invgamma implements the (d/p/q/r)
statistics functions for the inverse
gamma distribution in R. It
is ideal for using in other packages since it is lightweight and
leverages the (d/p/q/r)gamma() line of functions maintained
by CRAN.
There are two ways to get invgamma. For the CRAN version, use
install.packages("invgamma")For the development version, use
# install.packages("devtools")
devtools::install_github("dkahle/invgamma")(d/p/q/r)invgamma()
functionsThe functions in invgamma match those for the gamma
distribution provided by the stats package. Namely, it
uses as its density f(x) = (b^a / Gamma(a)) x^-(a+1) e^(-b/x),
where a = shape and b = rate.
The PDF
(the f(x) above) can be evaluated with the
dinvgamma() function:
library(invgamma)
library(ggplot2); theme_set(theme_bw())
x <- seq(0, 5, .01)
qplot(x, dinvgamma(x, 7, 10), geom = "line")
# Warning: Removed 1 rows containing missing values (geom_path).
The CDF
can be evaluated with the pinvgamma() function:
f <- function(x) dinvgamma(x, 7, 10)
q <- 2
integrate(f, 0, q)
# 0.7621835 with absolute error < 7.3e-05
(p <- pinvgamma(q, 7, 10))
# [1] 0.7621835The quantile
function can be evaluated with qinvgamma():
qinvgamma(p, 7, 10) # = q
# [1] 2And random number generation can be performed with
rinvgamma():
set.seed(1)
rinvgamma(5, 7, 10)
# [1] 1.9996157 0.9678268 0.9853343 1.3157697 3.1578177rinvgamma() can be used to obtain a Monte Carlo
estimate of the probability given by pinvgamma() above:
samples <- rinvgamma(1e5, 7, 10)
mean(samples <= q)
# [1] 0.7621Moreover, we can check the consistency and correctness of the implementation with
qplot(samples, geom = "density") +
stat_function(fun = f, color = "red")
(d/p/q/r)invchisq() and (d/p/q/r)invexp()
functionsThe gamma
distribution subsumes the chi-squared
and exponential
distributions,
so it makes sense to include the *invchisq() and
*invexp() functions in invgamma. Their
implementations, however, wrap *chisq() and
*exp(), not *invgamma().