R/dKumIW.R
In ousuga/RelDists: Estimation for some Reliability Distributions
Defines functions
hKumIW
rKumIW
qKumIW
pKumIW
dKumIW
Documented in
dKumIW
hKumIW
pKumIW
qKumIW
rKumIW
#' The Kumaraswamy Inverse Weibull distribution
#'
#' @author Johan David Marin Benjumea, \email{johand.marin@@udea.edu.co}
#'
#' @description
#' Density, distribution function, quantile function,
#' random generation and hazard function for the Kumaraswamy Inverse Weibull distribution
#' with parameters \code{mu}, \code{sigma} and \code{nu}.
#'
#' @param x,q vector of quantiles.
#' @param p vector of probabilities.
#' @param n number of observations.
#' @param mu parameter.
#' @param sigma parameter.
#' @param nu parameter.
#' @param log,log.p logical; if TRUE, probabilities p are given as log(p).
#' @param lower.tail logical; if TRUE (default), probabilities are P[X <= x], otherwise, P[X > x].
#'
#' @details
#' The Kumaraswamy Inverse Weibull Distribution with parameters \code{mu},
#' \code{sigma} and \code{nu} has density given by
#'
#' \eqn{f(x)= \mu \sigma \nu x^{-\mu - 1} \exp{- \sigma x^{-\mu}} (1 - \exp{- \sigma x^{-\mu}})^{\nu - 1},}
#'
#' for \eqn{x > 0}, \eqn{\mu > 0}, \eqn{\sigma > 0} and \eqn{\nu > 0}.
#'
#' @return
#' \code{dKumIW} gives the density, \code{pKumIW} gives the distribution
#' function, \code{qKumIW} gives the quantile function, \code{rKumIW}
#' generates random deviates and \code{hKumIW} gives the hazard function.
#'
#' @example examples/examples_dKumIW.R
#'
#' @references
#'\insertRef{almalki2014modifications}{RelDists}
#'
#'\insertRef{shahbaz2012kumaraswamy}{RelDists}
#'
#' @export
dKumIW <- function(x, mu, sigma, nu, log=FALSE){
if (any(x < 0))
stop(paste("x must be positive", "\n", ""))
if (any(mu <= 0 ))
stop(paste("mu must be positive", "\n", ""))
if (any(sigma <= 0))
stop(paste("sigma must be positive", "\n", ""))
if (any(nu <= 0 ))
stop(paste("nu must be positive", "\n", ""))
loglik <- log(mu) + log(sigma) + log(nu) - (mu + 1)*log(x) - sigma*x^(-mu) +
(nu -1)*log(1 - exp(- sigma*x^(-mu)))
if (log == FALSE)
density <- exp(loglik)
else
density <- loglik
return(density)
}
#' @export
#' @rdname dKumIW
pKumIW <- function(q, mu, sigma, nu, lower.tail=TRUE, log.p=FALSE){
if (any(q < 0))
stop(paste("q must be positive", "\n", ""))
if (any(mu <= 0 ))
stop(paste("mu must be positive", "\n", ""))
if (any(sigma <= 0))
stop(paste("sigma must be positive", "\n", ""))
if (any(nu <= 0))
stop(paste("nu must be positive", "\n", ""))
cdf <- 1 - (1 - exp(- sigma*q^(-mu)))^nu
if (lower.tail == TRUE) cdf <- cdf
else cdf <- 1 - cdf
if (log.p == FALSE) cdf <- cdf
else cdf <- log(cdf)
cdf
}
#' @export
#' @rdname dKumIW
qKumIW <- function(p, mu, sigma, nu, lower.tail=TRUE, log.p=FALSE){
if (any(mu <= 0 ))
stop(paste("mu must be positive", "\n", ""))
if (any(sigma <= 0))
stop(paste("sigma must be positive", "\n", ""))
if (any(nu <= 0))
stop(paste("nu must be positive", "\n", ""))
if (log.p == TRUE) p <- exp(p)
else p <- p
if (lower.tail == TRUE) p <- p
else p <- 1 - p
if (any(p < 0) | any(p > 1))
stop(paste("p must be between 0 and 1", "\n", ""))
q <- (-sigma / (log(1 - (1 - p)^(1/nu))))
q
}
#' @importFrom stats runif
#' @export
#' @rdname dKumIW
rKumIW <- function(n, mu, sigma, nu){
if(any(n <= 0))
stop(paste("n must be positive","\n",""))
if (any(mu <= 0 ))
stop(paste("mu must be positive", "\n", ""))
if (any(sigma <= 0))
stop(paste("sigma must be positive", "\n", ""))
if (any(nu <= 0))
stop(paste("nu must be positive", "\n", ""))
n <- ceiling(n)
p <- runif(n)
r <- qKumIW(p, mu, sigma, nu)
r
}
#' @export
#' @rdname dKumIW
hKumIW <- function(x, mu, sigma, nu){
if (any(x < 0))
stop(paste("x must be positive", "\n", ""))
if (any(mu <= 0 ))
stop(paste("mu must be positive", "\n", ""))
if (any(sigma <= 0))
stop(paste("sigma must be positive", "\n", ""))
if (any(nu <= 0))
stop(paste("nu must be positive", "\n", ""))
h <- dKumIW(x, mu, sigma, nu, log=FALSE) /
pKumIW(x, mu, sigma, nu, lower.tail=FALSE, log.p=FALSE)
h
}
ousuga/RelDists documentation built on Jan. 12, 2023, 10:27 p.m.
