While most Bayesian nonparametric models in machine learning have focused on
the Dirichlet process, the beta process, or their variants, the gamma process
has recently emerged as a useful nonparametric prior in its own right. Current
inference schemes for models involving the gamma process are restricted to
MCMC-based methods, which limits their scalability. In this paper, we present a
variational inference framework for models involving gamma process priors. Our
approach is based on a novel stick-breaking constructive definition of the
gamma process. We prove correctness of this stick-breaking process by using the
characterization of the gamma process as a completely random measure (CRM), and
we explicitly derive the rate measure of our construction using Poisson process
machinery. We also derive error bounds on the truncation of the infinite
process required for variational inference, similar to the truncation analyses
for other nonparametric models based on the Dirichlet and beta processes. Our
representation is then used to derive a variational inference algorithm for a
particular Bayesian nonparametric latent structure formulation known as the
infinite Gamma-Poisson model, where the latent variables are drawn from a gamma
process prior with Poisson likelihoods. Finally, we present results for our
algorithms on nonnegative matrix factorization tasks on document corpora, and
show that we compare favorably to both sampling-based techniques and
variational approaches based on beta-Bernoulli priors