Gumbel distribution - Misplaced Pages

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Gumbel
Probability density function
Cumulative distribution function
Parameters	$\mu \!$ location (real) $\beta >0\!$ scale (real)
Support	$x\in (-\infty ;+\infty )\!$
PDF	${\frac {1}{\beta }}e^{-z-e^{-z}}\!$ where $z={\frac {x-\mu }{\beta }}\!$
CDF	$\exp(-e^{-(x-\mu )/\beta })\!$
Mean	$\mu +\beta \,\gamma \!$
Median	$\mu -\beta \,\ln(\ln(2))\!$
Mode	$\mu \!$
Variance	${\frac {\pi ^{2}}{6}}\,\beta ^{2}\!$
Skewness	${\frac {12{\sqrt {6}}\,\zeta (3)}{\pi ^{3}}}\approx 1.14\!$
Excess kurtosis	${\frac {12}{5}}$
Entropy	$\ln(\beta )+\gamma +1\!$
MGF	$\Gamma (1-\beta \,t)\,e^{\mu \,t}\!$
CF	$\Gamma (1-i\,\beta \,t)\,e^{i\,\mu \,t}\!$

In probability theory and statistics, the Gumbel distribution is used to model the distribution of the maximum (or the minimum) of a number of samples of various distributions. Such a distribution might be used to represent the distribution of the maximum level of a river in a particular year if there was a list of maximum values for the past ten years. It is useful in predicting the chance that an extreme earthquake, flood or other natural disaster will occur.

The potential applicability of the Gumbel distribution to represent the distribution of maxima relates to extreme value theory which indicates that it is likely to be useful if the distribution of the underlying sample data is of the normal or exponential type.

The Gumbel distribution is a particular case of the generalized extreme value distribution (also known as the Fisher-Tippett distribution). It is also known as the log-Weibull distribution and the double exponential distribution (which is sometimes used to refer to the Laplace distribution). It is often incorrectly labelled as Gompertz distribution.

The Gumbel distribution is named after Emil Julius Gumbel (1891–1966)).

Properties

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The cumulative distribution function of the Gumbel distribution is

F(x;\mu ,\beta )=e^{-e^{-(x-\mu )/\beta }}.\,

The mode is μ, while the median is $\mu -\beta \ln \left(\ln 2\right),$ and the mean is given by

\operatorname {E} (X)=\mu +\gamma \beta ,

where $\gamma$ = Euler–Mascheroni constant $\approx$ 0.5772.

The standard deviation is

\beta \pi /{\sqrt {6}}.\,

Standard Gumbel distribution

The standard Gumbel distribution is the case where μ = 0 and β = 1 with cumulative distribution function

F(x)=e^{-e^{(-x)}}\,

and probability density function

f(x)=e^{-x}e^{-e^{-x}}.

In this case mode is 0, the median is $-\ln(\ln(2))\approx$ 0.3665 and the mean is $\gamma$ , where this is defined above. The standard deviation is

\pi /{\sqrt {6}}\approx

1.2825.

Generating Gumbel variates

Given a random variate U drawn from the uniform distribution in the interval , the variate

X=\mu -\beta \ln(-\ln(U))\,

has a Gumbel distribution with parameters μ and β. This follows from the form of the cumulative distribution function given above.

Related distributions

When the cdf of Y is the converse of the Gumbel standard cumulative distribution, $P(Y\leq y)=1-F(y)$ , then Y has a Gompertz distribution.

Application

Fitted cumulative Gumbel distribution to maximum one-day October rainfalls

Gumbel has shown that the maximum value (or first order statistic) in a sample of a random variable following an exponential distribution approaches the Gumbel distribution closer with increasing sample size.

In hydrology, therefore, the Gumbel distribution is used to analyze such variables as monthly and annual maximum values of daily rainfall and river discharge volumes, and also to descibe droughts.

