Heavy-tailed distribution

In probability theory, heavy-tailed distributions are probability distributions whose tails are not exponentially bounded:[1] that is, they have heavier tails than the exponential distribution. In many applications it is the right tail of the distribution that is of interest, but a distribution may have a heavy left tail, or both tails may be heavy.

There are two important subclasses of heavy-tailed distributions, the long-tailed distributions and the subexponential distributions. In practice, all commonly used heavy-tailed distributions belong to the subexponential class.

There is still some discrepancy over the use of the term heavy-tailed. There are two other definitions in use. Some authors use the term to refer to those distributions which do not have all their power moments finite; and some others to those distributions that do not have a variance. The definition given in this article is the most general in use, and includes all distributions encompassed by the alternative definitions, as well as those distributions such as log-normal that possess all their power moments, yet which are generally acknowledged to be heavy-tailed. (Occasionally, heavy-tailed is used for any distribution that has heavier tails than the normal distribution.)

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Definition of heavy-tailed distribution

The distribution of a random variable X with distribution function F is said to have a heavy right tail if[1]


\lim_{x \to \infty} e^{\lambda x}\Pr[X>x] = \infty \quad \mbox{for all } \lambda>0.\,

This is also written in terms of the tail distribution function

\overline{F}(x) \equiv \Pr(X>x) \,

as


\lim_{x \to \infty} e^{\lambda x}\overline{F}(x) = \infty \quad \mbox{for all } \lambda>0.\,

This is equivalent to the statement that the moment generating function of F, MF(t), is infinite for all t > 0[2].

The definitions of heavy-tailed for left-tailed or two tailed distributions are similar.

Definition of long-tailed distribution

The distribution of a random variable X with distribution function F is said to have a long right tail[1] if for all t > 0,


\lim_{x \to \infty} \Pr[X>x%2Bt|X>x] =1, \,

or equivalently


\overline{F}(x%2Bt) \sim \overline{F}(x) \quad \mbox{as } x \to \infty. \,

This has the intuitive interpretation for a right-tailed long-tailed distributed quantity that if the long-tailed quantity exceeds some high level, the probability approaches 1 that it will exceed any other higher level: if you know the situation is bad, it is probably worse than you think.

All long-tailed distributions are heavy-tailed, but the converse is false, and it is possible to construct heavy-tailed distributions that are not long-tailed.

Subexponential distributions

Subexponentiality is defined in terms of convolutions of probability distributions. For two independent, identically distributed random variables  X_1,X_2 with common distribution function F the convolution of F with itself, F^{*2} is defined, using Lebesgue-Stieltjes integration, by:


\Pr(X_1%2BX_2 \leq x) = F^{*2}(x) = \int_{- \infty}^{\infty} F(x-y)\,dF(y).

The n-fold convolution F^{*n} is defined in the same way. The tail distribution function \overline{F} is defined as \overline{F}(x) = 1-F(x).

A distribution F on the positive half-line is subexponential[1] if


\overline{F^{*2}}(x) \sim 2\overline{F}(x) \quad \mbox{as } x \to \infty.

This implies[3] that, for any n \geq 1,


\overline{F^{*n}}(x) \sim n\overline{F}(x) \quad \mbox{as } x \to \infty.

The probabilistic interpretation[3] of this is that, for a sum of n independent random variables X_1,\ldots,X_n with common distribution F,


\Pr(X_1%2B \cdots X_n>x) \sim \Pr(\max(X_1, \ldots,X_n)>x) \quad \mbox{as } x \to \infty.

This is often known as the principle of the single big jump[4].

A distribution F on the whole real line is subexponential if the distribution F I([0,\infty)) is[5]. Here I([0,\infty)) is the indicator function of the positive half-line. Alternatively, a random variable X supported on the real line is subexponential if and only if X^%2B = \max(0,X) is subexponential.

All subexponential distributions are long-tailed, but examples can be constructed of long-tailed distributions that are not subexponential.

Common heavy-tailed distributions

All commonly used heavy-tailed distributions are subexponential.[3]

Those that are one-tailed include:

Those that are two-tailed include:

See also

References

  1. ^ a b c d Asmussen, Søren (2003). Applied probability and queues. Berlin: Springer. ISBN 9780387002118. 
  2. ^ Rolski, Schmidli, Scmidt, Teugels, Stochastic Processes for Insurance and Finance, 1999
  3. ^ a b c Embrechts, Paul; Claudia Klüppelberg; Mikosch, Thomas (1997). Modelling Extremal Events for Insurance and Finance. Berlin: Springer. ISBN 9783540609315. 
  4. ^ Foss, Konstantopolous, Zachary, "Discrete and continuous time modulated random walks with heavy-tailed increments", Journal of Theoretical Probability, 20 (2007), No.3, 581—612
  5. ^ Willekens, E. Subexponentiality on the real line. Technical Report, K.U. Leuven(1986)
  6. ^ Falk, M., Hüsler, J. & Reiss, R. (2010). "Laws of Small Numbers: Extremes and Rare Events". Springer. p. 80. ISBN 9783034800082. 
  7. ^ Alves, M.I.F., de Haan, L. & Neves, C. (March 10, 2006). "Statistical inference for heavy and super-heavy tailed distributions". http://docentes.deio.fc.ul.pt/fragaalves/SuperHeavy.pdf. 
  8. ^ John P. Nolan (2009). "Stable Distributions: Models for Heavy Tailed Data" (PDF). http://academic2.american.edu/~jpnolan/stable/chap1.pdf. Retrieved 2009-02-21. 
  9. ^ Stephen Lihn (2009). "Skew Lognormal Cascade Distribution". http://www.skew-lognormal-cascade-distribution.org/.