Density function, distribution function, quantile function, random generation,
raw moments and limited moments for the Inverse Weibull distribution
with parameters shape and scale.
dinvweibull(x, shape, rate = 1, scale = 1/rate, log = FALSE)
pinvweibull(q, shape, rate = 1, scale = 1/rate,
lower.tail = TRUE, log.p = FALSE)
qinvweibull(p, shape, rate = 1, scale = 1/rate,
lower.tail = TRUE, log.p = FALSE)
rinvweibull(n, shape, rate = 1, scale = 1/rate)
minvweibull(order, shape, rate = 1, scale = 1/rate)
levinvweibull(limit, shape, rate = 1, scale = 1/rate,
order = 1)vector of quantiles.
vector of probabilities.
number of observations. If length(n) > 1, the length is
taken to be the number required.
parameters. Must be strictly positive.
an alternative way to specify the scale.
logical; if TRUE, probabilities/densities
\(p\) are returned as \(\log(p)\).
logical; if TRUE (default), probabilities are
\(P[X \le x]\), otherwise, \(P[X > x]\).
order of the moment.
limit of the loss variable.
dinvweibull gives the density,
pinvweibull gives the distribution function,
qinvweibull gives the quantile function,
rinvweibull generates random deviates,
minvweibull gives the \(k\)th raw moment, and
levinvweibull gives the \(k\)th moment of the limited loss
variable.
Invalid arguments will result in return value NaN, with a warning.
The inverse Weibull distribution with parameters shape \(=
\tau\) and scale \(= \theta\) has density:
$$f(x) = \frac{\tau (\theta/x)^\tau e^{-(\theta/x)^\tau}}{x}$$
for \(x > 0\), \(\tau > 0\) and \(\theta > 0\).
The special case shape == 1 is an
Inverse Exponential distribution.
The \(k\)th raw moment of the random variable \(X\) is \(E[X^k]\), \(k < \tau\), and the \(k\)th limited moment at some limit \(d\) is \(E[\min(X, d)^k]\), all \(k\).
Kleiber, C. and Kotz, S. (2003), Statistical Size Distributions in Economics and Actuarial Sciences, Wiley.
Klugman, S. A., Panjer, H. H. and Willmot, G. E. (2012), Loss Models, From Data to Decisions, Fourth Edition, Wiley.
# NOT RUN {
exp(dinvweibull(2, 3, 4, log = TRUE))
p <- (1:10)/10
pinvweibull(qinvweibull(p, 2, 3), 2, 3)
mlgompertz(-1, 3, 3)
levinvweibull(10, 2, 3, order = 1)
# }
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