Fast spatial Gaussian process maximum likelihood estimation via skeletonization factorizations
Abstract
Maximum likelihood estimation for parameter-fitting given observations from a Gaussian process in space is a computationally-demanding task that restricts the use of such methods to moderately-sized datasets. We present a framework for unstructured observations in two spatial dimensions that allows for evaluation of the log-likelihood and its gradient (i.e., the score equations) in time under certain assumptions, where is the number of observations. Our method relies on the skeletonization procedure described by Martinsson & Rokhlin in the form of the recursive skeletonization factorization of Ho & Ying. Combining this with an adaptation of the matrix peeling algorithm of Lin et al. for constructing -matrix representations of black-box operators, we obtain a framework that can be used in the context of any first-order optimization routine to quickly and accurately compute maximum-likelihood estimates.
Cite
@article{arxiv.1603.08057,
title = {Fast spatial Gaussian process maximum likelihood estimation via skeletonization factorizations},
author = {Victor Minden and Anil Damle and Kenneth L. Ho and Lexing Ying},
journal= {arXiv preprint arXiv:1603.08057},
year = {2018}
}
Comments
36 pages, 8 figures