Difference between revisions of "Lévy-Khinchin canonical representation"
From Encyclopedia of Mathematics
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| − | A formula for the logarithm | + | {{TEX|done}} |
| + | A formula for the logarithm $\ln\phi(\lambda)$ of the [[Characteristic function|characteristic function]] of an [[Infinitely-divisible distribution|infinitely-divisible distribution]]: | ||
| − | + | $$\ln\phi(\lambda)=i\gamma\lambda+\int\limits_{-\infty}^\infty\left(e^{i\lambda x}-1-\frac{i\lambda x}{1+x^2}\right)\frac{1+x^2}{x^2}dG(x),$$ | |
| − | where the integrand is equal to | + | where the integrand is equal to $-\lambda^2/2$ for $x=0$ and the characteristics $\gamma$ and $G$ are such that $\gamma$ is a real number and $G$ is a non-decreasing left-continuous [[Function of bounded variation|function of bounded variation]]. |
| − | The Lévy–Khinchin canonical representation was proposed by A.Ya. Khinchin (1937) and is equivalent to a formula proposed a little earlier by P. Lévy (1934) and called the [[Lévy canonical representation|Lévy canonical representation]]. To each infinitely-divisible distribution corresponds a unique set of characteristics | + | The Lévy–Khinchin canonical representation was proposed by A.Ya. Khinchin (1937) and is equivalent to a formula proposed a little earlier by P. Lévy (1934) and called the [[Lévy canonical representation|Lévy canonical representation]]. To each infinitely-divisible distribution corresponds a unique set of characteristics $\gamma$ and $G$ in the Lévy–Khinchin canonical representation, and conversely, for any $\gamma$ and $G$ as above, the Lévy–Khinchin canonical representation determines the logarithm of the characteristic function of an infinitely-divisible distribution. For the weak convergence of the sequence of infinitely-divisible distributions determined by characteristics $\gamma_n$, $G_n$, $n=1,2,\dots,$ to a distribution (which is necessarily infinitely divisible) with characteristics $\gamma$ and $G$ it is necessary and sufficient that $\lim\gamma_n=\gamma$ and that the $G_n$ converge weakly to $G$ as $n\to\infty$. |
For references see [[Lévy canonical representation|Lévy canonical representation]]. | For references see [[Lévy canonical representation|Lévy canonical representation]]. | ||
Latest revision as of 17:46, 10 October 2014
A formula for the logarithm $\ln\phi(\lambda)$ of the characteristic function of an infinitely-divisible distribution:
$$\ln\phi(\lambda)=i\gamma\lambda+\int\limits_{-\infty}^\infty\left(e^{i\lambda x}-1-\frac{i\lambda x}{1+x^2}\right)\frac{1+x^2}{x^2}dG(x),$$
where the integrand is equal to $-\lambda^2/2$ for $x=0$ and the characteristics $\gamma$ and $G$ are such that $\gamma$ is a real number and $G$ is a non-decreasing left-continuous function of bounded variation.
The Lévy–Khinchin canonical representation was proposed by A.Ya. Khinchin (1937) and is equivalent to a formula proposed a little earlier by P. Lévy (1934) and called the Lévy canonical representation. To each infinitely-divisible distribution corresponds a unique set of characteristics $\gamma$ and $G$ in the Lévy–Khinchin canonical representation, and conversely, for any $\gamma$ and $G$ as above, the Lévy–Khinchin canonical representation determines the logarithm of the characteristic function of an infinitely-divisible distribution. For the weak convergence of the sequence of infinitely-divisible distributions determined by characteristics $\gamma_n$, $G_n$, $n=1,2,\dots,$ to a distribution (which is necessarily infinitely divisible) with characteristics $\gamma$ and $G$ it is necessary and sufficient that $\lim\gamma_n=\gamma$ and that the $G_n$ converge weakly to $G$ as $n\to\infty$.
For references see Lévy canonical representation.
Comments
For the notion of weak convergence see Distributions, convergence of.
How to Cite This Entry:
Lévy-Khinchin canonical representation. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=L%C3%A9vy-Khinchin_canonical_representation&oldid=33523
Lévy-Khinchin canonical representation. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=L%C3%A9vy-Khinchin_canonical_representation&oldid=33523
This article was adapted from an original article by B.A. Rogozin (originator), which appeared in Encyclopedia of Mathematics - ISBN 1402006098. See original article