We present a framework for sparse Gaussian process (GP) methods which uses forward selection with criteria based on information- theoretic principles, previously suggested for active learning. Our goal is not only to learn d{sparse predictors (which can be evalu- ated in O(d) rather than O(n), d (cid:28) n, n the number of training points), but also to perform training under strong restrictions on time and memory requirements. The scaling of our method is at most O(n (cid:1) d2), and in large real-world classi(cid:12)cation experiments we show that it can match prediction performance of the popular support vector machine (SVM), yet can be signi(cid:12)cantly faster in training. In contrast to the SVM, our approximation produces esti- mates of predictive probabilities ('error bars'), allows for Bayesian model selection and is less complex in implementation.

We present a framework for sparse Gaussian process (GP) methods which uses forward selection with criteria based on informationtheoretic principles, previously suggested for active learning. Our goal is not only to learn d-sparse predictors (which can be evaluated in O(d) rather than O(n), d n, n the number of training points), but also to perform training under strong restrictions on time and memory requirements.

We present a framework for sparse Gaussian process (GP) methods which uses forward selection with criteria based on informationtheoretic principles, previously suggested for active learning. Our goal is not only to learn d-sparse predictors (which can be evaluated in O(d) rather than O(n), d n, n the number of training points), but also to perform training under strong restrictions on time and memory requirements.

We present a framework for sparse Gaussian process (GP) methods which uses forward selection with criteria based on informationtheoretic principles,previously suggested for active learning. Our goal is not only to learn d-sparse predictors (which can be evaluated inO(d) rather than O(n), d n, n the number of training points), but also to perform training under strong restrictions on time and memory requirements.