dskewlap: Skew-Laplace Distribution
In GeneralizedHyperbolic: The Generalized Hyperbolic Distribution
SkewLaplace R Documentation
Skew-Laplace Distribution
Description
Density function, distribution function, quantiles and
random number generation for the skew-Laplace distribution.
Usage
dskewlap(x, mu = 0, alpha = 1, beta = 1,
param = c(mu, alpha, beta), logPars = FALSE)
pskewlap(q, mu = 0, alpha = 1, beta = 1,
param = c(mu, alpha, beta))
qskewlap(p, mu = 0, alpha = 1, beta = 1,
param = c(mu, alpha, beta))
rskewlap(n, mu = 0, alpha = 1, beta = 1,
param = c(mu, alpha, beta))
Arguments
x, q
Vector of quantiles.
p
Vector of probabilities.
n
Number of observations to be generated.
mu
The location parameter, set to 0 by default.
alpha, beta
The shape parameters, both set to 1 by default.
param
Vector of parameters of the skew-Laplace distribution:
\mu, \alpha and \beta
.
logPars
Logical. If TRUE the second and third components
of param are taken to be log(\alpha) and
log(\beta) respectively.
Details
The central skew-Laplace has mode zero, and is a mixture of a (negative)
exponential distribution with mean \beta, and the negative of an
exponential distribution with mean \alpha. The weights of
the positive and negative components are proportional to their means.
The general skew-Laplace distribution is a shifted central skew-Laplace
distribution, where the mode is given by \mu.
The density is given by:
f(x)=\frac{1}{\alpha+\beta} e^{(x - \mu)/\alpha}
for x\leq\mu, and
f(x)=\frac{1}{\alpha+\beta} e^{-(x - \mu)/\beta}
for x\geq\mu
Value
dskewlap gives the density, pskewlap gives the distribution
function, qskewlap gives the quantile function and rskewlap
generates random variates. The distribution function is obtained by
elementary integration of the density function. Random variates are
generated from exponential observations using the characterization of
the skew-Laplace as a mixture of exponential observations.
Author(s)
David Scott d.scott@auckland.ac.nz,
Ai-Wei Lee, Richard Trendall
References
Fieller, N. J., Flenley, E. C. and Olbricht, W. (1992)
Statistics of particle size data.
Appl. Statist.,
41, 127–146.
See Also
hyperbFitStart
Examples
param <- c(1, 1, 2)
par(mfrow = c(1, 2))
curve(dskewlap(x, param = param), from = -5, to = 8, n = 1000)
title("Density of the\n Skew-Laplace Distribution")
curve(pskewlap(x, param = param), from = -5, to = 8, n = 1000)
title("Distribution Function of the\n Skew-Laplace Distribution")
dataVector <- rskewlap(500, param = param)
curve(dskewlap(x, param = param), range(dataVector)[1], range(dataVector)[2],
n = 500)
hist(dataVector, freq = FALSE, add = TRUE)
title("Density and Histogram\n of the Skew-Laplace Distribution")
DistributionUtils::logHist(dataVector, main =
"Log-Density and Log-Histogram\n of the Skew-Laplace Distribution")
curve(log(dskewlap(x, param = param)), add = TRUE,
range(dataVector)[1], range(dataVector)[2], n = 500)
GeneralizedHyperbolic documentation built on Nov. 26, 2023, 5:07 p.m.
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| SkewLaplace | R Documentation |
Skew-Laplace Distribution
Description
Density function, distribution function, quantiles and random number generation for the skew-Laplace distribution.
Usage
dskewlap(x, mu = 0, alpha = 1, beta = 1,
param = c(mu, alpha, beta), logPars = FALSE)
pskewlap(q, mu = 0, alpha = 1, beta = 1,
param = c(mu, alpha, beta))
qskewlap(p, mu = 0, alpha = 1, beta = 1,
param = c(mu, alpha, beta))
rskewlap(n, mu = 0, alpha = 1, beta = 1,
param = c(mu, alpha, beta))
Arguments
x, q |
Vector of quantiles. |
p |
Vector of probabilities. |
n |
Number of observations to be generated. |
mu |
The location parameter, set to 0 by default. |
alpha, beta |
The shape parameters, both set to 1 by default. |
param |
Vector of parameters of the skew-Laplace distribution:
|
.
logPars |
Logical. If |
Details
The central skew-Laplace has mode zero, and is a mixture of a (negative)
exponential distribution with mean \beta, and the negative of an
exponential distribution with mean \alpha. The weights of
the positive and negative components are proportional to their means.
The general skew-Laplace distribution is a shifted central skew-Laplace
distribution, where the mode is given by \mu.
The density is given by:
f(x)=\frac{1}{\alpha+\beta} e^{(x - \mu)/\alpha}
for x\leq\mu, and
f(x)=\frac{1}{\alpha+\beta} e^{-(x - \mu)/\beta}
for x\geq\mu
Value
dskewlap gives the density, pskewlap gives the distribution
function, qskewlap gives the quantile function and rskewlap
generates random variates. The distribution function is obtained by
elementary integration of the density function. Random variates are
generated from exponential observations using the characterization of
the skew-Laplace as a mixture of exponential observations.
Author(s)
David Scott d.scott@auckland.ac.nz, Ai-Wei Lee, Richard Trendall
References
Fieller, N. J., Flenley, E. C. and Olbricht, W. (1992) Statistics of particle size data. Appl. Statist., 41, 127–146.
See Also
hyperbFitStart
Examples
param <- c(1, 1, 2)
par(mfrow = c(1, 2))
curve(dskewlap(x, param = param), from = -5, to = 8, n = 1000)
title("Density of the\n Skew-Laplace Distribution")
curve(pskewlap(x, param = param), from = -5, to = 8, n = 1000)
title("Distribution Function of the\n Skew-Laplace Distribution")
dataVector <- rskewlap(500, param = param)
curve(dskewlap(x, param = param), range(dataVector)[1], range(dataVector)[2],
n = 500)
hist(dataVector, freq = FALSE, add = TRUE)
title("Density and Histogram\n of the Skew-Laplace Distribution")
DistributionUtils::logHist(dataVector, main =
"Log-Density and Log-Histogram\n of the Skew-Laplace Distribution")
curve(log(dskewlap(x, param = param)), add = TRUE,
range(dataVector)[1], range(dataVector)[2], n = 500)
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