Discrete-stable distribution

The discrete-stable distributions^[1] are a class of probability distributions with the property that the sum of several random variables from such a distribution under appropriate scaling is distributed according to the same family. They are the discrete analogue of the continuous-stable distributions.

The discrete-stable distributions have been used in numerous fields, in particular in scale-free networks such as the internet, social networks^[2] or even semantic networks.^[3]

Both the discrete and continuous classes of stable distribution have properties such as infinite divisibility, power law tails and unimodality.

The most well-known discrete stable distribution is the Poisson distribution which is a special case.^[4] It is the only discrete-stable distribution for which the mean and all higher-order moments are finite.^{[dubious ]}

Definition

The discrete-stable distributions are defined^[5] through their probability-generating function

${\displaystyle G(s|\nu ,a)=\sum _{n=0}^{\infty }P(N|\nu ,a)(1-s)^{N}=\exp(-as^{\nu }).}$ 

In the above, ${\displaystyle a>0}$  is a scale parameter and ${\displaystyle 0<\nu \leq 1}$  describes the power-law behaviour such that when ${\displaystyle 0<\nu <1}$ ,

${\displaystyle \lim _{N\to \infty }P(N|\nu ,a)\sim {\frac {1}{N^{\nu +1}}}.}$ 

When ${\displaystyle \nu =1}$  the distribution becomes the familiar Poisson distribution with mean ${\displaystyle a}$ .

The characteristic function of a discrete-stable distribution has the form:^[6]

${\displaystyle \varphi (t;a,\nu )=\exp \left[a\left(e^{it}-1\right)^{\nu }\right]}$ , with ${\displaystyle a>0}$  and ${\displaystyle 0<\nu \leq 1}$ .

Again, when ${\displaystyle \nu =1}$  the distribution becomes the Poisson distribution with mean ${\displaystyle a}$ .

The original distribution is recovered through repeated differentiation of the generating function:

${\displaystyle P(N|\nu ,a)=\left.{\frac {(-1)^{N}}{N!}}{\frac {d^{N}G(s|\nu ,a)}{ds^{N}}}\right|_{s=1}.}$ 

A closed-form expression using elementary functions for the probability distribution of the discrete-stable distributions is not known except for in the Poisson case, in which

${\displaystyle \!P(N|\nu =1,a)={\frac {a^{N}e^{-a}}{N!}}.}$ 

Expressions do exist, however, using special functions for the case ${\displaystyle \nu =1/2}$ ^[7] (in terms of Bessel functions) and ${\displaystyle \nu =1/3}$ ^[8] (in terms of hypergeometric functions).

As compound probability distributions

The entire class of discrete-stable distributions can be formed as Poisson compound probability distributions where the mean, ${\displaystyle \lambda }$ , of a Poisson distribution is defined as a random variable with a probability density function (PDF). When the PDF of the mean is a one-sided continuous-stable distribution with stability parameter ${\displaystyle 0<\alpha <1}$  and scale parameter ${\displaystyle c}$  the resultant distribution is^[9] discrete-stable with index ${\displaystyle \nu =\alpha }$  and scale parameter ${\displaystyle a=c\sec(\alpha \pi /2)}$ .

Formally, this is written:

${\displaystyle P(N|\alpha ,c\sec(\alpha \pi /2))=\int _{0}^{\infty }P(N|1,\lambda )p(\lambda ;\alpha ,1,c,0)\,d\lambda }$ 

where ${\displaystyle p(x;\alpha ,1,c,0)}$  is the pdf of a one-sided continuous-stable distribution with symmetry paramètre ${\displaystyle \beta =1}$  and location parameter ${\displaystyle \mu =0}$ .

A more general result^[8] states that forming a compound distribution from any discrete-stable distribution with index ${\displaystyle \nu }$  with a one-sided continuous-stable distribution with index ${\displaystyle \alpha }$  results in a discrete-stable distribution with index ${\displaystyle \nu \cdot \alpha }$ , reducing the power-law index of the original distribution by a factor of ${\displaystyle \alpha }$ .

