We present a novel method for approximate inference in Bayesian models and regularized risk functionals. It is based on the propagation of mean and variance derived from the Laplace approximation of conditional probabilities in factorizing distributions, much akin to Minka's Expectation Propagation. In the jointly normal case, it coincides with the latter and belief propagation, whereas in the general case, it provides an optimization strategy containing Support Vector chunking, the Bayes Committee Machine, and Gaussian Process chunking as special cases
We formulate approximate Bayesian inference in non-conjugate temporal and spatio-temporal Gaussian p...
We present a novel method for approximate inference. Using some of the constructs from expectation p...
Gaussian process priors can be used to define flexible, probabilistic classification models. Unfortu...
We present a novel method for approximate inference in Bayesian models and regularized risk function...
We discuss the expectation propagation (EP) algorithm for approximate Bayesian inference using a fac...
Laplace's method, a family of asymptotic methods used to approximate integrals, is presented as...
Bayesian learning is often hampered by large computational expense. As a powerful generalization of ...
Abstract. We present a framework for efficient, accurate approximate Bayesian inference in generaliz...
We present a novel method for approximate inference. Using some of the constructs from expectation p...
Gaussian processes are attractive models for probabilistic classification but unfortunately exact in...
We present a framework for efficient, accurate approximate Bayesian inference in generalized linear ...
Includes supplementary materials for the online appendix.We propose the approximate Laplace approxim...
Loopy and generalized belief propagation are popular algorithms for approximate inference in Marko...
The key operation in Bayesian inference is to compute high-dimensional integrals. An old approximate...
The key operation in Bayesian inference is to compute high-dimensional integrals. An old approximate...
We formulate approximate Bayesian inference in non-conjugate temporal and spatio-temporal Gaussian p...
We present a novel method for approximate inference. Using some of the constructs from expectation p...
Gaussian process priors can be used to define flexible, probabilistic classification models. Unfortu...
We present a novel method for approximate inference in Bayesian models and regularized risk function...
We discuss the expectation propagation (EP) algorithm for approximate Bayesian inference using a fac...
Laplace's method, a family of asymptotic methods used to approximate integrals, is presented as...
Bayesian learning is often hampered by large computational expense. As a powerful generalization of ...
Abstract. We present a framework for efficient, accurate approximate Bayesian inference in generaliz...
We present a novel method for approximate inference. Using some of the constructs from expectation p...
Gaussian processes are attractive models for probabilistic classification but unfortunately exact in...
We present a framework for efficient, accurate approximate Bayesian inference in generalized linear ...
Includes supplementary materials for the online appendix.We propose the approximate Laplace approxim...
Loopy and generalized belief propagation are popular algorithms for approximate inference in Marko...
The key operation in Bayesian inference is to compute high-dimensional integrals. An old approximate...
The key operation in Bayesian inference is to compute high-dimensional integrals. An old approximate...
We formulate approximate Bayesian inference in non-conjugate temporal and spatio-temporal Gaussian p...
We present a novel method for approximate inference. Using some of the constructs from expectation p...
Gaussian process priors can be used to define flexible, probabilistic classification models. Unfortu...