added definition of conditional probability

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Josia Pietsch 2023-06-29 20:39:53 +02:00
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2 changed files with 27 additions and 40 deletions

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@ -78,6 +78,15 @@ We now want to generalize this to arbitrary random variables.
is a constant random variable.
\end{remark}
\begin{definition}[Conditional probability]
Let $A \subseteq \Omega$ be an event and $\cG \subseteq \cF$
a sub-$\sigma$-algebra.
We define the \vocab{conditional probability} of $A$ given $\cG$ by
\[
\bP[A | \cG] \coloneqq \bE[\One_A | \cG].
\]
\end{definition}
\paragraph{Plan}
We will give two different proves of \autoref{conditionalexpectation}.
The first one will use orthogonal projections.

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@ -1,5 +1,4 @@
\lecture{21}{2023-06-29}{}
% TODO: replace bf
This is the last lecture relevant for the exam.
(Apart from lecture 22 which will be a repetion).
@ -12,18 +11,18 @@ This is the last lecture relevant for the exam.
\begin{notation}
Let $E$ be a complete, separable metric space (e.g.~$E = \R$).
Suppose that for all $x \in E$ we have a probability measure
$\bfP(x, \dif y)$ on $E$.
$\mathbf{P}(x, \dif y)$ on $E$.
% i.e. $\mu(A) \coloneqq \int_A \bP(x, \dif y)$ is a probability measure.
Such a probability measure is a called
a \vocab{transition probability measure}.
\end{notation}
\begin{examle}
\begin{example}
$E =\R$,
\[\bfP(x, \dif y) = \frac{1}{\sqrt{2 \pi} } e^{- \frac{(x-y)^2}{2}} \dif y\]
\[\mathbf{P}(x, \dif y) = \frac{1}{\sqrt{2 \pi} } e^{- \frac{(x-y)^2}{2}} \dif y\]
is a transition probability measure.
\end{examle}
\end{example}
\begin{example}[Simple random walk as a transition probability measure]
$E = \Z$, $\bfP(x, \dif y)$
$E = \Z$, $\mathbf{P}(x, \dif y)$
assigns mass $\frac{1}{2}$ to $y = x+1$ and $y = x -1$.
\end{example}
@ -32,26 +31,26 @@ This is the last lecture relevant for the exam.
$x \in E$
define
\[
(\bfP f)(x) \coloneqq \int_E f(y) \bfP(x, \dif y).
(\mathbf{P} f)(x) \coloneqq \int_E f(y) \mathbf{P}(x, \dif y).
\]
This $\bfP$ is called a \vocab{transition operator}.
This $\mathbf{P}$ is called a \vocab{transition operator}.
\end{definition}
\begin{fact}
If $f \ge 0$, then $(\bfP f)(\cdot ) \ge 0$.
If $f \ge 0$, then $(\mathbf{P} f)(\cdot ) \ge 0$.
If $f \equiv 1$, we have $(\bfP f) \equiv 1$.
If $f \equiv 1$, we have $(\mathbf{P} f) \equiv 1$.
\end{fact}
\begin{notation}
Let $\bfI$ denote the \vocab{identity operator},
Let $\mathbf{I}$ denote the \vocab{identity operator},
i.e.
\[
(\bfI f)(x) = f(x)
(\mathbf{I} f)(x) = f(x)
\]
for all $f$.
Then for a transition operator $\bfP$ we write
Then for a transition operator $\mathbf{P}$ we write
\[
\bfL \coloneqq \bfI - \bfP.
\mathbf{L} \coloneqq \mathbf{I} - \mathbf{P}.
\]
\end{notation}
@ -71,16 +70,16 @@ is the unique solution to this problem.
Let $(\Omega, \cF, \{\cF_n\}_n, \bP_x)$
be a filtered probability space, where for every $x \in \R$,
$\bP_x$ is a probability measure.
Let $\bE_x$ denote expectation with respect to $\bfP(x, \cdot )$.
Let $\bE_x$ denote expectation with respect to $\mathbf{P}(x, \cdot )$.
Then $(X_n)_{n \ge 0}$ is a \vocab{Markov chain} starting at $x \in \R$
with \vocab[Markov chain!Transition probability]{transition probability}
$\bfP(x, \cdot )$ if
$\mathbf{P}(x, \cdot )$ if
\begin{enumerate}[(i)]
\item $\bP_x[X_0 = x] = 1$,
\item for all bounded, measurable $f: \R \to \R$,
\[\bE_x[f(X_{n+1}) | \cF_n] \overset{\text{a.s.}}{=}%
\bE_{x}[f(X_{n+1}) | X_n] = %
\int f(y) \bfP(X_n, \dif y).\]
\int f(y) \mathbf{P}(X_n, \dif y).\]
\end{enumerate}
(Recall $\cF_n = \sigma(X_1,\ldots, X_n)$.)
\end{definition}
@ -92,12 +91,6 @@ is the unique solution to this problem.
\]
\end{example}
\begin{definition}[Conditional probability]
\[
\bP[A | \cG] \coloneqq \bE[\One_A | \cG].
\]
\end{definition}
\begin{example}
Let $\xi_i$ be i.i.d.~with$\bP[\xi_i = 1] = \bP[\xi_i = -1] = \frac{1}{2}$
and define $X_n \coloneqq \sum_{i=1}^{n} \xi_i$.
@ -105,14 +98,8 @@ is the unique solution to this problem.
Intuitively, conditioned on $X_n$, $X_{n+1}$ should
be independent of $\sigma(X_1,\ldots, X_{n-1})$.
For a set $B$, we have
\[
\bP_0[X_{n+1} \in B| \sigma(X_1,\ldots, X_n)]
= \bE[\One_{X_n + \xi_{n+1} \in B} | \sigma(X_1,\ldots, X_n)]
= \bE[\One_{X_n + \xi_{n+1} \in B} | \sigma(X_n)].
\]
\begin{claim}
For a set $B$, we have
$\bE[\One_{X_{n+1} \in B} | \sigma(X_1,\ldots, X_n)] = \bE[\One_{X_{n+1} \in B} | \sigma(X_n)]$.
\end{claim}
\begin{subproof}
@ -120,16 +107,7 @@ is the unique solution to this problem.
\end{subproof}
\end{example}
%TODO
{ \huge\color{red}
{ \large\color{red}
New information after this point is not relevant for the exam.
}
Stopping times and optional stopping are very relevant for the exam,