skellam distribution

   kurtosis   = $1/(\mu_1+\mu_2)$ |   entropy    =|   mgf        = $e^{-(\mu_1+\mu_2)+\mu_1e^t+\mu_2e^{-t}}$ |   char       = $e^{-(\mu_1+\mu_2)+\mu_1e^{it}+\mu_2e^{-it}}$

}} The Skellam distribution is the discrete probability distribution of the difference N₁ − N₂ of two correlated or uncorrelated random variables N₁ and N₂ having Poisson distributions with different expected values μ₁ and μ₂. It is useful in describing the statistics of the difference of two images with simple photon noise, as well as describing the point spread distribution in certain sports where all scored points are equal, such as baseball, hockey and soccer. Only the case of uncorrelated variables will be considered in this article. See Karlis & Ntzoufras, 2003 for the use of the Skellam distribution to describe the difference of correlated Poisson-distributed variables. Recall that probability mass function of a Poisson distribution with mean μ is given by

  P_n(\mu)={\mu^n\over n!}e^{-\mu}.

(Skellam, 1946). The Skellam probability mass function is:

   P_n(\mu_1,\mu_2)=\sum_{k=-\infty}^\infty   P_{n+k}(\mu_1)P_k(\mu_2)

   =e^{-(\mu_1+\mu_2)}\sum_{k=-\infty}^\infty

   = e^{-(\mu_1+\mu_2)}   \left({\mu_1\over\mu_2}\right)^{n/2}I_n(2\sqrt{\mu_1\mu_2})

where I _n(z) is the modified Bessel function of the first kind. The above formulas have assumed that any term with a negative factorial is set to zero. The special case for μ₁ = μ₂ is given by (Irwin, 1937):

   P_n\left(\mu,\mu\right) = e^{-2\mu}I_n(2\mu)

Note also that, using the limiting values of the Bessel function for small arguments, we can recover the Poisson distribution as a special case of the Skellam distribution for μ₂=0.

Properties

The Skellam probability mass function is of course normalized:

   \sum_{k=-\infty}^\infty P_k(\mu_1,\mu_2)=1.

We know that the generating function for a Poisson distribution is:

   G\left(t,\mu\right)= e^{\mu(t-1)}.

It follows that the generating function G(t,μ₁,μ₂) for a Skellam probability function will be:

G(t,\mu_1,\mu_2) = \sum_{k=0}^\infty P_k(\mu_1,\mu_2)t^k

= G\left(t,\mu_1\right)G\left(1/t,\mu_2\right)\,

= e^{-(\mu_1+\mu_2)+\mu_1 t+\mu_2/t}.

Notice that the form of the generating function implies that the distribution of the sums or the differences or, in fact, any linear combination of two Skellam-distributed variables are again Skellam-distributed. The moment-generating function is given by:

M\left(t,\mu_1,\mu_2\right) = G(e^t,\mu_1,\mu_2)

= \sum_{k=0}^\infty { t^k \over k!}\,m_k

which yields the raw moments m_k. Define:

\Delta\equiv\mu_1-\mu_2\,

\mu\equiv (\mu_1+\mu_2)/2.\,

Then the raw moments m_k are

m_1=\left.\Delta\right.\,

m_2=\left.2\mu+\Delta^2\right.\,

m_3=\left.\Delta(1+6\mu+\Delta^2)\right.\,

The central moments M_k are

M_2=\left.2\mu\right.,\,

M_3=\left.\Delta\right.,\,

M_4=\left.2\mu+12\mu^2\right..\,

The mean, variance, skewness, and kurtosis excess are respectively:

\left.\right.E(n)=\Delta\,

\sigma^2=\left.2\mu\right.\,

\gamma_1=\left.\Delta/(2\mu)^{3/2}\right.\,

\gamma_2=\left.1/2\mu\right..\,

The cumulant-generating function is given by:

   K(t,\mu_1,\mu_2)\equiv \ln(M(t,\mu_1,\mu_2))   = \sum_{k=0}^\infty { t^k \over k!}\,\kappa_k

which yields the cumulants:

\kappa_{2k}=\left.2\mu\right.

\kappa_{2k+1}=\left.\Delta\right. .

For the special case when μ₁ = μ₂, an asymptotic expansion of the modified Bessel function of the first kind yields for large μ:

   P_n(\mu,\mu)\sim   {1\over\sqrt{4\pi\mu}}\left (-1)^k{\{4n^2-1^2\}\{4n^2-3^2\}\cdots\{4n^2-(2k-1)^2\}    \over k!\,2^{3k}\,(2\mu)^k}\right    
  (Abramowitz & Stegun 1972, p. 377). Also, for this special case, when n is also large, and of order of the square root of 2μ, the distribution tends to a normal distribution:    
 
    P_n(\mu,\mu)\sim   {e^{-n^2/4\mu}\over\sqrt{4\pi\mu}}.    
  These special results can easily be extended to the more general case of different means.  References
   Abramowitz, M. and Stegun, I. A. (Eds.). 1972. Modified Bessel functions I and K.  Sections 9.6–9.7 in Handbook of Mathematical Functions with Formulas, Graphs, and Mathematical Tables, 9th printing, pp. 374–378. New York: Dover.
 
   Irwin, J. O. 1937. The frequency distribution of the difference between two independent variates following the same Poisson distribution. Journal of the Royal Statistical Society: Series A 100 (3): 415–416.
 
   Karlis, D. and Ntzoufras, I. 2003. Analysis of sports data using bivariate Poisson models. Journal of the Royal Statistical Society: Series D (The Statistician) 52 (3): 381–393. doi:10.1111/1467-9884.00366
 
   Karlis, D. and Ntzoufras, J. Bayesian analysis of paired count data.  Unpublished manuscript. http://www.ba.aegean.gr/ntzoufras/papers/11_poisdif.pdf
 
   Skellam, J. G. 1946. The frequency distribution of the difference between two Poisson variates belonging to different populations. Journal of the Royal Statistical Society: Series A 109 (3): 296.
 

 

  
 

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