Weibull distribution
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}}},] if [k>1]| variance =[\lambda^2\Gamma\left(1+\frac\right) - \mu^2\,]| skewness =[\frac)\lambda^3-3\mu\sigma^2-\mu^3}]| kurtosis =(see text)| entropy =[\gamma\left(1\!-\!\frac\right)+\ln\left(\frac\right)+1]| mgf = see Weibull fading| char =| }}
In probability theory and statistics, the Weibull distribution (named after Waloddi Weibull) is a continuous probability distribution with the probability density function
- [f(x;k,\lambda) = \left(\right)^ e^\,]
The cumulative distribution function is
- [F(x;k,\lambda) = 1- e^\,]
The failure rate h (or hazard rate) is given by
- [ h(x;k,\lambda) = \left(\right)^.]
An understanding of the failure rate may provide insight as to what is causing the failures:
- A decreasing failure rate would suggest "infant mortality". That is, defective items fail early and the failure rate decreases over time as they fall out of the population.
- A constant failure rate suggests that items are failing from random events.
- An increasing failure rate suggests "wear out" - parts are more likely to fail as time goes on.
Properties
The nth raw moment is given by:
- [m_n = \lambda^n \Gamma(1+n/k)\,]
- [\textrm(X) = \lambda \Gamma(1+1/k)\,]
- [\textrm(X) = \lambda^2[Gamma(1+2/k) - Gamma^2(1+1/k)]\,]
- [\gamma_1=\frac\right)\lambda^3-3\mu\sigma^2-\mu^3}]
- [\gamma_2=\frac]
- [\gamma_2=\frac\right)-3\sigma^4-4\gamma_1\sigma^3\mu-6\sigma^2\mu^2-\mu^4}.]
Generating Weibull-distributed random variates
Given a random variate U drawn from the uniform distribution in the interval
- [X=\lambda (-\ln(U))^\,]
Related distributions
- [X \sim \mathrm(\lambda)] is an exponential distribution if [X \sim \mathrm(\gamma = 1, \lambda^)].
- [X \sim \mathrm(\beta)] is a Rayleigh distribution if [X \sim \mathrm(\gamma = 2, \sqrt \beta)].
- [\lambda(-\ln(X))^\,] is a Weibull distribution if [X \sim \mathrm(0,1)].
- See also the generalized extreme value distribution.
Uses
The Weibull distribution is most commonly used in life data analysis, though it has found other applications as well. The Weibull distribution is often used in place of the normal distribution due to the fact that a Weibull variate can be generated through inversion, while normal variates are typically generated using the more complicated Box-Muller method, which requires two uniform random variates. Weibull distributions may also be used to represent manufacturing and delivery times in industrial engineering problems, while it is very important in extreme value theory and weather forecasting. It is also a very popular statistical model in reliability engineering and failure analysis, while it is widely applied in radar systems to model the dispersion of the received signals level produced by some types of clutters. Furthermore, concerning wireless communications, the Weibull distribution may be used for fading channel modelling, since the Weibull fading model seems to exhibit good fit to experimental fading channel measurements. The Weibull distribution is also commonly used to describe wind speed distributions as the natural distribution often matches the Weibull shape.External links
- [The Weibull distribution (with examples, properties, and calculators).]
- [The Weibull plot.]
- [Weibull plotting paper.]
- [Using Excel for Weibull Analysis]
This article from the Quality Digest describes how to use MS Excel to analyse lifetest data with the Weibull statistical distribution. Although Excel doesn't have an inverse Weibull function, this article shows how to use Excel to solve for critical values.
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