Gumbel has also shown that the estimator r / (n+1) for the probability of an event - where r is the rank number of the observed value in the data series and n is the total number of observations - is an unbiased estimator of the cumulative probability around the mode of the distribution. Therefore, this estimator is often used as a plotting position.

The blue picture illustrates an example of fitting the Gumbel distribution to ranked maximum one-day October rainfalls showing also the 90% confidence belt based on the binomial distribution. The rainfall data are represented by the plotting position r / (n+1) as part of the cumulative frequency analysis.

References

Willemse, W. J. and Kaas, R., "Rational reconstruction of frailty-based mortality models by a generalisation of Gompertz’ law of mortality", Insurance: Mathematics and Economics, 40 (3) (2007), 468–484.
Gumbel, E.J. 1954. "Statistical theory of extreme values and some practical applications". Applied Mathematics Series, 33. U.S. Department of Commerce, National Bureau of Standards.
Ritzema (ed.), H.P. (1994). Frequency and Regression Analysis (PDF). Chapter 6 in: Drainage Principles and Applications, Publication 16, International Institute for Land Reclamation and Improvement (ILRI), Wageningen, The Netherlands. pp. 175–224. ISBN 90 70754 3 39. {{cite book}}: |last= has generic name (help)
Burke, E.J.; Perry R.H.J.; Brown, S.J. (2010) "An extreme value analysis of UK drought and projections of change in the future", Journal of Hydrology

Probability distributions (list)

Discrete
univariate

with finite support	Benford Bernoulli Beta-binomial Binomial Categorical Hypergeometric Negative Poisson binomial Rademacher Soliton Discrete uniform Zipf Zipf–Mandelbrot
with infinite support	Beta negative binomial Borel Conway–Maxwell–Poisson Discrete phase-type Delaporte Extended negative binomial Flory–Schulz Gauss–Kuzmin Geometric Logarithmic Mixed Poisson Negative binomial Panjer Parabolic fractal Poisson Skellam Yule–Simon Zeta

Continuous
univariate

supported on a bounded interval	Arcsine ARGUS Balding–Nichols Bates Beta Generalized Beta rectangular Continuous Bernoulli Irwin–Hall Kumaraswamy Logit-normal Noncentral beta PERT Raised cosine Reciprocal Triangular U-quadratic Uniform Wigner semicircle
supported on a semi-infinite interval	Benini Benktander 1st kind Benktander 2nd kind Beta prime Burr Chi Chi-squared Noncentral Inverse Scaled Dagum Davis Erlang Hyper Exponential Hyperexponential Hypoexponential Logarithmic F Noncentral Folded normal Fréchet Gamma Generalized Inverse gamma/Gompertz Gompertz Shifted Half-logistic Half-normal Hotelling's T-squared Inverse Gaussian Generalized Kolmogorov Lévy Log-Cauchy Log-Laplace Log-logistic Log-normal Log-t Lomax Matrix-exponential Maxwell–Boltzmann Maxwell–Jüttner Mittag-Leffler Nakagami Pareto Phase-type Poly-Weibull Rayleigh Relativistic Breit–Wigner Rice Truncated normal type-2 Gumbel Weibull Discrete Wilks's lambda
supported on the whole real line	Cauchy Exponential power Fisher's z Kaniadakis κ-Gaussian Gaussian q Generalized normal Generalized hyperbolic Geometric stable Gumbel Holtsmark Hyperbolic secant Johnson's S_U Landau Laplace Asymmetric Logistic Noncentral t Normal (Gaussian) Normal-inverse Gaussian Skew normal Slash Stable Student's t Tracy–Widom Variance-gamma Voigt
with support whose type varies	Generalized chi-squared Generalized extreme value Generalized Pareto Marchenko–Pastur Kaniadakis κ-exponential Kaniadakis κ-Gamma Kaniadakis κ-Weibull Kaniadakis κ-Logistic Kaniadakis κ-Erlang q-exponential q-Gaussian q-Weibull Shifted log-logistic Tukey lambda