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| \documentclass[uebung]{../../../lecture} | |||
| \title{Wtheo 0: Übungsblatt 3} | |||
| \author{Josua Kugler, Christian Merten} | |||
| \usepackage[]{bbm} | |||
| \usepackage[]{mathrsfs} | |||
| \begin{document} | |||
| \punkte[9] | |||
| \begin{aufgabe} | |||
| \begin{enumerate}[(a)] | |||
| \item Beh.: $C_{\alpha, x_m} = \alpha x_m^{\alpha}$. | |||
| \begin{proof} | |||
| Es muss gelten | |||
| \begin{salign*} | |||
| \int_{-\infty}^{\infty} \mathbbm{f}(x) \d x &= 1 | |||
| \intertext{Damit folgt} | |||
| \int_{-\infty}^{\infty} C_{\alpha, x_m} x^{-(\alpha +1)} \mathbbm{1}_{\{x \ge x_m\} } \d x | |||
| &= \int_{x_m}^{\infty} C_{\alpha,x_m} x^{-(\alpha + 1)} \d x \\ | |||
| &= C_{\alpha, x_m} \int_{x_m}^{\infty} x^{-(\alpha +1)} \d x \\ | |||
| &\stackrel{\alpha + 1 > 1}{=} - C_{\alpha, x_m} \frac{1}{\alpha} x^{-\alpha} \Big|_{x_m}^{\infty} \\ | |||
| &= - \frac{C_{\alpha,x_m}}{\alpha} \lim_{z \to \infty} \left[ z^{-\alpha} - x_m^{-\alpha} \right] \\ | |||
| &\stackrel{\alpha > 0}{=} \frac{C_{\alpha, x_m}}{\alpha} x_m^{-\alpha} \\ | |||
| &\stackrel{!}{=} 1 | |||
| \intertext{Damit folgt dann} | |||
| C_{\alpha,x_m} &= \alpha x_m^{\alpha} | |||
| .\end{salign*} | |||
| \end{proof} | |||
| \item Beh.: $\mathbbm{F}(x) = \left( 1 - \left( \frac{x_m}{x} \right)^{\alpha} \right) \mathbbm{1}_{\{x \ge x_m > 0\} }$ | |||
| \begin{proof} | |||
| Falls $x < x_m$ ist $\mathbbm{f}(y) = 0$ $\forall y \le x$, also $\mathbb{F}(x) = 0$. | |||
| Sei also $x \ge x_m$. Dann folgt | |||
| \begin{salign*} | |||
| \mathbb{F}(x) &= \int_{x_m}^{x} \alpha x_m^{\alpha} y^{-(\alpha + 1)} \d y \\ | |||
| &= - x_m^{\alpha} y^{-\alpha} \Big|_{x_m}^{x} \\ | |||
| &= - x_m^{\alpha} \left[ x^{-\alpha} - x_m^{-\alpha} \right] \\ | |||
| &= -x_m^{\alpha} x^{-\alpha} + x_m^{\alpha} x_m^{-\alpha} \\ | |||
| &= 1 - \left( \frac{x_m}{x} \right)^{\alpha} | |||
| \intertext{Insgesamt folgt} | |||
| \mathbb{F}(x) &= \left( 1 - \left( \frac{x_m}{x} \right)^{\alpha} \right) \mathbbm{1}_{\{x \ge x_m > 0\} } | |||
| .\end{salign*} | |||
| \end{proof} | |||
| \item Beh.: $\mathbb{P}([1,2]) = \frac{1}{2} = \mathbb{P}((2, \infty))$. | |||
| \begin{proof} | |||
| Mit $\alpha = x_m = 1$ folgt $\mathbb{F}(x) = \left( 1 - \frac{1}{x} \right) \mathbbm{1}_{\{x \le 1\} }$. Damit folgt | |||
| \begin{salign*} | |||
| \mathbb{P}([1,2]) &= \mathbb{F}(2) - \mathbb{F}(1) = 1 - \frac{1}{2} - 1 + 1 = \frac{1}{2} \\ | |||
| \mathbb{P}((2, \infty)) &= 1 - \mathbb{P}((-\infty, 2]) = 1 - \mathbb{F}(2) = 1 - 1 +\frac{1}{2} = \frac{1}{2} | |||
