Draft:Linnik class

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Instructions · What links here · Linnik class (talk: + · bio) · (log) · Copyvios report · reFill · Citation Bot · (Search: Google, Wikipedia) · Submitted 15 days ago by Aannuuttaa (talk: D · +) · Last edited 12 days ago by The Boolean

The Linnik class $I_{0}$ is one of the central concepts in the arithmetic of probability distributions. Following Yuri Vladimirovich Linnik, denote by $I_{0}$ the class of distributions that have no indecomposable divisors. Examples of distributions belonging to the class $I_{0}$ include normal distributions (Cramér's theorem), Poisson distributions (Raikov's theorem), as well as their convolutions (Linnik's theorem). Let $\mu \in I_{0}$ . Then, according to Khinchin's second theorem, the distribution $\mu$ is infinitely divisible. Hence, by the Lévy formula, its characteristic function can be represented in the form

{\hat {\mu }}(s)=\exp \left\{i\beta s-\sigma s^{2}+\int \limits _{\mathbb {R} \backslash \{0\}}\left(e^{ixs}-1-{ixs \over 1+x^{2}}\right)dF(x)\right\},\quad \quad \quad (1)

where $\beta \in \mathbb {R}$ , $\sigma \geq 0$ , and $F$ is a Borel measure on $\mathbb {R} \setminus \{0\}$ satisfying the condition

\int \limits _{\mathbb {R} \backslash \{0\}}{x^{2} \over {1+x^{2}}}dF(x)<\infty .

The measure $F$ is called the Lévy spectral measure of the infinitely divisible distribution $\mu$ . The central problem in the arithmetic of probability distributions is to determine conditions on $\sigma$ and $F$ that are necessary and sufficient for an infinitely divisible distribution $\mu$ to belong to the class $I_{0}$ . Denote by ${\mathfrak {L}}$ the class of infinitely divisible distributions $\mu$ having the property that the Lévy spectral measure $F$ in (1) is discrete and concentrated on a set of the form

$\{\mu _{k1}\}_{k=-\infty }^{\infty }\cup \{\mu _{k2}\}_{k=-\infty }^{\infty },$

where $\mu _{k1}>0$ , $\mu _{k2}<0$ , and the numbers $\mu _{k+1,r}/\mu _{k,r}$ , $r=1,2$ , $k=0,\pm 1,\pm 2,\dots$ , are natural numbers different from 1.

Linnik's theorem on the class $I_{0}$

Let $\mu$ be an infinitely divisible distribution and suppose that in formula (1), $\sigma >0$ . If $\mu \in I_{0}$ , then $\mu \in {\mathfrak {L}}$ ^[1]. Note that there exist distributions belonging to the class ${\mathfrak {L}}$ but not to $I_{0}$ . A corresponding example was constructed in ^[2]. On the other hand, under the additional assumption of rapid decay of the quantity $\int \limits _{|x|>y}dF(x)$ as $y\rightarrow \infty$ , membership in the class ${\mathfrak {L}}$ implies membership in the class $I_{0}$ ^[3].

Membership in the class $I_{0}$ of generalized Poisson distributions

We present two results concerning membership in the class $I_{0}$ of a generalized Poisson distribution, i.e., an infinitely divisible distribution $\mu$ such that in (1), $\sigma =0$ and the Lévy spectral measure $F$ is completely finite.

Theorem 1^[4]. Suppose that in (1), $\sigma =0$ , the Lévy spectral measure $F$ is finite and concentrated on the interval $(a,b)$ , where $0<a<b\leq 2a$ . Then $\mu \in I_{0}$ .

Theorem 2^[5]. Suppose that in (1), $\sigma =0$ , the Lévy spectral measure $F$ is finite and concentrated on a set of independent points. Then $\mu \in I_{0}$ .

Properties of the class $I_{0}$ as a subset of the class of all infinitely divisible distributions

1. The class $I_{0}$ is dense (in the weak topology) in the class of all infinitely divisible distributions^[6].

2. Any infinitely divisible distribution can be represented as a finite or countable convolution of distributions belonging to the class $I_{0}$ ^[4].

References

↑ Linnik, Yu. V. General theorems on the decomposition of infinitely divisible laws. I // Theory of Probability and Its Applications. — 1958. — Vol. 3, No. 1. — P. 3–40.
↑ Goldberg, A. A.; Ostrovskii, I. V. Application of W. K. Hayman's theorem to a problem in the theory of decomposition of probability laws // Ukrainian Mathematical Journal. — 1967. — Vol. 19, No. 3. — P. 104–106.
↑ Linnik, Yu. V.; Ostrovskii, I. V. Decomposition of Random Variables and Vectors. — Moscow: Nauka, 1972.
1 2 Ostrovskii, I. V. On decompositions of infinitely divisible laws without a Gaussian component // Doklady Akademii Nauk SSSR. — 1965. — Vol. 161, No. 1. — P. 48–51.
↑ Cuppens, R. Ensembles indépendants et décomposition des fonctions caractéristiques // C. R. Acad. Sci. Paris, Série A-B. — 1971. — Vol. 272. — P. A1464–A1466.
↑ Ostrovskii, I. V. On certain classes of infinitely divisible laws // Izvestiya Akademii Nauk SSSR, Seriya Matematicheskaya. — 1970. — Vol. 34, No. 4. — P. 923–944.

[Linnik1958-1] Linnik, Yu. V. General theorems on the decomposition of infinitely divisible laws. I // Theory of Probability and Its Applications. — 1958. — Vol. 3, No. 1. — P. 3–40.

[GoldbergOstrovsky1967-2] Goldberg, A. A.; Ostrovskii, I. V. Application of W. K. Hayman's theorem to a problem in the theory of decomposition of probability laws // Ukrainian Mathematical Journal. — 1967. — Vol. 19, No. 3. — P. 104–106.

[LinnikOstrovsky1972-3] Linnik, Yu. V.; Ostrovskii, I. V. Decomposition of Random Variables and Vectors. — Moscow: Nauka, 1972.

[Ostrovsky1965-4] 1 2 Ostrovskii, I. V. On decompositions of infinitely divisible laws without a Gaussian component // Doklady Akademii Nauk SSSR. — 1965. — Vol. 161, No. 1. — P. 48–51.

[Cuppens1971-5] Cuppens, R. Ensembles indépendants et décomposition des fonctions caractéristiques // C. R. Acad. Sci. Paris, Série A-B. — 1971. — Vol. 272. — P. A1464–A1466.

[Ostrovsky1970-6] Ostrovskii, I. V. On certain classes of infinitely divisible laws // Izvestiya Akademii Nauk SSSR, Seriya Matematicheskaya. — 1970. — Vol. 34, No. 4. — P. 923–944.

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Draft:Linnik class

Linnik's theorem on the class I 0 {\displaystyle I_{0}}

Membership in the class I 0 {\displaystyle I_{0}} of generalized Poisson distributions

Properties of the class I 0 {\displaystyle I_{0}} as a subset of the class of all infinitely divisible distributions

References

Linnik's theorem on the class $I_{0}$

Membership in the class $I_{0}$ of generalized Poisson distributions

Properties of the class $I_{0}$ as a subset of the class of all infinitely divisible distributions