dgig: Generalized Inverse Gaussian Distribution
In GeneralizedHyperbolic: The Generalized Hyperbolic Distribution
Generalized Inverse Gaussian R Documentation
Generalized Inverse Gaussian Distribution
Description
Density function, cumulative distribution function, quantile function
and random number generation for the generalized inverse Gaussian
distribution with parameter vector param. Utility routines are
included for the derivative of the density function and to find
suitable break points for use in determining the distribution function.
Usage
dgig(x, chi = 1, psi = 1, lambda = 1,
param = c(chi, psi, lambda), KOmega = NULL)
pgig(q, chi = 1, psi = 1, lambda = 1,
param = c(chi,psi,lambda), lower.tail = TRUE,
ibfTol = .Machine$double.eps^(0.85), nmax = 200)
qgig(p, chi = 1, psi = 1, lambda = 1,
param = c(chi, psi, lambda), lower.tail = TRUE,
method = c("spline", "integrate"),
nInterpol = 501, uniTol = 10^(-7),
ibfTol = .Machine$double.eps^(0.85), nmax =200, ...)
rgig(n, chi = 1, psi = 1, lambda = 1,
param = c(chi, psi, lambda))
rgig1(n, chi = 1, psi = 1, param = c(chi, psi))
ddgig(x, chi = 1, psi = 1, lambda = 1,
param = c(chi, psi, lambda), KOmega = NULL)
Arguments
x, q
Vector of quantiles.
p
Vector of probabilities.
n
Number of observations to be generated.
chi
A shape parameter that by default holds a value of 1.
psi
Another shape parameter that is set to 1 by default.
lambda
Shape parameter of the GIG distribution. Common to all
forms of parameterization. By default this is set to 1.
param
Parameter vector taking the form c(chi, psi, lambda)
for rgig, or c(chi, psi) for rgig1.
method
Character. If "spline" quantiles are found from a
spline approximation to the distribution function. If
"integrate", the distribution function used is always obtained
by integration.
lower.tail
Logical. If TRUE, probabilities are
P(X\leq x), otherwise as P(X>x).
KOmega
Sets the value of the Bessel function in the density or
derivative of the density. See Details.
ibfTol
Value of tolerance to be passed to
incompleteBesselK by pgig.
nmax
Value of maximum order of the approximating series to be
passed to incompleteBesselK by pgig.
nInterpol
The number of points used in qgig for cubic spline
interpolation (see splinefun) of the distribution function.
uniTol
Value of tol in
calls to uniroot. See uniroot.
...
Passes arguments to uniroot. See Details.
Details
The generalized inverse Gaussian distribution has density
f(x)=\frac{(\psi/\chi)^{\frac{\lambda}{2}}}%
{2K_\lambda(\sqrt{\psi\chi})}x^{\lambda-1}%
e^{-\frac{1}{2}\left(\chi x^{-1}+\psi x\right)}
for x>0, where K_\lambda() is the
modified Bessel function of the third kind with order
\lambda.
The generalized inverse Gaussian distribution is investigated in
detail in Jörgensen (1982).
Use gigChangePars to convert from the
(\delta,\gamma),
(\alpha,\beta), or
(\omega,\eta) parameterizations to the
(\chi,\psi), parameterization used above.
pgig calls the function
incompleteBesselK from the package
DistributionUtils to integrate the density function
dgig. This can be expected to be accurate to about 13 decimal
places on a 32-bit computer, often more accurate. The algorithm used
is due to Slavinsky and Safouhi (2010).
Calculation of quantiles using qgig permits the use of two
different methods. Both methods use uniroot to find the value
of x for which a given q is equal F(x) where F
denotes the cumulative distribution function. The difference is in how
the numerical approximation to F is obtained. The obvious
and more accurate method is to calculate the value of F(x)
whenever it is required using a call to pghyp. This is what
is done if the method is specified as "integrate". It is clear
that the time required for this approach is roughly linear in the
number of quantiles being calculated. A Q-Q plot of a large data set
will clearly take some time. The alternative (and default) method is
that for the major part of the distribution a spline approximation to
F(x) is calculated and quantiles found using uniroot with
this approximation. For extreme values (for which the tail probability
is less than 10^{-7}), the integration method is still
used even when the method specifed is "spline".
If accurate probabilities or quantiles are required, tolerances
(intTol and uniTol) should be set to small values, say
10^{-10} or 10^{-12} with method
= "integrate". Generally then accuracy might be expected to be at
least 10^{-9}. If the default values of the functions
are used, accuracy can only be expected to be around
10^{-4}. Note that on 32-bit systems
.Machine$double.eps^0.25 = 0.0001220703 is a typical value.
