dirmultinomial: Fitting a Dirichlet-Multinomial Distribution

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

If the model is an intercept-only model then @misc (which is a list) has a component called shape which is a vector with the \(M\) values \(\pi_j(1/\phi-1)\).

The Dirichlet-multinomial distribution arises from a multinomial distribution where the probability parameters are not constant but are generated from a multivariate distribution called the Dirichlet distribution. The Dirichlet-multinomial distribution has probability function $$P(Y_1=y_1,\ldots,Y_M=y_M) = {N_{*} \choose {y_1,\ldots,y_M}} \frac{ \prod_{j=1}^{M} \prod_{r=1}^{y_{j}} (\pi_j (1-\phi) + (r-1)\phi)}{ \prod_{r=1}^{N_{*}} (1-\phi + (r-1)\phi)}$$ where \(\phi\) is the over-dispersion parameter and \(N_{*} = y_1+\cdots+y_M\). Here, \(a \choose b\) means ``\(a\) choose \(b\)'' and refers to combinations (see choose). The above formula applies to each row of the matrix response. In this VGAM family function the first \(M-1\) linear/additive predictors correspond to the first \(M-1\) probabilities via $$\eta_j = \log(P[Y=j]/ P[Y=M]) = \log(\pi_j/\pi_M)$$ where \(\eta_j\) is the \(j\)th linear/additive predictor (\(\eta_M=0\) by definition for \(P[Y=M]\) but not for \(\phi\)) and \(j=1,\ldots,M-1\). The \(M\)th linear/additive predictor corresponds to lphi applied to \(\phi\).

Note that \(E(Y_j) = N_* \pi_j\) but the probabilities (returned as the fitted values) \(\pi_j\) are bundled together as a \(M\)-column matrix. The quantities \(N_*\) are returned as the prior weights.

The beta-binomial distribution is a special case of the Dirichlet-multinomial distribution when \(M=2\); see betabinomial. It is easy to show that the first shape parameter of the beta distribution is \(shape1=\pi(1/\phi-1)\) and the second shape parameter is \(shape2=(1-\pi)(1/\phi-1)\). Also, \(\phi=1/(1+shape1+shape2)\), which is known as the intra-cluster correlation coefficient.