Kumaraswamy Weibull distribution

Description

Computes the pdf, cdf, value at risk and expected shortfall for the Kumaraswamy Weibull distribution due to Cordeiro et al. (2010) given by

\begin{array}{ll} &\displaystyle f (x) = \frac {a b \alpha x^{\alpha - 1}}{\sigma^\alpha} \exp \left[ -\left( \frac {x}{\sigma} \right)^{\alpha} \right] \left\{ 1 - \exp \left[ -\left( \frac {x}{\sigma} \right)^{\alpha} \right] \right\}^{a - 1} \left[ 1 - \left\{ 1 - \exp \left[ -\left( \frac {x}{\sigma} \right)^{\alpha} \right] \right\}^a \right]^{b - 1}, \\ &\displaystyle F (x) = 1 - \left[ 1 - \left\{ 1 - \exp \left[ -\left( \frac {x}{\sigma} \right)^{\alpha} \right] \right\}^a \right]^b, \\ &\displaystyle {\rm VaR}_p (X) = \sigma \left[ -\log \left\{ 1 - \left[ 1 - (1 - p)^{1 / b} \right]^{1 / a} \right\} \right]^{1 / \alpha}, \\ &\displaystyle {\rm ES}_p (X) = \frac {\sigma}{p} \int_0^p \left[ -\log \left\{ 1 - \left[ 1 - (1 - v)^{1 / b} \right]^{1 / a} \right\} \right]^{1 / \alpha} dv \end{array}

for x > 0, 0 < p < 1, a > 0, the first shape parameter, b > 0, the second shape parameter, \alpha > 0, the third shape parameter, and \sigma > 0, the scale parameter.

Usage

dkumweibull(x, a=1, b=1, alpha=1, sigma=1, log=FALSE)
pkumweibull(x, a=1, b=1, alpha=1, sigma=1, log.p=FALSE, lower.tail=TRUE)
varkumweibull(p, a=1, b=1, alpha=1, sigma=1, log.p=FALSE, lower.tail=TRUE)
eskumweibull(p, a=1, b=1, alpha=1, sigma=1)

Arguments

Value

An object of the same length as x, giving the pdf or cdf values computed at x or an object of the same length as p, giving the values at risk or expected shortfall computed at p.

Author(s)

Saralees Nadarajah

References

Stephen Chan, Saralees Nadarajah & Emmanuel Afuecheta (2016). An R Package for Value at Risk and Expected Shortfall, Communications in Statistics - Simulation and Computation, 45:9, 3416-3434, doi:10.1080/03610918.2014.944658

Examples

x=runif(10,min=0,max=1)
dkumweibull(x)
pkumweibull(x)
varkumweibull(x)
eskumweibull(x)