TruncatedLogistic {crch} | R Documentation |
Create a Truncated Logistic Distribution
Description
Class and methods for left-, right-, and interval-truncated logistic distributions using the workflow from the distributions3 package.
Usage
TruncatedLogistic(location = 0, scale = 1, left = -Inf, right = Inf)
Arguments
location |
numeric. The location parameter of the underlying untruncated
logistic distribution, typically written |
scale |
numeric. The scale parameter (standard deviation) of
the underlying untruncated logistic distribution,
typically written |
left |
numeric. The left truncation point. Can be any real number,
defaults to |
right |
numeric. The right truncation point. Can be any real number,
defaults to |
Details
The constructor function TruncatedLogistic
sets up a distribution
object, representing the truncated logistic probability distribution by the
corresponding parameters: the latent mean location
= \mu
and
latent standard deviation scale
= \sigma
(i.e., the parameters
of the underlying untruncated logistic variable), the left
truncation
point (with -Inf
corresponding to untruncated), and the
right
truncation point (with Inf
corresponding to untruncated).
The truncated logistic distribution has probability density function (PDF):
f(x) = 1/\sigma \lambda((x - \mu)/\sigma) / (\Lambda((right - \mu)/\sigma) - \Lambda((left - \mu)/\sigma))
for left \le x \le right
, and 0 otherwise,
where \Lambda
and \lambda
are the cumulative distribution function
and probability density function of the standard logistic distribution,
respectively.
All parameters can also be vectors, so that it is possible to define a vector of truncated logistic distributions with potentially different parameters. All parameters need to have the same length or must be scalars (i.e., of length 1) which are then recycled to the length of the other parameters.
For the TruncatedLogistic
distribution objects there is a wide range
of standard methods available to the generics provided in the distributions3
package: pdf
and log_pdf
for the (log-)density (PDF), cdf
for the probability
from the cumulative distribution function (CDF), quantile
for quantiles,
random
for simulating random variables,
crps
for the continuous ranked probability score
(CRPS), and support
for the support interval
(minimum and maximum). Internally, these methods rely on the usual d/p/q/r
functions provided for the truncated logistic distributions in the crch
package, see dtlogis
, and the crps_tlogis
function from the scoringRules package.
The methods is_discrete
and is_continuous
can be used to query whether the distributions are discrete on the entire support
(always FALSE
) or continuous on the entire support (always TRUE
).
See the examples below for an illustration of the workflow for the class and methods.
Value
A TruncatedLogistic
distribution object.
See Also
dtlogis
, Logistic
, CensoredLogistic
,
TruncatedNormal
, TruncatedStudentsT
Examples
## package and random seed
library("distributions3")
set.seed(6020)
## three truncated logistic distributions:
## - untruncated standard logistic
## - left-truncated at zero with latent location = 1 and scale = 1
## - interval-truncated in [0, 5] with latent location = 2 and scale = 1
X <- TruncatedLogistic(
location = c( 0, 1, 2),
scale = c( 1, 1, 1),
left = c(-Inf, 0, 0),
right = c( Inf, Inf, 5)
)
X
## compute mean of the truncated distribution
mean(X)
## higher moments (variance, skewness, kurtosis) are not implemented yet
## support interval (minimum and maximum)
support(X)
## simulate random variables
random(X, 5)
## histograms of 1,000 simulated observations
x <- random(X, 1000)
hist(x[1, ], main = "untruncated")
hist(x[2, ], main = "left-truncated at zero")
hist(x[3, ], main = "interval-truncated in [0, 5]")
## probability density function (PDF) and log-density (or log-likelihood)
x <- c(0, 0, 1)
pdf(X, x)
pdf(X, x, log = TRUE)
log_pdf(X, x)
## cumulative distribution function (CDF)
cdf(X, x)
## quantiles
quantile(X, 0.5)
## cdf() and quantile() are inverses (except at truncation points)
cdf(X, quantile(X, 0.5))
quantile(X, cdf(X, 1))
## all methods above can either be applied elementwise or for
## all combinations of X and x, if length(X) = length(x),
## also the result can be assured to be a matrix via drop = FALSE
p <- c(0.05, 0.5, 0.95)
quantile(X, p, elementwise = FALSE)
quantile(X, p, elementwise = TRUE)
quantile(X, p, elementwise = TRUE, drop = FALSE)
## compare theoretical and empirical mean from 1,000 simulated observations
cbind(
"theoretical" = mean(X),
"empirical" = rowMeans(random(X, 1000))
)
## evaluate continuous ranked probability score (CRPS) using scoringRules
library("scoringRules")
crps(X, x)