Free Poisson distribution

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In the mathematics of free probability theory, the free Poisson distribution is a counterpart of the Poisson distribution in conventional probability theory.

The free Poisson distribution^[1] with jump size ${\displaystyle \alpha }$ and rate ${\displaystyle \lambda }$ arises in free probability theory as the limit of repeated free convolution

${\displaystyle {((1-\frac{\lambda }{N}){\delta }_0+\frac{\lambda }{N}{\delta }_{\alpha })}^{⊞N}}$

as N → ∞.

In other words, let ${\displaystyle X_N}$ be random variables so that ${\displaystyle X_N}$ has value ${\displaystyle \alpha }$ with probability ${\displaystyle \frac{\lambda }{N}}$ and value 0 with the remaining probability. Assume also that the family ${\displaystyle X_1,X_2,\dots }$ are freely independent. Then the limit as ${\displaystyle N\to \mathrm{\infty }}$ of the law of ${\displaystyle X_1+\cdots +X_N}$ is given by the Free Poisson law with parameters ${\displaystyle \lambda ,\alpha }$.

This definition is analogous to one of the ways in which the classical Poisson distribution is obtained from a (classical) Poisson process.

The measure associated to the free Poisson law is given by^[2]

${\displaystyle \mu =\{\begin{array}{ll}(1-\lambda ){\delta }_0+\nu ,& \text{if }0\le \lambda \le 1\\ \nu ,& \text{if }\lambda >1,\end{array}}$

where

${\displaystyle \nu =\frac{1}{2\pi \alpha t}\sqrt{4\lambda {\alpha }^2-(t-\alpha (1+\lambda ){)}^2}dt}$

and has support ${\displaystyle [\alpha (1-\sqrt{\lambda }{)}^2,\alpha (1+\sqrt{\lambda }{)}^2]}$.

This law also arises in random matrix theory as the Marchenko–Pastur law. Its free cumulants are equal to ${\displaystyle {\kappa }_n=\lambda {\alpha }^n}$.

We give values of some important transforms of the free Poisson law; the computation can be found in e.g. in the book Lectures on the Combinatorics of Free Probability by A. Nica and R. Speicher^[3]

The R-transform of the free Poisson law is given by

${\displaystyle R(z)=\frac{\lambda \alpha }{1-\alpha z}.}$

The Cauchy transform (which is the negative of the Stieltjes transformation) is given by

${\displaystyle G(z)=\frac{z+\alpha -\lambda \alpha -\sqrt{(z-\alpha (1+\lambda ){)}^2-4\lambda {\alpha }^2}}{2\alpha z}}$

The S-transform is given by

${\displaystyle S(z)=\frac{1}{z+\lambda }}$

in the case that ${\displaystyle \alpha =1}$.

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