Borel right process

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Let $E$ be a locally compact separable metric space. We will denote by $\mathcal E$ the Borel subsets of $E$ . Let $Ω$ be the space of right continuous maps from $[0,\infty)$ to $E$ that have left limits in $E$ , and for each $t \in [0,\infty)$ , denote by $X t$ the coordinate map at $t$ ; for each $\omega \in \Omega$ , $X_t(\omega) \in E$ is the value of $ω$ at $t$ . We denote the universal completion of $\mathcal E$ by $\mathcal E^*$ . For each $t\in[0,\infty)$ , let

$\mathcal F_t = \sigma\left\{ X_s^{-1}(B) : s\in[0,t], B \in \mathcal E\right\},$

$\mathcal F_t^* = \sigma\left\{ X_s^{-1}(B) : s\in[0,t], B \in \mathcal E^*\right\},$

and then, let

$\mathcal F_\infty = \sigma\left\{ X_s^{-1}(B) : s\in[0,\infty), B \in \mathcal E\right\},$

$\mathcal F_\infty^* = \sigma\left\{ X_s^{-1}(B) : s\in[0,\infty), B \in \mathcal E^*\right\}.$

For each Borel measurable function $f$ on $E$ , define, for each $x \in E$ ,

$U^\alpha f(x) = \mathbf E^x\left[ \int_0^\infty e^{-\alpha t} f(X_t)\, dt \right].$

Since $P_tf(x) = \mathbf E^x\left[f(X_t)\right]$ and the mapping given by $t \rightarrow X_t$ is right continuous, we see that for any uniformly continuous function $f$ , we have that the mapping given by $t \rightarrow P_tf(x)$ is right continuous. Therefore, together with the monotone class theorem, one can show that for any universally measurable function $f$ , the mapping given by $(t,x) \rightarrow P_tf(x)$ , is jointly measurable, that is, $\mathcal B([0,\infty))\otimes \mathcal E^*$ measurable, and subsequently, the mapping is also $\left(\mathcal B([0,\infty))\otimes \mathcal E^*\right)^{\lambda\otimes \mu}$ -measurable for all finite measures $λ$ on $\mathcal B([0,\infty))$ and $μ$ on $\mathcal E^*$ . Here, $\left(\mathcal B([0,\infty))\otimes \mathcal E^*\right)^{\lambda\otimes \mu}$ is the completion of $\mathcal B([0,\infty))\otimes \mathcal E^*$ with respect to the product measure $\lambda \otimes \mu$ . Now, this shows that for any bounded universally measurable function $f$ on $E$ , the mapping $t\rightarrow P_tf(x)$ is Lebeague measurable, and hence, for each $\alpha \in [0,\infty)$ , one can define

$U^\alpha f(x) = \int_0^\infty e^{-\alpha t}P_tf(x) dt.$

There is enough joint measurability to check that $\{U^\alpha : \alpha \in (0,\infty) \}$ is a Markov resolvent on $(E,\mathcal E^*)$ , which uniquely associated with the Markovian semigroup $\{ P_t : t \in [0,\infty) \}$ . Consequently, one may apply Fubini's theorem to see that

$U^\alpha f(x) = \mathbf E^x\left[ \int_0^\infty e^{-\alpha t} f(X_t) dt \right].$

The followings are the defining properties of Borel right processes:

Hypothesis Droite 1: For each probability measure $μ$ on $(E, \mathcal E)$ , there exists a probability measure $\mathbf P^\mu$ on $(\Omega, \mathcal F^*)$ such that $(X_t, \mathcal F_t^*, P^\mu)$ is a Markov process with initial measure $μ$ and transition semigroup $\{ P_t : t \in [0,\infty) \}$ .
Hypothesis Droite 2: Let $f$ be $α$ -excessive for the resolvent on $(E, \mathcal E^*)$ . Then, for each probability measure $μ$ on $(E,\mathcal E)$ , a mapping given by $t \rightarrow f(X_t)$ is $P μ$ almost surely right continuous on $[0,\infty)$ .

Categories: Topology | Descriptive set theory

Borel right process

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