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I have a Poisson process $X_t$ for $t\ge0$. How I can find a process $b_t$ such that $\exp ({\alpha X_t})=1+\int_0^t b_{s^{-}}dX_s$ where $\alpha\in\mathbb{R}$ and what would be the expectation of $\exp ({\alpha X_t})$. The last question is how i can find expectation and variance of this process $\int_0^t \exp(\alpha X_{s^-})dX_s.$

Thanks.

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    Wh$a$t is the context of this question? Usually if you encounter stochastic integrals you would know a bit of stochastics...2011-04-18

1 Answers 1

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I thinks this is an application of Ito's Lemma with noncontinuous semimartingales. Of course, in the case that $X$ is a Poisson process, it simpliefies to $f(X_t)-f(X_0)=\sum_{0< s\le t} \Delta [f(X_{s})],$ where $f(x)=e^{\alpha x}$. Since the Poisson process has a jump size 1 a.s., $\sum_{0 So the process you are looking for is $b_s=f(X_s+1)-f(X_s)=\exp(\alpha X_s)(e^\alpha-1).$

With that, the last question is easy to answer, since $\int_0^t \exp(\alpha X_{s^-})dX_s=\frac1{e^{\alpha}-1}[\exp(\alpha X_t)-1],$ and you can use the moment generating function for $X_t$ $\mathbb{E} \exp(\alpha X_t)=\exp\{\lambda t (e^{\alpha}-1)\}$ to figure out expectation and variance of $\int_0^t \exp(\alpha X_{s^-})dX_s.$

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    Yup. $ $ $ $ $ $2011-04-26