| .\end{salign*} | |||
| \end{proof} | |||
| \end{enumerate} | |||
| \end{aufgabe} | |||
| \stepcounter{aufgabe} | |||
| \begin{aufgabe} | |||
| Zunächst ist zu bemerken, dass mit $\mathscr{E} := \{ (a, \infty] \mid a \in \R\} $ nach VL | |||
| gilt $\sigma(\mathscr{E}) = \overline{\mathscr{B}}$. Damit ist | |||
| $f\colon \Omega \to \overline{\R}$ genau dann $(\mathscr{A}, \overline{\mathscr{B}})$ messbar, | |||
| wenn $f^{-1}(\mathscr{E}) \subseteq \mathscr{A}$. | |||
| \begin{enumerate}[(a)] | |||
| \item | |||
| \begin{enumerate}[(1)] | |||
| \item Sei $m \in \N$. Beh.: Folgende Abbildungen sind $(\mathscr{A}, \overline{\mathscr{B}})$ | |||
| messbar: | |||
| \begin{enumerate}[(i)] | |||
| \item $\sup_{n \ge m} X_n \colon \Omega \to \overline{\R}$ | |||
| \item $\inf_{n \ge m} X_n \colon \Omega \to \overline{\R}$ | |||
| \end{enumerate} | |||
| \begin{proof} | |||
| \begin{enumerate}[(i)] | |||
| \item Sei $a \in \R$ bel. Für $x \in \R$ gilt dann | |||
| \[ | |||
| \sup_{n \ge m} X^{n}(x) > a \iff \exists n \ge m\colon X^{n}(x) > a | |||
| .\] | |||
| Damit folgt da $X^{n}$ $(\mathscr{A}, \overline{\mathscr{B}})$-messbar | |||
| und $\mathscr{A}$ $\sigma$-Algebra: | |||
| \begin{salign*} | |||
| (\sup_{n \ge m} X_n)^{-1}((a, \infty])) | |||
| &= \{ x \in \Omega \mid \sup_{n \ge m} X^{n}(x) > a\} \\ | |||
| &= \{ x \in \Omega \mid \exists n \ge m\colon X^{n} > a\} \\ | |||
| &= \bigcup_{n \ge m} \{ x \in \Omega \mid X^{n}(x) > a\} \\ | |||
| &= \bigcup_{n \ge m} \underbrace{(X^{n})^{-1}((a, \infty])}_{\in \mathscr{A}} | |||
| \in \mathscr{A} | |||
| .\end{salign*} | |||
| Also $\sup_{n \ge m} X^{n}$ $(\mathscr{A}, \overline{\mathscr{B}})$-messbar. | |||
| \item Sei $a \in \R$. Für $x \in \R$ gilt dann | |||
| \[ | |||
| \inf_{n \ge m} X^{n}(x) < a \iff \exists n \ge m\colon X^{n}(x) < a | |||
| .\] | |||
| Damit folgt da $X^{n}$ $(\mathscr{A}, \overline{\mathscr{B}})$-messbar | |||
| und $\mathscr{A}$ $\sigma$-Algebra: | |||
| \begin{salign*} | |||
| (\inf_{n \ge m} X_n)^{-1}([-\infty, a)) | |||
| &= \{ x \in \Omega \mid \inf_{n \ge m} X^{n}(x) < a\} \\ | |||
| &= \{ x \in \Omega \mid \exists n \ge m\colon X^{n} < a\} \\ | |||
| &= \bigcup_{n \ge m} \{ x \in \Omega \mid X^{n}(x) < a\} \\ | |||
| &= \bigcup_{n \ge m} \underbrace{(X^{n})^{-1}([-\infty, a))}_{\in \mathscr{A}} | |||
| \in \mathscr{A} | |||
| .\end{salign*} | |||
| Da auch $\sigma(\{ [-\infty, a) \mid a \in \R \}) = \overline{\mathscr{B}}$ | |||
| folgt | |||
| also $\inf_{n \ge m} X^{n}$ $(\mathscr{A}, \overline{\mathscr{B}})$-messbar. | |||
