Kurt Cutajar scite author profile

Abstract. The scalable calculation of matrix determinants has been a bottleneck to the widespread application of many machine learning methods such as determinantal point processes, Gaussian processes, generalised Markov random fields, graph models and many others. In this work, we estimate log determinants under the framework of maximum entropy, given information in the form of moment constraints from stochastic trace estimation. The estimates demonstrate a significant improvement on state-of-the-art alternative methods, as shown on a wide variety of UFL sparse matrices. By taking the example of a general Markov random field, we also demonstrate how this approach can significantly accelerate inference in large-scale learning methods involving the log determinant.

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Random Feature Expansions for Deep Gaussian Processes

Cutajar¹,

Bonilla²,

Michiardi³

et al. 2016

Preprint

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Bayesian Inference of Log Determinants

Fitzsimons¹,

Cutajar²,

Osborne³

et al. 2017

Preprint

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The log-determinant of a kernel matrix appears in a variety of machine learning problems, ranging from determinantal point processes and generalized Markov random fields, through to the training of Gaussian processes. Exact calculation of this term is often intractable when the size of the kernel matrix exceeds a few thousands. In the spirit of probabilistic numerics, we reinterpret the problem of computing the log-determinant as a Bayesian inference problem. In particular, we combine prior knowledge in the form of bounds from matrix theory and evidence derived from stochastic trace estimation to obtain probabilistic estimates for the log-determinant and its associated uncertainty within a given computational budget. Beyond its novelty and theoretic appeal, the performance of our proposal is competitive with state-of-the-art approaches to approximating the log-determinant, while also quantifying the uncertainty due to budgetconstrained evidence.

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Entropic Trace Estimates for Log Determinants

Fitzsimons¹,

Granziol²,

Cutajar³

et al. 2017

Preprint

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Kurt Cutajar

Deep Gaussian Processes for Multi-fidelity Modeling

Entropic Trace Estimates for Log Determinants

Random Feature Expansions for Deep Gaussian Processes

Bayesian Inference of Log Determinants

Entropic Trace Estimates for Log Determinants

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