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| Title of object: |
hitting times are stopping times |
| Canonical Name: |
HittingTimesAreStoppingTimes |
| Type: |
Theorem |
| Created on: |
2008-12-27 12:26:57 |
| Modified on: |
2008-12-27 13:38:40 |
| Classification: |
msc:60G40, msc:60G05 |
| Keywords: |
stopping time, adapted process, progressive process |
| Defines: |
hitting time |
Preamble:
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Content:
\PMlinkescapeword{filtration}
\PMlinkescapeword{property}
\PMlinkescapeword{index set}
\PMlinkescapeword{state}
\PMlinkescapeword{even}
\PMlinkescapeword{analytic sets}
\PMlinkescapeword{properties}
Let $(\mathcal{F}_t)_{t\in\mathbb{T}}$ be a \PMlinkname{filtration}{FiltrationOfSigmaAlgebras} on a measurable space $(\Omega,\mathcal{F})$. If $X$ is an adapted stochastic process taking values in a measurable space $(E,\mathcal{A})$ then the \emph{hitting time} of a set $S\in\mathcal{A}$ is defined as
\begin{align*}
&\tau\colon\Omega\rightarrow\mathbb{T}\cup\{\pm\infty\},\\
&\tau(\omega)=\inf\left\{t\in\mathbb{T}:X_t(\omega)\in S\right\}.
\end{align*}
We suppose that $\mathbb{T}$ is a closed subset of $\mathbb{R}$, so the hitting time $\tau$ will indeed lie in $\mathbb{T}$ whenever it is finite. The main cases are discrete-time when $\mathbb{T}=\mathbb{Z}_+$ and continuous-time where $\mathbb{T}=\mathbb{R}_+$. An important property of hitting times is that they are stopping times, as stated below for the different cases.
\section{discrete-time processes}
For discrete-time processes, hitting times are easily shown to be stopping times.
\begin{theorem*}
If the index set $\mathbb{T}$ is discrete, then the hitting time $\tau$ is a stopping time.
\end{theorem*}
\begin{proof}
For any $s\le t\in\mathbb{T}$ then $X_s$ will be $\mathcal{F}_t/\mathcal{A}$-measurable, as it is adapted. So, by the fact that the $\sigma$-algebra $\mathcal{F}_t$ is closed under taking countable unions,
\begin{equation*}
\left\{\tau\le t\right\}=\bigcup_{\substack{s\in\mathbb{T},\\ s\le t}}X_s^{-1}(S)\in\mathcal{F}_t
\end{equation*}
as required.
\end{proof}
\section{right-continuous processes}
For continuous-time processes it is not necessarily true that a hitting time is even measurable. However, the situation is simpler for right-continuous processes.
\begin{theorem*}
Suppose that $X$ is a right-continuous and adapted process taking values in a metric space $E$, and that the filtration $(\mathcal{F}_t)$ is universally complete. Then, the hitting time $\tau$ of any closed subset $S\subseteq E$ is a stopping time.
\end{theorem*}
In particular, the hitting time of any closed set $S\subseteq\mathbb{R}$ for an adapted right-continuous and real-valued process is a stopping time.
The proof of this result is rather more involved than the discrete-time case and the condition that $\mathcal{F}_t$ is universally complete is required, otherwise $\tau$ need not even be measurable.
\section{progressively measurable processes}
The d\'ebut $D(A)$ of a set $A\subseteq\mathbb{T}\times\Omega$ is defined to be the hitting time of $\{1\}$ for the process $1_A$,
\begin{equation*}
D(A)(\omega)=\inf\left\{ t\in\mathbb{T}:(t,\omega)\in A\right\}.
\end{equation*}
An important result for continuous-time stochastic processes is the d\'ebut theorem.
\begin{theorem*}[D\'ebut theorem]
Suppose that the filtration $(\mathcal{F}_t)$ is right-continuous and universally complete. Then, the d\'ebut $D(A)$ of a progressively measurable $A\subseteq\mathbb{T}\times\Omega$ is a stopping time.
\end{theorem*}
Proofs of this result typically rely upon properties of analytic sets, and are therefore much more involved than the result above for right-continuous processes.
A process $X$ taking values in a measurable space $(E,\mathcal{A})$ is said to be progressive if the set $X^{-1}(S)$ is progressively measurable for every $S\in\mathcal{A}$. In particular, the hitting time of $S$ is equal to the d\'ebut of $X^{-1}(S)$ and the d\'ebut theorem has the following immediate corollary.
\begin{theorem*}
Suppose that the filtration $(\mathcal{F}_t)$ is right-continuous and universally complete, and that $X$ is a progressive process taking values in a measurable space $(E,\mathcal{A})$. Then, the hitting time $\tau$ of any set $S\in\mathcal{A}$ is a stopping time.
\end{theorem*}
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