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R/lognormalb.R
In mc2d: Tools for Two-Dimensional Monte-Carlo Simulations
#' The Log Normal Distribution parameterized through its mean and standard deviation.
#'
#' Density, distribution function, quantile function and random generation for a log normal distribution whose
#' arithmetic mean equals to \samp{mean} and standard deviation equals to \samp{sd}.
#'
#' This function calls the corresponding density, distribution function, quantile function and random generation
#' from the log normal (see \code{\link[stats]{Lognormal}}) after evaluation of \eqn{meanlog = log(mean^2 / sqrt(sd^2+mean^2))} and
#' \eqn{sqrt{(log(1+sd^2/mean^2))}}
#'
#' @name Lognormalb
#' @param x,q vector of quantiles.
#' @param p vector of probabilities.
#' @param n number of observations. If `length(n) > 1`, the length is taken to be the number required.
#' @param mean the mean of the distribution.
#' @param sd the standard deviation of the distribution.
#' @param log,log.p logical. if `TRUE` probabilities `p` are given as `log(p)`.
#' @param lower.tail logical. if `TRUE`, probabilities are \eqn{P[X \le x]}, otherwise, \eqn{P[X > x]}.
#' @keywords distribution
#' @seealso \code{\link[stats]{Lognormal}}
#'
#' @return \samp{dlnormb} gives the density, \samp{plnormb} gives the distribution function,
#' \samp{qlnormb} gives the quantile function, and \samp{rlnormb} generates random deviates.
#' The length of the result is determined by \samp{n} for \samp{rlnorm}, and is the maximum of the lengths
#' of the numerical arguments for the other functions.
#' The numerical arguments other than \samp{n} are recycled to the length of the result.
#' Only the first elements of the logical arguments are used.
#'
#' The default \samp{mean} and \samp{sd} are chosen to provide a distribution close to a lognormal with
#' \samp{meanlog = 0} and \samp{sdlog = 1}.
#'
#' @examples
#' x <- rlnormb(1E5,3,6)
#' mean(x)
#' sd(x)
#' dlnormb(1) == dnorm(0)
#' dlnormb(1) == dlnorm(1)
#'
dlnormb <- function (x, mean = exp(0.5), sd = sqrt(exp(2)-exp(1)), log = FALSE)
{
gmean <- log(mean^2 / sqrt(sd^2+mean^2))
gstd <- sqrt(log(1+sd^2/mean^2))
return(dlnorm(x, meanlog = gmean, sdlog = gstd, log = log))
}
#' @rdname Lognormalb
plnormb <- function (q, mean = exp(0.5), sd = sqrt(exp(2)-exp(1)), lower.tail = TRUE, log.p = FALSE)
{
gmean <- log(mean^2 / sqrt(sd^2+mean^2))
gstd <- sqrt(log(1+sd^2/mean^2))
return(plnorm(q, meanlog = gmean, sdlog = gstd, lower.tail = lower.tail, log.p = log.p))
}
#' @rdname Lognormalb
qlnormb <- function (p, mean = exp(0.5), sd = sqrt(exp(2)-exp(1)), lower.tail = TRUE, log.p = FALSE)
{
gmean <- log(mean^2 / sqrt(sd^2+mean^2))
gstd <- sqrt(log(1+sd^2/mean^2))
return(qlnorm(p, meanlog = gmean, sdlog = gstd, lower.tail = lower.tail, log.p = log.p))
}
#' @rdname Lognormalb
rlnormb <- function (n, mean = exp(0.5), sd = sqrt(exp(2)-exp(1)))
{
gmean <- log(mean^2 / sqrt(sd^2+mean^2))
gstd <- sqrt(log(1+sd^2/mean^2))
return(rlnorm(n, meanlog = gmean, sdlog = gstd))
}
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#' The Log Normal Distribution parameterized through its mean and standard deviation.
#'
#' Density, distribution function, quantile function and random generation for a log normal distribution whose
#' arithmetic mean equals to \samp{mean} and standard deviation equals to \samp{sd}.
#'
#' This function calls the corresponding density, distribution function, quantile function and random generation
#' from the log normal (see \code{\link[stats]{Lognormal}}) after evaluation of \eqn{meanlog = log(mean^2 / sqrt(sd^2+mean^2))} and
#' \eqn{sqrt{(log(1+sd^2/mean^2))}}
#'
#' @name Lognormalb
#' @param x,q vector of quantiles.
#' @param p vector of probabilities.
#' @param n number of observations. If `length(n) > 1`, the length is taken to be the number required.
#' @param mean the mean of the distribution.
#' @param sd the standard deviation of the distribution.
#' @param log,log.p logical. if `TRUE` probabilities `p` are given as `log(p)`.
#' @param lower.tail logical. if `TRUE`, probabilities are \eqn{P[X \le x]}, otherwise, \eqn{P[X > x]}.
#' @keywords distribution
#' @seealso \code{\link[stats]{Lognormal}}
#'
#' @return \samp{dlnormb} gives the density, \samp{plnormb} gives the distribution function,
#' \samp{qlnormb} gives the quantile function, and \samp{rlnormb} generates random deviates.
#' The length of the result is determined by \samp{n} for \samp{rlnorm}, and is the maximum of the lengths
#' of the numerical arguments for the other functions.
#' The numerical arguments other than \samp{n} are recycled to the length of the result.
#' Only the first elements of the logical arguments are used.
#'
#' The default \samp{mean} and \samp{sd} are chosen to provide a distribution close to a lognormal with
#' \samp{meanlog = 0} and \samp{sdlog = 1}.
#'
#' @examples
#' x <- rlnormb(1E5,3,6)
#' mean(x)
#' sd(x)
#' dlnormb(1) == dnorm(0)
#' dlnormb(1) == dlnorm(1)
#'
dlnormb <- function (x, mean = exp(0.5), sd = sqrt(exp(2)-exp(1)), log = FALSE)
{
gmean <- log(mean^2 / sqrt(sd^2+mean^2))
gstd <- sqrt(log(1+sd^2/mean^2))
return(dlnorm(x, meanlog = gmean, sdlog = gstd, log = log))
}
#' @rdname Lognormalb
plnormb <- function (q, mean = exp(0.5), sd = sqrt(exp(2)-exp(1)), lower.tail = TRUE, log.p = FALSE)
{
gmean <- log(mean^2 / sqrt(sd^2+mean^2))
gstd <- sqrt(log(1+sd^2/mean^2))
return(plnorm(q, meanlog = gmean, sdlog = gstd, lower.tail = lower.tail, log.p = log.p))
}
#' @rdname Lognormalb
qlnormb <- function (p, mean = exp(0.5), sd = sqrt(exp(2)-exp(1)), lower.tail = TRUE, log.p = FALSE)
{
gmean <- log(mean^2 / sqrt(sd^2+mean^2))
gstd <- sqrt(log(1+sd^2/mean^2))
return(qlnorm(p, meanlog = gmean, sdlog = gstd, lower.tail = lower.tail, log.p = log.p))
}
#' @rdname Lognormalb
rlnormb <- function (n, mean = exp(0.5), sd = sqrt(exp(2)-exp(1)))
{
gmean <- log(mean^2 / sqrt(sd^2+mean^2))
gstd <- sqrt(log(1+sd^2/mean^2))
return(rlnorm(n, meanlog = gmean, sdlog = gstd))
}
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