Generalized inverse Gaussian observations are obtained via the
algorithm of Dagpunar (1989).
Value
dgig gives the density, pgig gives the distribution
function, qgig gives the quantile function, and rgig
generates random variates. rgig1 generates random variates in
the special case where \lambda = 1.
ddgig gives the derivative of dgig.
Author(s)
David Scott d.scott@auckland.ac.nz, Richard Trendall,
and Melanie Luen.
References
Dagpunar, J.S. (1989). An easily implemented generalised inverse
Gaussian generator. Commun. Statist. -Simula., 18,
703–710.
Jörgensen, B. (1982). Statistical Properties of
the Generalized Inverse Gaussian Distribution. Lecture Notes in
Statistics, Vol. 9, Springer-Verlag, New York.
Slevinsky, Richard M., and Safouhi, Hassan (2010) A recursive
algorithm for the G transformation and accurate computation of
incomplete Bessel functions. Appl. Numer. Math., In press.
See Also
safeIntegrate,
integrate for its shortfalls, splinefun,
uniroot and gigChangePars for changing
parameters to the (\chi,\psi) parameterization,
dghyp for the generalized hyperbolic distribution.
Examples
param <- c(2, 3, 1)
gigRange <- gigCalcRange(param = param, tol = 10^(-3))
par(mfrow = c(1, 2))
curve(dgig(x, param = param), from = gigRange[1], to = gigRange[2],
n = 1000)
title("Density of the\n Generalized Inverse Gaussian")
curve(pgig(x, param = param), from = gigRange[1], to = gigRange[2],
n = 1000)
title("Distribution Function of the\n Generalized Inverse Gaussian")
dataVector <- rgig(500, param = param)
curve(dgig(x, param = param), range(dataVector)[1], range(dataVector)[2],
n = 500)
hist(dataVector, freq = FALSE, add = TRUE)
title("Density and Histogram\n of the Generalized Inverse Gaussian")
DistributionUtils::logHist(dataVector, main =
"Log-Density and Log-Histogram\n of the Generalized Inverse Gaussian")
curve(log(dgig(x, param = param)), add = TRUE,
range(dataVector)[1], range(dataVector)[2], n = 500)
par(mfrow = c(2, 1))
curve(dgig(x, param = param), from = gigRange[1], to = gigRange[2],
n = 1000)
title("Density of the\n Generalized Inverse Gaussian")
curve(ddgig(x, param = param), from = gigRange[1], to = gigRange[2],
n = 1000)
title("Derivative of the Density\n of the Generalized Inverse Gaussian")
GeneralizedHyperbolic documentation built on Nov. 26, 2023, 3 p.m.
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| Generalized Inverse Gaussian | R Documentation |
Generalized Inverse Gaussian Distribution
Description
Density function, cumulative distribution function, quantile function
and random number generation for the generalized inverse Gaussian
distribution with parameter vector param. Utility routines are
included for the derivative of the density function and to find
suitable break points for use in determining the distribution function.
Usage
dgig(x, chi = 1, psi = 1, lambda = 1,
param = c(chi, psi, lambda), KOmega = NULL)
pgig(q, chi = 1, psi = 1, lambda = 1,
param = c(chi,psi,lambda), lower.tail = TRUE,
ibfTol = .Machine$double.eps^(0.85), nmax = 200)
qgig(p, chi = 1, psi = 1, lambda = 1,
param = c(chi, psi, lambda), lower.tail = TRUE,
method = c("spline", "integrate"),
nInterpol = 501, uniTol = 10^(-7),
ibfTol = .Machine$double.eps^(0.85), nmax =200, ...)
rgig(n, chi = 1, psi = 1, lambda = 1,
param = c(chi, psi, lambda))
rgig1(n, chi = 1, psi = 1, param = c(chi, psi))
ddgig(x, chi = 1, psi = 1, lambda = 1,
param = c(chi, psi, lambda), KOmega = NULL)
Arguments
x, q |
Vector of quantiles. |
p |
Vector of probabilities. |
n |
Number of observations to be generated. |
chi |
A shape parameter that by default holds a value of 1. |
psi |
Another shape parameter that is set to 1 by default. |
lambda |
Shape parameter of the GIG distribution. Common to all forms of parameterization. By default this is set to 1. |
param |
Parameter vector taking the form |
method |
Character. If |
lower.tail |
Logical. If |
KOmega |
Sets the value of the Bessel function in the density or derivative of the density. See Details. |
ibfTol |
Value of tolerance to be passed to
|
nmax |
Value of maximum order of the approximating series to be
passed to |
nInterpol |
The number of points used in qgig for cubic spline
interpolation (see |
uniTol |
Value of |
... |
Passes arguments to |
Details
The generalized inverse Gaussian distribution has density
f(x)=\frac{(\psi/\chi)^{\frac{\lambda}{2}}}%
{2K_\lambda(\sqrt{\psi\chi})}x^{\lambda-1}%
e^{-\frac{1}{2}\left(\chi x^{-1}+\psi x\right)}
for x>0, where K_\lambda() is the
modified Bessel function of the third kind with order
\lambda.
