Gompertz distribution explained

In probability and statistics, the Gompertz distribution is a continuous probability distribution, named after Benjamin Gompertz. The Gompertz distribution is often applied to describe the distribution of adult lifespans by demographers and actuaries. Related fields of science such as biology and gerontology also considered the Gompertz distribution for the analysis of survival. More recently, computer scientists have also started to model the failure rates of computer code by the Gompertz distribution. In Marketing Science, it has been used as an individual-level simulation for customer lifetime value modeling. In network theory, particularly the Erdős–Rényi model, the walk length of a random self-avoiding walk (SAW) is distributed according to the Gompertz distribution.^[1]

Specification

Probability density function

The probability density function of the Gompertz distribution is:

f\left(x;η,b\right)=bη\exp\left(η+bx-ηe^bx\right)forx\geq0,

where

b>0

is the scale parameter and

η>0

is the shape parameter of the Gompertz distribution. In the actuarial and biological sciences and in demography, the Gompertz distribution is parametrized slightly differently (Gompertz–Makeham law of mortality).

Cumulative distribution function

The cumulative distribution function of the Gompertz distribution is:

F\left(x;η,b\right)=1-\exp\left(-η\left(e^bx-1\right)\right),

where

η,b>0,

and

x\geq0.

Moment generating function

The moment generating function is:

E\left(e^-t\right)=ηe^ηE_t/b\left(η\right)

where

E_t/b

	infin
\left(η\right)=\int
	1

e^-ηv^-t/bdv, t>0.

Properties

h(x)=ηbe^bx

is a convex function of

F\left(x;η,b\right)

. The model can be fitted into the innovation-imitation paradigm with

p=ηb

as the coefficient of innovation and

as the coefficient of imitation. When

becomes large,

z(t)

approaches

infty

. The model can also belong to the propensity-to-adopt paradigm with

as the propensity to adopt and

as the overall appeal of the new offering.

Shapes

The Gompertz density function can take on different shapes depending on the values of the shape parameter

When

η\geq1,

the probability density function has its mode at 0.

When

0<η<1,

the probability density function has its mode at

x^{*=\left(1/b\right)ln}\left(1/η\right)with0<F\left(x^*\right)<1-e^-1=0.632121

Kullback-Leibler divergence

f₁

and

f₂

are the probability density functions of two Gompertz distributions, then their Kullback-Leibler divergence is given by

\begin{align} D_KL(f₁\parallelf₂₎&=

	infty
\int
	0

f_1(x;b_1,η₁₎ln

	f_1(x;b_1,η₁₎
	f_2(x;b_2,η₂₎

dx\\ &=ln

	η₁
e		b₁η₁

	η₂
e		b₂η₂

	η₁
e

\left[\left(

	b₂
	b₁

-1\right)\operatorname{Ei}(-η_1)
+

η₂

	b₂
	b₁

\Gamma\left(

	b₂
	b₁

+1,η₁\right)\right] -(η₁+1) \end{align}

where

\operatorname{Ei}( ⋅ )

denotes the exponential integral and

\Gamma( ⋅ , ⋅ )

is the upper incomplete gamma function.^[2]

Related distributions

If X is defined to be the result of sampling from a Gumbel distribution until a negative value Y is produced, and setting X=-Y, then X has a Gompertz distribution.
The gamma distribution is a natural conjugate prior to a Gompertz likelihood with known scale parameter

When

varies according to a gamma distribution with shape parameter

\alpha

and scale parameter

\beta

(mean =

\alpha/\beta

), the distribution of

is Gamma/Gompertz.

Y\simGompertz

, then

X=\exp(Y)\simWeibull^-1

, and hence

\exp(-Y)\simWeibull

.^[3]

Applications

In hydrology the Gompertz distribution is applied to extreme events such as annual maximum one-day rainfalls and river discharges. The blue picture illustrates an example of fitting the Gompertz distribution to ranked annually maximum one-day rainfalls showing also the 90% confidence belt based on the binomial distribution. The rainfall data are represented by plotting positions as part of the cumulative frequency analysis.

References

Web site: Bemmaor. Albert C.. Glady. Nicolas. 2011. Implementing the Gamma/Gompertz/NBD Model in MATLAB. ESSEC Business School. Cergy-Pontoise.
Gompertz . B. . Benjamin Gompertz . 1825 . 513–583. On the Nature of the Function Expressive of the Law of Human Mortality, and on a New Mode of Determining the Value of Life Contingencies . Philosophical Transactions of the Royal Society of London. 115 . 107756 . 10.1098/rstl.1825.0026. 145157003 . free .
Book: Johnson . Norman L. . Kotz . Samuel . Balakrishnan . N. . 1995 . Continuous Univariate Distributions . 2 . 2nd . John Wiley & Sons . New York . 0-471-58494-0 . 25 - 26.
Sheikh. A. K.. Boah, J. K. . Younas, M. . Truncated Extreme Value Model for Pipeline Reliability. Reliability Engineering and System Safety. 1989. 25. 1. 1–14 . 10.1016/0951-8320(89)90020-3.

Notes and References

Tishby, Biham, Katzav (2016), The distribution of path lengths of self avoiding walks on Erdős-Rényi networks, .
Bauckhage, C. (2014), Characterizations and Kullback-Leibler Divergence of Gompertz Distributions, .
Book: Kleiber. Christian. Kotz. Samuel. 2003. Statistical Size Distributions in Economics and Actuarial Sciences. Wiley. 179. 9780471150640. 10.1002/0471457175.

Gompertz distribution explained

Specification

Probability density function

Cumulative distribution function

Moment generating function

Properties

Shapes

Kullback-Leibler divergence

Related distributions

Applications

See also

References

Notes and References