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Density, distribution function, quantile function and random generation for the Kumaraswamy distribution.
dkumar(x, shape1, shape2, log = FALSE)
pkumar(q, shape1, shape2, lower.tail = TRUE, log.p = FALSE)
qkumar(p, shape1, shape2, lower.tail = TRUE, log.p = FALSE)
rkumar(n, shape1, shape2)vector of quantiles.
vector of probabilities.
number of observations.
If length(n) > 1 then the length is taken to be the number required.
positive shape parameters.
Logical.
If log = TRUE then the logarithm of the density is returned.
dkumar gives the density,
pkumar gives the distribution function,
qkumar gives the quantile function, and
rkumar generates random deviates.
See kumar, the VGAM family function
for estimating the parameters,
for the formula of the probability density function and other details.
# NOT RUN {
shape1 <- 2; shape2 <- 2; nn <- 201; # shape1 <- shape2 <- 0.5;
x <- seq(-0.05, 1.05, len = nn)
plot(x, dkumar(x, shape1, shape2), type = "l", las = 1, ylim = c(0,1.5),
ylab = paste("fkumar(shape1 = ", shape1, ", shape2 = ", shape2, ")"),
col = "blue", cex.main = 0.8,
main = "Blue is density, orange is cumulative distribution function",
sub = "Purple lines are the 10,20,...,90 percentiles")
lines(x, pkumar(x, shape1, shape2), col = "orange")
probs <- seq(0.1, 0.9, by = 0.1)
Q <- qkumar(probs, shape1, shape2)
lines(Q, dkumar(Q, shape1, shape2), col = "purple", lty = 3, type = "h")
lines(Q, pkumar(Q, shape1, shape2), col = "purple", lty = 3, type = "h")
abline(h = probs, col = "purple", lty = 3)
max(abs(pkumar(Q, shape1, shape2) - probs)) # Should be 0
# }
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