The generalized inverse Gaussian distribution is investigated in detail in Jörgensen (1982).
Use gigChangePars to convert from the
(\delta,\gamma),
(\alpha,\beta), or
(\omega,\eta) parameterizations to the
(\chi,\psi), parameterization used above.
pgig calls the function
incompleteBesselK from the package
DistributionUtils to integrate the density function
dgig. This can be expected to be accurate to about 13 decimal
places on a 32-bit computer, often more accurate. The algorithm used
is due to Slavinsky and Safouhi (2010).
Calculation of quantiles using qgig permits the use of two
different methods. Both methods use uniroot to find the value
of x for which a given q is equal F(x) where F
denotes the cumulative distribution function. The difference is in how
the numerical approximation to F is obtained. The obvious
and more accurate method is to calculate the value of F(x)
whenever it is required using a call to pghyp. This is what
is done if the method is specified as "integrate". It is clear
that the time required for this approach is roughly linear in the
number of quantiles being calculated. A Q-Q plot of a large data set
will clearly take some time. The alternative (and default) method is
that for the major part of the distribution a spline approximation to
F(x) is calculated and quantiles found using uniroot with
this approximation. For extreme values (for which the tail probability
is less than 10^{-7}), the integration method is still
used even when the method specifed is "spline".
If accurate probabilities or quantiles are required, tolerances
(intTol and uniTol) should be set to small values, say
10^{-10} or 10^{-12} with method
= "integrate". Generally then accuracy might be expected to be at
least 10^{-9}. If the default values of the functions
are used, accuracy can only be expected to be around
10^{-4}. Note that on 32-bit systems
.Machine$double.eps^0.25 = 0.0001220703 is a typical value.
Generalized inverse Gaussian observations are obtained via the algorithm of Dagpunar (1989).
Value
dgig gives the density, pgig gives the distribution
function, qgig gives the quantile function, and rgig
generates random variates. rgig1 generates random variates in
the special case where \lambda = 1.
ddgig gives the derivative of dgig.
Author(s)
David Scott d.scott@auckland.ac.nz, Richard Trendall, and Melanie Luen.
References
Dagpunar, J.S. (1989). An easily implemented generalised inverse Gaussian generator. Commun. Statist. -Simula., 18, 703–710.
Jörgensen, B. (1982). Statistical Properties of the Generalized Inverse Gaussian Distribution. Lecture Notes in Statistics, Vol. 9, Springer-Verlag, New York.
Slevinsky, Richard M., and Safouhi, Hassan (2010) A recursive algorithm for the G transformation and accurate computation of incomplete Bessel functions. Appl. Numer. Math., In press.
See Also
safeIntegrate,
integrate for its shortfalls, splinefun,
uniroot and gigChangePars for changing
parameters to the (\chi,\psi) parameterization,
dghyp for the generalized hyperbolic distribution.
Examples
param <- c(2, 3, 1)
gigRange <- gigCalcRange(param = param, tol = 10^(-3))
par(mfrow = c(1, 2))
curve(dgig(x, param = param), from = gigRange[1], to = gigRange[2],
n = 1000)
title("Density of the\n Generalized Inverse Gaussian")
curve(pgig(x, param = param), from = gigRange[1], to = gigRange[2],
n = 1000)
title("Distribution Function of the\n Generalized Inverse Gaussian")
dataVector <- rgig(500, param = param)
curve(dgig(x, param = param), range(dataVector)[1], range(dataVector)[2],
n = 500)
hist(dataVector, freq = FALSE, add = TRUE)
title("Density and Histogram\n of the Generalized Inverse Gaussian")
DistributionUtils::logHist(dataVector, main =
"Log-Density and Log-Histogram\n of the Generalized Inverse Gaussian")
curve(log(dgig(x, param = param)), add = TRUE,
range(dataVector)[1], range(dataVector)[2], n = 500)
par(mfrow = c(2, 1))
curve(dgig(x, param = param), from = gigRange[1], to = gigRange[2],
n = 1000)
title("Density of the\n Generalized Inverse Gaussian")
curve(ddgig(x, param = param), from = gigRange[1], to = gigRange[2],
n = 1000)
title("Derivative of the Density\n of the Generalized Inverse Gaussian")
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