Generalized Inverse Gaussian: The Generalized Inverse Gaussian Distribution

Description

Density, distribution function, quantile function, random generation, expected shortfall and expected value and variance for the generalized inverse gaussian distribution.

Usage

dgig(x, lambda = 1, chi = 1, psi = 1)
pgig(q, lambda = 1, chi = 1, psi = 1, ...)
qgig(p, lambda = 1, chi = 1, psi = 1, method = c("integration", "splines"), 
     spline.points = 200, subdivisions = 200, 
     root.tol = .Machine$double.eps^0.5, 
     rel.tol = root.tol^1.5, abs.tol = rel.tol, ...)
     
rgig(n = 10, lambda = 1, chi = 1, psi = 1, envplot = F, messages = F)
ESgig(p, lambda = 1, chi = 1, psi = 1, ...)
Egig(lambda, chi, psi, func = c("x", "logx", "1/x", "var"), check.pars = T)

Arguments

A vector of quantiles.

A vector of probabilities.

Number of observations.

lambda

A shape and scale and parameter.

chi, psi

Shape and scale parameters. Must be positive.

subdivisions

The number of subdivisions passed to integrate when computing the the distribution function pgig.

rel.tol

The relative accuracy requested from integrate.

abs.tol

The absolute accuracy requested from integrate.

method

Determines which method is used when calculating quantiles.

spline.points

The number of support points when computing the quantiles using splines instead of integration.

root.tol

The tolerance of uniroot.

messages

If TRUE error messages from rgig are printed.

envplot

If TRUE an plot of the envelope is shown.

func

The transformation function when computing the expected value. x is the expected value (default), log x returns the expected value of the logarithm of x, 1/x returns the

check.pars

If TRUE the parameters are checked first.

...

Arguments passed form ESgig to qgig.

Value

dgig gives the density, pgig gives the distribution function, qgig gives the quantile function, ESgig gives the expected shortfall, rgig generates random deviates and Egig gives the expected value of either x, 1/x, log(x) or the variance if func equals var.

Details

qgig computes the quantiles either by using the integration method where the root of the distribution function is solved or via splines which interpolates the distribution function and solves it with uniroot afterwards. The integration method is recommended when few quantiles are required. If more than approximately 20 quantiles are needed to be calculated the splines method becomes faster. The accuracy can be controlled with an adequate setting of the parameters rel.tol, abs.tol, root.tol and spline.points. rgig uses the random generator from the S-Plus library QRMlib (see http://www.math.ethz.ch/~mcneil/book/QRMlib.html).

References

The algorithm for simulating generalized inverse gaussian variates is copied from the S-Plus and Rlibrary QRMlib from Alexander J. McNeil (2005) designed to accompany the book Quantitative Risk Management, Concepts, Techniques and Tools. http://www.math.ethz.ch/~mcneil/book/QRMlib.html.

Examples

Run this code

dgig(1:40,lambda=10,chi=1,psi=1)
qgig(1e-5,lambda=10,chi=1,psi=1)
Egig(lambda=10,chi=1,psi=1,func="x")
Egig(lambda=10,chi=1,psi=1,func="var")
Egig(lambda=10,chi=1,psi=1,func="1/x")

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