Exponential-logarithmic distribution

In probability theory and statistics, the Exponential-Logarithmic (EL) distribution is a family of lifetime distributions with decreasing failure rate, defined on the interval [0, ∞). This distribution is parameterized by two parameters and .

Exponential-Logarithmic distribution (EL)
Probability density function
Probability density function
Parameters
Support
PDF
CDF
Mean
Median
Mode 0
Variance
MGF

Introduction

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The study of lengths of the lives of organisms, devices, materials, etc., is of major importance in the biological and engineering sciences. In general, the lifetime of a device is expected to exhibit decreasing failure rate (DFR) when its behavior over time is characterized by 'work-hardening' (in engineering terms) or 'immunity' (in biological terms).

The exponential-logarithmic model, together with its various properties, are studied by Tahmasbi and Rezaei (2008).[1] This model is obtained under the concept of population heterogeneity (through the process of compounding).

Properties of the distribution

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Distribution

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The probability density function (pdf) of the EL distribution is given by Tahmasbi and Rezaei (2008)[1]

 

where   and  . This function is strictly decreasing in   and tends to zero as  . The EL distribution has its modal value of the density at x=0, given by

 

The EL reduces to the exponential distribution with rate parameter  , as  .

The cumulative distribution function is given by

 

and hence, the median is given by

 .

Moments

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The moment generating function of   can be determined from the pdf by direct integration and is given by

 

where   is a hypergeometric function. This function is also known as Barnes's extended hypergeometric function. The definition of   is

 

where   and  .

The moments of   can be derived from  . For  , the raw moments are given by

 

where   is the polylogarithm function which is defined as follows:[2]

 

Hence the mean and variance of the EL distribution are given, respectively, by

 
 

The survival, hazard and mean residual life functions

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Hazard function

The survival function (also known as the reliability function) and hazard function (also known as the failure rate function) of the EL distribution are given, respectively, by

 
 

The mean residual lifetime of the EL distribution is given by

 

where   is the dilogarithm function

Random number generation

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Let U be a random variate from the standard uniform distribution. Then the following transformation of U has the EL distribution with parameters p and β:

 

Estimation of the parameters

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To estimate the parameters, the EM algorithm is used. This method is discussed by Tahmasbi and Rezaei (2008).[1] The EM iteration is given by

 
 
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The EL distribution has been generalized to form the Weibull-logarithmic distribution.[3]

If X is defined to be the random variable which is the minimum of N independent realisations from an exponential distribution with rate parameter β, and if N is a realisation from a logarithmic distribution (where the parameter p in the usual parameterisation is replaced by (1 − p)), then X has the exponential-logarithmic distribution in the parameterisation used above.

References

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  1. ^ a b c Tahmasbi, R., Rezaei, S., (2008), "A two-parameter lifetime distribution with decreasing failure rate", Computational Statistics and Data Analysis, 52 (8), 3889-3901. doi:10.1016/j.csda.2007.12.002
  2. ^ Lewin, L. (1981) Polylogarithms and Associated Functions, North Holland, Amsterdam.
  3. ^ Ciumara, Roxana; Preda, Vasile (2009) "The Weibull-logarithmic distribution in lifetime analysis and its properties". In: L. Sakalauskas, C. Skiadas and E. K. Zavadskas (Eds.) Applied Stochastic Models and Data Analysis Archived 2011-05-18 at the Wayback Machine, The XIII International Conference, Selected papers. Vilnius, 2009 ISBN 978-9955-28-463-5