Gaussian processes with linear operator inequality constraints
Abstract
This paper presents an approach for constrained Gaussian Process (GP) regression where we assume that a set of linear transformations of the process are bounded. It is motivated by machine learning applications for high-consequence engineering systems, where this kind of information is often made available from phenomenological knowledge. We consider a GP over functions on taking values in , where the process is still Gaussian when is a linear operator. Our goal is to model under the constraint that realizations of are confined to a convex set of functions. In particular, we require that , given two functions and where pointwise. This formulation provides a consistent way of encoding multiple linear constraints, such as shape-constraints based on e.g. boundedness, monotonicity or convexity. We adopt the approach of using a sufficiently dense set of virtual observation locations where the constraint is required to hold, and derive the exact posterior for a conjugate likelihood. The results needed for stable numerical implementation are derived, together with an efficient sampling scheme for estimating the posterior process.
Cite
@article{arxiv.1901.03134,
title = {Gaussian processes with linear operator inequality constraints},
author = {Christian Agrell},
journal= {arXiv preprint arXiv:1901.03134},
year = {2019}
}
Comments
Published in JMLR: http://jmlr.org/papers/volume20/19-065/19-065.pdf