Learn R Programming

VGAM (version 0.9-2)

Betabinom: The Beta-Binomial Distribution

Description

Density, distribution function, and random generation for the beta-binomial distribution.

Usage

dbetabinom(x, size, prob, rho = 0, log = FALSE)
pbetabinom(q, size, prob, rho, log.p = FALSE)
rbetabinom(n, size, prob, rho = 0)
dbetabinom.ab(x, size, shape1, shape2, log = FALSE, .dontuse.prob = NULL)
pbetabinom.ab(q, size, shape1, shape2, log.p = FALSE)
rbetabinom.ab(n, size, shape1, shape2, .dontuse.prob = NULL)

Arguments

x, q
vector of quantiles.
size
number of trials.
n
number of observations. Same as runif.
prob
the probability of success $\mu$. Must be in the unit closed interval $[0,1]$.
rho
the correlation parameter $\rho$. Usually must be in the unit open interval $(0,1)$, however, the value 0 is sometimes supported (if so then it corresponds to the usual binomial distribution).
shape1, shape2
the two (positive) shape parameters of the standard beta distribution. They are called a and b in beta respectively.
log, log.p
Logical. If TRUE then all probabilities p are given as log(p).
.dontuse.prob
An argument that should be ignored and unused.

Value

  • dbetabinom and dbetabinom.ab give the density, pbetabinom and pbetabinom.ab give the distribution function, and rbetabinom and rbetabinom.ab generate random deviates.

Details

The beta-binomial distribution is a binomial distribution whose probability of success is not a constant but it is generated from a beta distribution with parameters shape1 and shape2. Note that the mean of this beta distribution is mu = shape1/(shape1+shape2), which therefore is the mean or the probability of success.

See betabinomial and betabinomial.ab, the VGAM family functions for estimating the parameters, for the formula of the probability density function and other details.

See Also

betabinomial, betabinomial.ab.

Examples

Run this code
set.seed(1); rbetabinom(10, 100, prob = 0.5)
set.seed(1);     rbinom(10, 100, prob = 0.5)  # The same since rho = 0

N <- 9; xx <- 0:N; s1 <- 2; s2 <- 3
dy <- dbetabinom.ab(xx, size = N, shape1 = s1, shape2 = s2)
barplot(rbind(dy, dbinom(xx, size = N, prob = s1 / (s1+s2))),
        beside = TRUE, col = c("blue","green"), las = 1,
        main = paste("Beta-binomial (size=",N,", shape1=", s1,
                   ", shape2=", s2, ") (blue) vs\n",
        " Binomial(size=", N, ", prob=", s1/(s1+s2), ") (green)", sep = ""),
        names.arg = as.character(xx), cex.main = 0.8)
sum(dy * xx)  # Check expected values are equal
sum(dbinom(xx, size = N, prob = s1 / (s1+s2)) * xx)
cumsum(dy) - pbetabinom.ab(xx, N, shape1 = s1, shape2 = s2)  # Should be all 0

y <- rbetabinom.ab(n = 10000, size = N, shape1 = s1, shape2 = s2)
ty <- table(y)
barplot(rbind(dy, ty / sum(ty)),
        beside = TRUE, col = c("blue", "orange"), las = 1,
        main = paste("Beta-binomial (size=", N, ", shape1=", s1,
                     ", shape2=", s2, ") (blue) vs\n",
        " Random generated beta-binomial(size=", N, ", prob=", s1/(s1+s2),
        ") (orange)", sep = ""), cex.main = 0.8,
        names.arg = as.character(xx))

Run the code above in your browser using DataLab