UMD Probability Qualifying Exams/Jan2010Probability

We will show it converges to a Poisson distribution with parameter ${\displaystyle \lambda }$. The characteristic function for the Poisson distribution is ${\displaystyle e^{\lambda (e^{it}-1)}}$. We show the characteristic function, ${\displaystyle E[\exp(it\sum _{k=1}^{r_{n}}X_{nk})]}$ converges to ${\displaystyle e^{\lambda (e^{it}-1)}}$, which implies the result.

${\displaystyle \log E[\exp(it\sum _{k=1}^{r_{n}}X_{nk})]=\sum _{k=1}^{r_{n}}\log((1-p_{nk})+p_{nk}e^{it})=\sum _{k=1}^{r_{n}}\log(1-p_{nk}(1-e^{it}))=\sum _{k=1}^{r_{n}}(-p_{nk}(1-e^{it})+O(p_{nk}^{2}))}$. By our assumptions, this converges to ${\displaystyle \lambda (e^{it}-1)}$.

Let ${\displaystyle Y_{n}=(X_{1}X_{2}\cdots X_{n})^{1/n}}$.

${\displaystyle \log(Y_{n})={\frac {1}{n}}\sum _{j=1}^{n}\log(X_{j})}$.

The random variables ${\displaystyle \log(X_{j})}$ are i.i.d. with finite mean,

${\displaystyle E[\log(X_{j})]=\int _{0}^{1}\log(t)dt=-1}$.

Therefore, the strong law of large numbers implies ${\displaystyle {\frac {1}{n}}\sum _{j=1}^{n}\log(X_{j})}$ converges with probability one to ${\displaystyle -1}$.

So almost surely, ${\displaystyle \log(Y_{n})}$ converges to ${\displaystyle -1}$ and ${\displaystyle Y_{n}}$ converges to ${\displaystyle e^{-1}}$.

Since ${\displaystyle X_{n}}$ is a martingale, ${\displaystyle |X_{n}|}$ is a non-negative submartingale and ${\displaystyle E[|X_{n}|^{2}]<\infty }$ since ${\displaystyle X_{n}}$ is square integrable. Thus ${\displaystyle |X_{n}|}$ meets the conditions for Doob's Martingale Inequality and the result follows.

${\displaystyle E[(X-E[X|{\mathcal {G}}_{1}])^{2}]=E[((X-E[X|{\mathcal {G}}_{2}])+(E[X|{\mathcal {G}}_{2}]-E[X|{\mathcal {G}}_{1}]))^{2}]}$ ${\displaystyle =E[(X-E[X|{\mathcal {G}}_{2}])^{2}]+E[(E[X|{\mathcal {G}}_{2}]-E[X|{\mathcal {G}}_{1}])^{2}]+2E[(X-E[X|{\mathcal {G}}_{2}])(E[X|{\mathcal {G}}_{2}]-E[X|{\mathcal {G}}_{1}])]}$

We will show that the third term vanishes. Then since the second term is nonnegative, the result follows.

${\displaystyle E[(X-E[X|{\mathcal {G}}_{2}])(E[X|{\mathcal {G}}_{2}]-E[X|{\mathcal {G}}_{1}])]=E[E[(X-E[X|{\mathcal {G}}_{2}])(E[X|{\mathcal {G}}_{2}]-E[X|{\mathcal {G}}_{1}])|{\mathcal {G}}_{2}]]}$ by the law of total probability.

${\displaystyle E[(X-E[X|{\mathcal {G}}_{2}])(E[X|{\mathcal {G}}_{2}]-E[X|{\mathcal {G}}_{1}])|{\mathcal {G}}_{2}]=(E[X|{\mathcal {G}}_{2}]-E[X|{\mathcal {G}}_{1}])E[(X-E[X|{\mathcal {G}}_{2}])|{\mathcal {G}}_{2}]}$, since ${\displaystyle (E[X|{\mathcal {G}}_{2}]-E[X|{\mathcal {G}}_{1}])}$ is ${\displaystyle {\mathcal {G}}_{2}}$-measurable.

Finally, ${\displaystyle E[(X-E[X|{\mathcal {G}}_{2}])|{\mathcal {G}}_{2}]=E[X|{\mathcal {G}}_{2}]-E[E[X|{\mathcal {G}}_{2}]|{\mathcal {G}}_{2}]=E[X|{\mathcal {G}}_{2}]-E[X|{\mathcal {G}}_{2}]=0}$

We show ${\displaystyle P[X_{n}=1{\text{ finitely often}}]=0.}$. If ${\displaystyle X_{n}=1}$ for only finitely many ${\displaystyle n}$, then there is a largest index ${\displaystyle T}$ for which ${\displaystyle X_{T}=1}$. We show in contrast that for all ${\displaystyle T}$, ${\displaystyle P[X_{n}=0{\text{ for all }}n\geq T]=0}$.

First notice, ${\displaystyle P[X_{1}=0]\leq (1-\alpha )}$ and ${\displaystyle P[X_{T}=0]=E[P[X_{T}=0|X_{1},X_{2},\ldots ,X_{T-1}]]\leq (1-\alpha ){\text{ for T}}>1}$.

Then let ${\displaystyle A_{n}^{(T)}}$ be the event ${\displaystyle [X_{T+n-1}=\ldots =X_{T}=0]}$, then ${\displaystyle P[X_{n}=0{\text{ for all }}n\geq T]=P[A_{n}^{(T)}{\text{ occurs for all n}}]}$.

Notice ${\displaystyle P[A_{n}^{(T)}]=P[X_{T+n-1}=0|A_{n-1}^{(T)}]P[A_{n-1}^{(T)}]\leq (1-\alpha )P[A_{n-1}^{(T)}]{\text{ for n =2,3,}}\ldots }$ and ${\displaystyle P[A_{1}^{(T)}]=P[X_{T}=0]\leq (1-\alpha )}$. Therefore ${\displaystyle P[A_{n}^{(T)}]\leq (1-\alpha )^{n}}$ and ${\displaystyle \lim _{n\rightarrow \infty }P[A_{n}^{(T)}]=0}$. So ${\displaystyle P[X_{n}=0{\text{ for all n}}\geq T]=0}$ and we reach the desired conclusion.