Autocorrelator: Difference between revisions

Latest revision as of 01:39, 17 December 2013

Let $(E, 𝒜, μ)$ be some measure space with $σ$ -finite measure $μ$ . The Poisson random measure with intensity measure $μ$ is a family of random variables ${N_{A}}_{A \in 𝒜}$ defined on some probability space $(Ω, ℱ, P)$ such that

i) $\forall A \in 𝒜, N_{A}$ is a Poisson random variable with rate $μ (A)$ .

ii) If sets $A_{1}, A_{2}, \dots, A_{n} \in 𝒜$ don't intersect then the corresponding random variables from i) are mutually independent.

iii) $\forall ω \in Ω N_{∙} (ω)$ is a measure on $(E, 𝒜)$

Existence

If $μ \equiv 0$ then $N \equiv 0$ satisfies the conditions i)–iii). Otherwise, in the case of finite measure $μ$ , given $Z$ , a Poisson random variable with rate $μ (E)$ , and $X_{1}, X_{2}, \dots$ , mutually independent random variables with distribution $\frac{μ}{μ (E)}$ , define $N_{\cdot} (ω) = \sum_{i = 1}^{Z (ω)} δ_{X_{i} (ω)} (\cdot)$ where $δ_{c} (A)$ is a degenerate measure located in $c$ . Then $N$ will be a Poisson random measure. In the case $μ$ is not finite the measure $N$ can be obtained from the measures constructed above on parts of $E$ where $μ$ is finite.

Applications

This kind of random measure is often used when describing jumps of stochastic processes, in particular in Lévy–Itō decomposition of the Lévy processes.

References

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+Let <math>(E, \mathcal A, \mu)</math> be some [[measure space]] with <math>\sigma</math>-[[sigma finite measure|finite measure]] <math>\mu</math>. The '''Poisson random measure''' with intensity [[Measure (mathematics)|measure]] <math>\mu</math> is a family of [[random variables]] <math>\{N_A\}_{A\in\mathcal{A}}</math> defined on some [[probability space]] <math>(\Omega, \mathcal F, \mathrm{P})</math> such that
+i) <math>\forall A\in\mathcal{A},\quad N_A</math> is a [[Poisson distribution|Poisson random variable]] with rate <math>\mu(A)</math>.
+ii) If sets <math>A_1,A_2,\ldots,A_n\in\mathcal{A}</math> don't intersect then the corresponding [[random variables]] from i) are mutually [[Statistical independence|independent]].
+iii) <math>\forall\omega\in\Omega\;N_{\bullet}(\omega)</math> is a measure on <math>(E, \mathcal A)</math>
+==Existence==
+If <math>\mu\equiv 0</math> then <math>N\equiv 0</math> satisfies the conditions i)–iii). Otherwise,  in the case of [[finite measure]] <math>\mu</math>, given <math>Z</math>, a [[Poisson distribution|Poisson random variable]] with rate <math>\mu(E)</math>, and <math>X_1, X_2,\ldots</math>, mutually [[Statistical independence|independent]] [[random variable]]s with [[Probability distribution|distribution]] <math>\frac{\mu}{\mu(E)}</math>, define <math>N_{\cdot}(\omega) = \sum\limits_{i=1}^{Z(\omega)} \delta_{X_i(\omega)}(\cdot)</math> where <math>\delta_c(A)</math> is a [[degenerate distribution|degenerate measure]] located in <math>c</math>. Then <math>N</math> will be a Poisson random measure. In the case <math>\mu</math> is not finite the [[Measure (mathematics)|measure]] <math>N</math> can be obtained from the measures constructed above on parts of <math>E</math> where <math>\mu</math> is finite.
+==Applications==
+This kind of [[random measure]] is often used when describing jumps of [[stochastic process]]es, in particular in [[Lévy–Itō decomposition]] of the [[Lévy process]]es.
+==References==
+*{{cite book |last=Sato |first=K. |year=2010 |title=Lévy Processes and Infinitely Divisible Distributions |publisher=Cambridge University Press |isbn=0-521-55302-4 }}
+[[Category:Probability theory]]

Autocorrelator: Difference between revisions

Latest revision as of 01:39, 17 December 2013

Existence

Applications

References

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