P(E_\text{a}) \approx 0{,}212\text{\%} \\
\end{gather*} \end{gather*}
\vspace*{-18mm} \vspace*{-18mm}
\begin{columns} \begin{columns}
\pause\column{\kitthreecolumns} \pause\column{\kitthreecolumns}
\centering \centering
\begin{align*} \begin{align*}
P(E_\text{b}) &\overset{\text{a)}}{=} P\left(Z < \frac{S(1 - \delta) - \mu}{\sigma'}\right) P(E_\text{b}) &\overset{\text{a)}}{=} P\left(\widetilde{X} < \frac{S(1 - \delta) - \mu}{\sigma'}\right)
+ P\left(Z > \frac{S(1 + \delta) - \mu}{\sigma'}\right) \\[2mm] + P\left(\widetilde{X} > \frac{S(1 + \delta) - \mu}{\sigma'}\right) \\[2mm]
&= P\left(Z < -\frac{0{,}2}{\sigma'}\right) &= P\left(\widetilde{X} < -\frac{0{,}2}{\sigma'}\right)
+ P\left(Z > \frac{0{,}2}{\sigma'}\right) \\[2mm] + P\left(\widetilde{X} > \frac{0{,}2}{\sigma'}\right) \\[2mm]
&= \Phi\left(-\frac{0{,}2}{\sigma'}\right) &= \Phi\left(-\frac{0{,}2}{\sigma'}\right)
+ \left(1 - \Phi\left(\frac{0{,}2}{\sigma'} \right)\right) \\[2mm] + \left(1 - \Phi\left(\frac{0{,}2}{\sigma'} \right)\right) \\[2mm]
&= 2 - 2 \Phi\left(\frac{0{,}2}{\sigma'} \right) &= 2 - 2 \Phi\left(\frac{0{,}2}{\sigma'} \right)
@@ -402,20 +708,20 @@
\pause\column{\kitthreecolumns} \pause\column{\kitthreecolumns}
\centering \centering
\begin{gather*} \begin{gather*}
2 - 2\Phi\left(\frac{0.2}{\sigma'}\right) = 2{,}12\cdot 10^{-3} \\ 2 - 2\Phi\left(\frac{0{,}2}{\sigma'}\right) = 2{,}12\cdot 10^{-3} \\[2mm]
\Rightarrow \Phi\left(\frac{0.2}{\sigma'}\right) \approx 0.9989 \\ \Rightarrow \Phi\left(\frac{0{,}2}{\sigma'}\right) \approx 0{,}9989 \\[2mm]
\Rightarrow \sigma' \approx \frac{0{,}2}{\Phi^{-1}(0{,}9989)} \Rightarrow \sigma' \approx \frac{0{,}2}{\Phi^{-1}(0{,}9989)}
\approx \frac{0{,}2}{3{,}08} \approx 0.65 \approx \frac{0{,}2}{3{,}08} \approx 0{,}65
\end{gather*} \end{gather*}
\end{columns} \end{columns}
\pause \vspace*{-5mm}\item Durch einen Produktionsfehler verschiebt sich der \pause \vspace*{-5mm}\item Durch einen Produktionsfehler verschiebt sich der
Mittelwert $\mu$ auf $5{,}1$ Volt ($\sigma$ ist $0{,}07$ Volt). Mittelwert $\mu$ auf $5{,}1$ Volt ($\sigma$ ist $0{,}07$ Volt).
Wie groß ist jetzt der Prozentsatz, der aussortiert wird? Wie groß ist jetzt der Prozentsatz, der aussortiert wird?
\pause \begin{align*} \pause \begin{align*}
P(E_\text{c}) &\overset{\text{a)}}{=} P\left(Z < \frac{S(1 - \delta) - \mu}{\sigma}\right) P(E_\text{c}) &\overset{\text{a)}}{=} P\left(\widetilde{X} < \frac{S(1 - \delta) - \mu}{\sigma}\right)
+ P\left(Z > \frac{S(1 + \delta) - \mu}{\sigma}\right) \\[2mm] + P\left(\widetilde{X} > \frac{S(1 + \delta) - \mu}{\sigma}\right) \\[2mm]
&\approx \Phi(-4{,}29) + (1 - \Phi(1{,}43)) \\ &\approx \Phi(-4{,}29) + (1 - \Phi(1{,}43)) \\
& = 2 - \Phi(4{,}29) - \Phi(1{,}43) \approx 7.78 \text{\%} & = 2 - \Phi(4{,}29) - \Phi(1{,}43) \approx 7{,}78 \text{\%}
\end{align*} \end{align*}
\end{enumerate} \end{enumerate}
% tex-fmt: on % tex-fmt: on