lecture 13 part 1

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@ -64,7 +64,7 @@ where $\mu = \bP X^{-1}$.
Let $\bP \in M_1(\R)$ such that $\phi_\R \in L^1(\lambda)$. Let $\bP \in M_1(\R)$ such that $\phi_\R \in L^1(\lambda)$.
Then $\bP$ has a continuous probability density given by Then $\bP$ has a continuous probability density given by
\[ \[
f(x) = \frac{1}{2 \pi} \int_{\R} e^{-\i t x} \phi_{\R(t) dt}. f(x) = \frac{1}{2 \pi} \int_{\R} e^{-\i t x} \phi_{\R}(t) dt.
\] \]
\end{theorem} \end{theorem}
@ -247,11 +247,13 @@ Unfortunately, we won't prove \autoref{bochnersthm} in this lecture.
which is the distribution of $X \equiv 0$. which is the distribution of $X \equiv 0$.
But $F_n(0) \centernot\to F(0)$. But $F_n(0) \centernot\to F(0)$.
\end{example} \end{example}
\begin{theorem} \begin{theorem} % Theorem 1
\label{lec10_thm1}
$X_n \xrightarrow{\text{dist}} X$ iff $X_n \xrightarrow{\text{dist}} X$ iff
$F_n(t) \to F(t)$ for all continuity points $t$ of $F$. $F_n(t) \to F(t)$ for all continuity points $t$ of $F$.
\end{theorem} \end{theorem}
\begin{theorem}[Levy's continuity theorem]\label{levycontinuity} \begin{theorem}[Levy's continuity theorem]\label{levycontinuity}
% Theorem 2
$X_n \xrightarrow{\text{dist}} X$ iff $X_n \xrightarrow{\text{dist}} X$ iff
$\phi_{X_n}(t) \to \phi(t)$ for all $t \in \R$. $\phi_{X_n}(t) \to \phi(t)$ for all $t \in \R$.
\end{theorem} \end{theorem}

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@ -221,6 +221,3 @@ Now, we can finally prove the CLT:
where $\langle t, X\rangle \coloneqq \sum_{i = 1}^d t_i X_i$. where $\langle t, X\rangle \coloneqq \sum_{i = 1}^d t_i X_i$.
\end{remark} \end{remark}
Exercise: Find out, which properties also hold for $d > 1$. Exercise: Find out, which properties also hold for $d > 1$.

