Open AccessJournal Article
Approximations for Binary Gaussian Process Classification
TL;DR: A comprehensive overview of many recent algorithms for approximate inference in Gaussian process models for probabilistic binary classification and the relationships between several approaches are elucidated theoretically, and the properties of the different algorithms are corroborated by experimental results.
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Abstract: We provide a comprehensive overview of many recent algorithms for approximate inference in Gaussian process models for probabilistic binary classification. The relationships between several approaches are elucidated theoretically, and the properties of the different algorithms are corroborated by experimental results. We examine both 1) the quality of the predictive distributions and 2) the suitability of the different marginal likelihood approximations for model selection (selecting hyperparameters) and compare to a gold standard based on MCMC. Interestingly, some methods produce good predictive distributions although their marginal likelihood approximations are poor. Strong conclusions are drawn about the methods: The Expectation Propagation algorithm is almost always the method of choice unless the computational budget is very tight. We also extend existing methods in various ways, and provide unifying code implementing all approaches.
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Tom Minka
- 02 Aug 2001
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Expectation Propagation for approximate Bayesian inference
TL;DR: Expectation Propagation (EP) as mentioned in this paper is a deterministic approximation technique in Bayesian networks that unifies two previous techniques: assumed-density filtering, an extension of the Kalman filter, and loopy belief propagation.
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