In other words,

${\displaystyle P(N|\nu \cdot \alpha ,c\sec(\pi \alpha /2))=\int _{0}^{\infty }P(N|\alpha ,\lambda )p(\lambda ;\nu ,1,c,0)\,d\lambda .}$ 

In the Poisson limit

In the limit ${\displaystyle \nu \rightarrow 1}$ , the discrete-stable distributions behave^[9] like a Poisson distribution with mean ${\displaystyle a\sec(\nu \pi /2)}$  for small ${\displaystyle N}$ , however for ${\displaystyle N\gg 1}$ , the power-law tail dominates.

The convergence of i.i.d. random variates with power-law tails ${\displaystyle P(N)\sim 1/N^{1+\nu }}$  to a discrete-stable distribution is extraordinarily slow^[10] when ${\displaystyle \nu \approx 1}$  - the limit being the Poisson distribution when ${\displaystyle \nu >1}$  and ${\displaystyle P(N|\nu ,a)}$  when ${\displaystyle \nu \leq 1}$ .

See also

• Stable distribution
• Poisson distribution

References

1. Steutel, F. W.; van Harn, K. (1979). "Discrete Analogues of Self-Decomposability and Stability" (PDF). Annals of Probability. 7 (5): 893–899. doi:10.1214/aop/1176994950.
2. Barabási, Albert-László (2003). Linked: how everything is connected to everything else and what it means for business, science, and everyday life. New York, NY: Plum.
3. Steyvers, M.; Tenenbaum, J. B. (2005). "The Large-Scale Structure of Semantic Networks: Statistical Analyses and a Model of Semantic Growth". Cognitive Science. 29 (1): 41–78. arXiv:cond-mat/0110012. doi:10.1207/s15516709cog2901_3. PMID 21702767. S2CID 6000627.
4. Renshaw, Eric (2015-03-19). Stochastic Population Processes: Analysis, Approximations, Simulations. OUP Oxford. ISBN 978-0-19-106039-7.
5. Hopcraft, K. I.; Jakeman, E.; Matthews, J. O. (2002). "Generation and monitoring of a discrete stable random process". Journal of Physics A. 35 (49): L745–752. Bibcode:2002JPhA...35L.745H. doi:10.1088/0305-4470/35/49/101.
6. Slamova, Lenka; Klebanov, Lev. "Modeling financial returns by discrete stable distributions" (PDF). International Conference Mathematical Methods in Economics. Retrieved 2023-07-07.
7. Matthews, J. O.; Hopcraft, K. I.; Jakeman, E. (2003). "Generation and monitoring of discrete stable random processes using multiple immigration population models". Journal of Physics A. 36 (46): 11585–11603. Bibcode:2003JPhA...3611585M. doi:10.1088/0305-4470/36/46/004.
8. Lee, W.H. (2010). Continuous and discrete properties of stochastic processes (PhD thesis). The University of Nottingham.
9. Lee, W. H.; Hopcraft, K. I.; Jakeman, E. (2008). "Continuous and discrete stable processes". Physical Review E. 77 (1): 011109–1 to 011109–04. Bibcode:2008PhRvE..77a1109L. doi:10.1103/PhysRevE.77.011109. PMID 18351820.
10. Hopcraft, K. I.; Jakeman, E.; Matthews, J. O. (2004). "Discrete scale-free distributions and associated limit theorems". Journal of Physics A. 37 (48): L635–L642. Bibcode:2004JPhA...37L.635H. doi:10.1088/0305-4470/37/48/L01.

Further reading

• Feller, W. (1971) An Introduction to Probability Theory and Its Applications, Volume 2. Wiley. ISBN 0-471-25709-5
• Gnedenko, B. V.; Kolmogorov, A. N. (1954). Limit Distributions for Sums of Independent Random Variables. Addison-Wesley.
• Ibragimov, I.; Linnik, Yu (1971). Independent and Stationary Sequences of Random Variables. Wolters-Noordhoff Publishing Groningen, The Netherlands.