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% Lecture 13 2023-05
%The difficult part is to show \autoref{levycontinuity}.
%This is the last lecture, where we will deal with independent random variables.
We have seen, that
if $X_1, X_2,\ldots$ are i.i.d.~with $ \mu = \bE[X_1]$,
$\sigma^2 = \Var(X_1)$,
then $\frac{\sum_{i=1}^{n} (X_i - \mu)}{\sigma \sqrt{n} } \xrightarrow{(d)} \cN(0,1)$.
\begin{question}
What happens if $X_1, X_2,\ldots$ are independent, but not identically distributed? Do we still have a CLT?
\end{question}
\begin{theorem}[Lindeberg CLT]
\label{lindebergclt}
Assume $X_1, X_2, \ldots,$ are independent (but not necessarily identically distributed) with $\mu_i = \bE[X_i] < \infty$ and $\sigma_i^2 = \Var(X_i) < \infty$.
Let $S_n = \sqrt{\sum_{i=1}^{n} \sigma_i^2}$
and assume that $\lim_{n \to \infty} \frac{1}{S_n^2} \bE\left[(X_i - \mu_i)^2 \One_{|X_i - \mu_i| > \epsilon \S_n}\right] = 0$ for all $\epsilon > 0$
(\vocab{Lindeberg condition}, ``The truncated variance is negligible compared to the variance.'').
Then the CLT holds, i.e.~
\[
\frac{\sum_{i=1}^n (X_i - \mu_i)}{S_n} \xrightarrow{(d)} \cN(0,1).
\]
\end{theorem}
\begin{theorem}[Lyapunov condition]
\label{lyapunovclt}
Let $X_1, X_2,\ldots$ be independent, $\mu_i = \bE[X_i] < \infty$,
$\sigma_i^2 = \Var(X_i) < \infty$
and $S_n \coloneqq \sqrt{\sum_{i=1}^n \sigma_i^2}$.
Then, assume that, for some $\delta > 0$,
\[
\lim_{n \to \infty} \sum_{i=1}^{n} \bE[(X_i - \mu_i)^{2 + \delta}] = 0
\]
(\vocab{Lyapunov condition}).
Then the CLT holds.
\end{theorem}
\begin{remark}
The Lyapunov condition implies the Lindeberg condition.
(Exercise).
\end{remark}
We will not prove the \autoref{linebergclt} or \autoref{lyapunovclt}
in this lecture. However, they are quite important.
We will now sketch the proof of \autoref{levycontinuity},
details can be found in the notes.\todo{Complete this}
A generalized version of \autoref{levycontinuity} is the following:
\begin{theorem}[A generalized version of Levy's continuity \autoref{levycontinuity}]
\label{genlevycontinuity}
Suppose we have random variables $(X_n)_n$ such that
$\bE[e^{\i t X_n}] \xrightarrow{n \to \infty} \phi(t)$ for all $t \in \R$
for some function $\phi$ on $\R$.
Then the following are equivalent:
\begin{enumerate}[(a)]
\item The distribution of $X_n$ is \vocab[Distribution!tight]{tight} (dt. ``straff''),
i.e.~$\lim_{a \to \infty} \sup_{n \in \N} \bP[|X_n| > a] = 0$.
\item $X_n \xrightarrow{(d)} X$ for some real-valued random variable $X$.
\item $\phi$ is the characteristic function of $X$.
\item $\phi$ is continuous on all of $\R$.
\item $\phi$ is continuous at $0$.
\end{enumerate}
\end{theorem}
\begin{example}
Let $Z \sim \cN(0,1)$ and $X_n \coloneqq n Z$.
We have $\phi_{X_n}(t) = \bE[[e^{\i t X_n}] = e^{-\frac{1}{2} t^2 n^2} \xrightarrow{n \to \infty} \One_{\{t = 0\} }$.
$\One_{\{t = 0\}}$ is not continuous at $0$.
By \autoref{genlevycontinuity}, $X_n$ can not converge to a real-valued
random variable.
Exercise: $X_n \xrightarrow{(d)} \overline{X}$,
where $\bP[\overline{X} = \infty] = \frac{1}{2} = \bP[\overline{X} = -\infty]$.
Similar examples are $\mu_n \coloneqq \delta_n$ and
$\mu_n \coloneqq \frac{1}{2} \delta_n + \frac{1}{2} \delta_{-n}$.
\end{example}
\begin{example}
Suppose that $X_1, X_2,\ldots$ are i.d.d.~with $\bE[X_1] = 0$.
Let $\sigma^2 \coloneqq \Var(X_i)$.
Then the distribution of $\frac{S_n}{\sigma \sqrt{n}}$ is tight:
\begin{IEEEeqnarray*}{rCl}
\bE\left[ \left( \frac{S_n}{\sqrt{n} }^2 \right)^2 \right] &=&
\frac{1}{n} \bE[ (X_1+ \ldots + X_n)^2]\\
&=& \sigma^2
\end{IEEEeqnarray*}
For $a > 0$, by Chebyshev's inequality, % TODO
we have
\[
\bP\left[ \left| \frac{S_n}{\sqrt{n}} \right| > a \right] \leq \frac{\sigma^2}{a^2} \xrightarrow{a \to \infty} 0.
\]
verifying \autoref{genlevycontinuity}.
\end{example}
\begin{example}
Suppose $C$ is a random variable which is Cauchy distributed, i.e.~$C$
has probability distribution $f_C(x) = \frac{1}{\pi} \frac{1}{1 + x^2}$.
We know that $\bE[|C|] = \infty$.
We have $\phi_C(t) = \bE[e^{\i t C}] = e^{-|t|}$.
Suppose $C_1, C_2, \ldots, C_n$ are i.i.d.~Cauchy distributed
and let $S_n \coloneqq C_1 + \ldots + C_n$.
Exercise: $\phi_{S_n}(t) = e^{-|t|} = \phi_{C_1}(t)$, thus $S_n \sim C$.
\end{example}