Mixtures of Zellner's g-priors have been studied extensively in linear models
and have been shown to have numerous desirable properties for Bayesian variable
selection and model averaging. Several extensions of g-priors to Generalized
Linear Models (GLMs) have been proposed in the literature; however, the choice
of prior distribution of g and resulting properties for inference have received
considerably less attention. In this paper, we unify mixtures of g-priors in
GLMs by assigning the truncated Compound Confluent Hypergeometric (tCCH)
distribution to 1/(1 + g), which encompasses as special cases several mixtures
of g-priors in the literature, such as the hyper-g, Beta-prime, truncated
Gamma, incomplete inverse-Gamma, benchmark, robust, hyper-g/n, and intrinsic
priors. Through an integrated Laplace approximation, the posterior distribution
of 1/(1 + g) is in turn a tCCH distribution, and approximate marginal
likelihoods are thus available analytically, leading to "Compound
Hypergeometric Information Criteria" for model selection. We discuss the local
geometric properties of the g-prior in GLMs and show how the desiderata for
model selection proposed by Bayarri et al, such as asymptotic model selection
consistency, intrinsic consistency, and measurement invariance may be used to
justify the prior and specific choices of the hyper parameters. We illustrate
inference using these priors and contrast them to other approaches via
simulation and real data examples. The methodology is implemented in the R
package BAS and freely available on CRAN