This is an old revision of this page, as edited by Ichbin4(talk | contribs) at 10:51, 29 December 2020(Correct excess box kurtosis to actually give excess rather than entire kurtosis. (These differ by 3 for all distributions.) This is confusing because the property name is "kurtosis" but it is displayed to the viewer as "ex. kurtosis", and it is in fact excess kurtosis that is given for all other distributions.). The present address (URL) is a permanent link to this revision, which may differ significantly from the current revision.
Revision as of 10:51, 29 December 2020 by Ichbin4(talk | contribs)(Correct excess box kurtosis to actually give excess rather than entire kurtosis. (These differ by 3 for all distributions.) This is confusing because the property name is "kurtosis" but it is displayed to the viewer as "ex. kurtosis", and it is in fact excess kurtosis that is given for all other distributions.)
Examples of the probability mass function for the Skellam distribution. The horizontal axis is the index k. (The function is only defined at integer values of k. The connecting lines do not indicate continuity.)
The distribution is also applicable to a special case of the difference of dependent Poisson random variables, but just the obvious case where the two variables have a common additive random contribution which is cancelled by the differencing: see Karlis & Ntzoufras (2003) for details and an application.
The probability mass function for the Skellam distribution for a difference between two independent Poisson-distributed random variables with means and is given by:
where Ik(z) is the modified Bessel function of the first kind. Since k is an integer we have that Ik(z)=I|k|(z).
for (and zero otherwise). The Skellam probability mass function for the difference of two independent counts is the convolution of two Poisson distributions: (Skellam, 1946)
Since the Poisson distribution is zero for negative values of the count , the second sum is only taken for those terms where and . It can be shown that the above sum implies that
so that:
where Ik(z) is the modified Bessel function of the first kind. The special case for is given by Irwin (1937):
Using the limiting values of the modified Bessel function for small arguments, we can recover the Poisson distribution as a special case of the Skellam distribution for .
Properties
As it is a discrete probability function, the Skellam probability mass function is normalized:
It follows that the pgf, , for a Skellam probability mass function will be:
Notice that the form of the probability-generating function implies that the distribution of the sums or the differences of any number of independent Skellam-distributed variables are again Skellam-distributed. It is sometimes claimed that any linear combination of two Skellam distributed variables are again Skellam-distributed, but this is clearly not true since any multiplier other than would change the support of the distribution and alter the pattern of moments in a way that no Skellam distribution can satisfy.
(Abramowitz & Stegun 1972, p. 377). Also, for this special case, when k is also large, and of order of the square root of 2μ, the distribution tends to a normal distribution:
These special results can easily be extended to the more general case of different means.
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. JSTOR2980526
Karlis, D. and Ntzoufras, I. (2003) "Analysis of sports data using bivariate Poisson models". Journal of the Royal Statistical Society, Series D, 52 (3), 381–393. doi:10.1111/1467-9884.00366
Karlis D. and Ntzoufras I. (2006). Bayesian analysis of the differences of count data. Statistics in Medicine, 25, 1885–1905. [1]
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. JSTOR2981372