bratt {VGAM}R Documentation

Bradley Terry Model With Ties

Description

Fits a Bradley Terry model with ties (intercept-only model) by maximum likelihood estimation.

Usage

bratt(refgp = "last", refvalue = 1, init.alpha = 1, i0 = 0.01)

Arguments

refgp Integer whose value must be from the set {1,...,M}, where there are M competitors. The default value indicates the last competitor is used—but don't input a character string, in general.
refvalue Numeric. A positive value for the reference group.
init.alpha Initial values for the alphas. These are recycled to the appropriate length.
i0 Initial value for alpha_0. If convergence fails, try another positive value.

Details

There are several models that extend the ordinary Bradley Terry model to handle ties. This family function implements one of these models. It involves M competitors who either win or lose or tie against each other. (If there are no draws/ties then use brat). The probability that Competitor i beats Competitor j is alpha_i / (alpha_i + alpha_j + alpha_0), where all the alphas are positive. The probability that Competitor i ties with Competitor j is alpha_0 / (alpha_i + alpha_j + alpha_0). Loosely, the alphas can be thought of as the competitors' `abilities', and alpha_0 is an added parameter to model ties. For identifiability, one of the alpha_i is set to a known value refvalue, e.g., 1. By default, this function chooses the last competitor to have this reference value. The data can be represented in the form of a M by M matrix of counts, where winners are the rows and losers are the columns. However, this is not the way the data should be inputted (see below).

Excluding the reference value/group, this function chooses log(alpha_j) as the first M-1 linear predictors. The log link ensures that the alphas are positive. The last linear predictor is log(alpha_0).

The Bradley Terry model can be fitted with covariates, e.g., a home advantage variable, but unfortunately, this lies outside the VGLM theoretical framework and therefore cannot be handled with this code.

Value

An object of class "vglmff" (see vglmff-class). The object is used by modelling functions such as vglm.

Note

The function Brat is useful for coercing a M by M matrix of counts into a one-row matrix suitable for bratt. Diagonal elements are skipped, and the usual S order of c(a.matrix) of elements is used. There should be no missing values apart from the diagonal elements of the square matrix. The matrix should have winners as the rows, and losers as the columns. In general, the response should be a matrix with M(M-1) columns.

Also, a symmetric matrix of ties should be passed into Brat. The diagonal of this matrix should be all NAs.

Only an intercept model is recommended with bratt. It doesn't make sense really to include covariates because of the limited VGLM framework.

Notationally, note that the VGAM family function brat has M+1 contestants, while bratt has M contestants.

Author(s)

T. W. Yee

References

Torsney, B. (2004) Fitting Bradley Terry models using a multiplicative algorithm. In: Antoch, J. (ed.) Proceedings in Computational Statistics COMPSTAT 2004, Physica-Verlag: Heidelberg. Pages 513–526.

See Also

brat, Brat, binomialff.

Examples

# citation statistics: being cited is a 'win'; citing is a 'loss'
journal = c("Biometrika", "Comm Statist", "JASA", "JRSS-B")
m = matrix(c( NA, 33, 320, 284,
             730, NA, 813, 276,
             498, 68,  NA, 325,
             221, 17, 142,  NA), 4,4)
dimnames(m) = list(winner = journal, loser = journal)

# Add some ties. This is fictitional data.
ties = 5 + 0*m
ties[2,1] = ties[1,2] = 9

# Now fit the model
fit = vglm(Brat(m, ties) ~ 1, bratt(refgp=1), trace=TRUE)
fit = vglm(Brat(m, ties) ~ 1, bratt(refgp=1), trace=TRUE, cri="c")

summary(fit)
c(0, coef(fit)) # log-abilities (in order of "journal"); last is log(alpha0)
c(1, Coef(fit)) # abilities (in order of "journal"); last is alpha0

fit@misc$alpha  # alpha_1,...,alpha_M
fit@misc$alpha0 # alpha_0

fitted(fit)  # probabilities of winning and tying, in awkward form
predict(fit)
(check = InverseBrat(fitted(fit)))    # probabilities of winning 
qprob = attr(fitted(fit), "probtie")  # probabilities of a tie 
qprobmat = InverseBrat(c(qprob), NCo=nrow(ties))  # probabilities of a tie 
check + t(check) + qprobmat    # Should be 1's in the off-diagonals 

[Package VGAM version 0.7-7 Index]