| \end{enumerate} | |||
| \end{proof} | |||
| \item Beh.: $\limsup_{n \to \infty} X^{n}$ und $\liminf_{n \to \infty} X^{n}$ sind | |||
| $(\mathscr{A}, \overline{\mathscr{B}})$-messbar. | |||
| \begin{proof} | |||
| Definiere $f_m \coloneqq \sup_{n \ge m} X_n$. Dann ist $f_m$ messbar nach (1)(i) | |||
| und | |||
| \[ | |||
| \limsup_{n \to \infty} X_n = \inf_{m \ge 1} \sup_{n \ge m} X_n = \inf_{m \ge 1} f_m | |||
| \] $(\mathscr{A}, \overline{\mathscr{B}})$-messbar nach (1)(ii). | |||
| Definiere nun $h_m \coloneqq \inf_{n \ge m} X_n$. $h_m$ messbar nach (1) (ii) | |||
| $\forall m \in \N$. Dann ist auch | |||
| \[ | |||
| \liminf_{n \to \infty} X_n = \sup_{m \ge 1} \inf_{n \ge m} X_n = \sup_{m \ge 1} h_m | |||
| \] $(\mathscr{A}, \overline{\mathscr{B}})$-messbar nach (1)(i). | |||
| \end{proof} | |||
| \item Beh.: $\lim_{n \to \infty} X_n$ $(\mathscr{A}, \overline{\mathscr{B}})$-messbar. | |||
| \begin{proof} | |||
| Sei $X = \lim_{n \to \infty} X_n$. Dann ist | |||
| $X = \liminf_{n \to \infty} X_n = \limsup_{n \to \infty} X_n$, also | |||
| $X$ $(\mathscr{A}, \overline{\mathscr{B}})$-messbar nach (2). | |||
| \end{proof} | |||
| \end{enumerate} | |||
| \item Beh.: $Y$ $(\mathscr{A}, \mathscr{B})$-messbar. | |||
| \begin{proof} | |||
| Beachte, dass es für $\mathscr{B}$ genügt, die offenen Intervalle | |||
| $(a, \infty)$ für $a \in \R$ zu betrachten. | |||
| Sei $a \in \R$ bel. | |||
| \begin{itemize} | |||
| \item Falls $a \le 0$, dann ist $0, 1 \in (a, \infty)$, also | |||
| $Y^{-1}((a, \infty)) = \Omega \in \mathscr{A}$. | |||
| \item Falls $0 < a < 1$: Dann ist $1 \in (a, \infty)$ und $0 \not\in (a, \infty)$. Damit | |||
| folgt | |||
| \begin{salign*} | |||
| Y^{-1}((a, \infty)) &= \{ \omega \in \Omega \mid X_1(\omega) > X_2(\omega) \} \\ | |||
| &= \{ \omega \in \Omega \mid X_1(\omega) - X_2(\omega) > 0\} \\ | |||
| &= \{ \omega \in \Omega \mid (X_1 - X_2)(\omega) \in (0, \infty]\} \\ | |||
| &= (X_1 - X_2)^{-1}((0, \infty]) | |||
| .\end{salign*} | |||
| Da $X_1, X_2$ $(\mathscr{A}, \overline{\mathscr{B}})$-messbar, ist | |||
| nach VL auch $X_1 - X_2$ $(\mathscr{A}, \overline{\mathscr{B}})$ messbar. | |||
| Da weiter $(0, \infty] \in \overline{\mathscr{B}}$, folgt also | |||
| $(X_1 - X_2)^{-1}((0, \infty]) \in \mathscr{A}$. | |||
| \item Falls $a \ge 1$, dann ist $0, 1 \not\in (a, \infty)$, also | |||
| $Y^{-1}((a, \infty)) = \infty \in \mathscr{A}$. | |||
| \end{itemize} | |||
| \end{proof} | |||
| \end{enumerate} | |||
| \end{aufgabe} | |||
| \end{document} | |||