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Defines functions hKumIW rKumIW qKumIW pKumIW dKumIW
Documented in dKumIW hKumIW pKumIW qKumIW rKumIW
#' The Kumaraswamy Inverse Weibull distribution
#'
#' @author Johan David Marin Benjumea, \email{johand.marin@@udea.edu.co}
#'
#' @description
#' Density, distribution function, quantile function,
#' random generation and hazard function for the Kumaraswamy Inverse Weibull distribution
#' with parameters \code{mu}, \code{sigma} and \code{nu}.
#'
#' @param x,q vector of quantiles.
#' @param p vector of probabilities.
#' @param n number of observations.
#' @param mu parameter.
#' @param sigma parameter.
#' @param nu parameter.
#' @param log,log.p logical; if TRUE, probabilities p are given as log(p).
#' @param lower.tail logical; if TRUE (default), probabilities are P[X <= x], otherwise, P[X > x].
#'
#' @details
#' The Kumaraswamy Inverse Weibull Distribution with parameters \code{mu},
#' \code{sigma} and \code{nu} has density given by
#'
#' \eqn{f(x)= \mu \sigma \nu x^{-\mu - 1} \exp{- \sigma x^{-\mu}} (1 - \exp{- \sigma x^{-\mu}})^{\nu - 1},}
#'
#' for \eqn{x > 0}, \eqn{\mu > 0}, \eqn{\sigma > 0} and \eqn{\nu > 0}.
#'
#' @return
#' \code{dKumIW} gives the density, \code{pKumIW} gives the distribution
#' function, \code{qKumIW} gives the quantile function, \code{rKumIW}
#' generates random deviates and \code{hKumIW} gives the hazard function.
#'
#' @example examples/examples_dKumIW.R
#'
#' @references
#'\insertRef{almalki2014modifications}{RelDists}
#'
#'\insertRef{shahbaz2012kumaraswamy}{RelDists}
#'
#' @export
dKumIW <- function(x, mu, sigma, nu, log=FALSE){
if (any(x < 0))
stop(paste("x must be positive", "\n", ""))
if (any(mu <= 0 ))
stop(paste("mu must be positive", "\n", ""))
if (any(sigma <= 0))
stop(paste("sigma must be positive", "\n", ""))
if (any(nu <= 0 ))
stop(paste("nu must be positive", "\n", ""))
loglik <- log(mu) + log(sigma) + log(nu) - (mu + 1)*log(x) - sigma*x^(-mu) +
(nu -1)*log(1 - exp(- sigma*x^(-mu)))
if (log == FALSE)
density <- exp(loglik)
else
density <- loglik
return(density)
}
#' @export
#' @rdname dKumIW
pKumIW <- function(q, mu, sigma, nu, lower.tail=TRUE, log.p=FALSE){
if (any(q < 0))
stop(paste("q must be positive", "\n", ""))
if (any(mu <= 0 ))
stop(paste("mu must be positive", "\n", ""))
if (any(sigma <= 0))
stop(paste("sigma must be positive", "\n", ""))
if (any(nu <= 0))
stop(paste("nu must be positive", "\n", ""))
cdf <- 1 - (1 - exp(- sigma*q^(-mu)))^nu
if (lower.tail == TRUE) cdf <- cdf
else cdf <- 1 - cdf
if (log.p == FALSE) cdf <- cdf
else cdf <- log(cdf)
cdf
}
#' @export
#' @rdname dKumIW
qKumIW <- function(p, mu, sigma, nu, lower.tail=TRUE, log.p=FALSE){
if (any(mu <= 0 ))
stop(paste("mu must be positive", "\n", ""))
if (any(sigma <= 0))
stop(paste("sigma must be positive", "\n", ""))
if (any(nu <= 0))
stop(paste("nu must be positive", "\n", ""))
if (log.p == TRUE) p <- exp(p)
else p <- p
if (lower.tail == TRUE) p <- p
else p <- 1 - p
if (any(p < 0) | any(p > 1))
stop(paste("p must be between 0 and 1", "\n", ""))
q <- (-sigma / (log(1 - (1 - p)^(1/nu))))
q
}
#' @importFrom stats runif
#' @export
#' @rdname dKumIW
rKumIW <- function(n, mu, sigma, nu){
if(any(n <= 0))
stop(paste("n must be positive","\n",""))
if (any(mu <= 0 ))
stop(paste("mu must be positive", "\n", ""))
if (any(sigma <= 0))
stop(paste("sigma must be positive", "\n", ""))
if (any(nu <= 0))
stop(paste("nu must be positive", "\n", ""))
n <- ceiling(n)
p <- runif(n)
r <- qKumIW(p, mu, sigma, nu)
r
}
#' @export
#' @rdname dKumIW
hKumIW <- function(x, mu, sigma, nu){
if (any(x < 0))
stop(paste("x must be positive", "\n", ""))
if (any(mu <= 0 ))
stop(paste("mu must be positive", "\n", ""))
if (any(sigma <= 0))
stop(paste("sigma must be positive", "\n", ""))
if (any(nu <= 0))
stop(paste("nu must be positive", "\n", ""))
h <- dKumIW(x, mu, sigma, nu, log=FALSE) /
pKumIW(x, mu, sigma, nu, lower.tail=FALSE, log.p=FALSE)
h
}
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