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arxiv: 1407.6710 · v1 · pith:MSNMEBCX · submitted 2014-07-24 · astro-ph.IM · gr-qc

Low-rank approximations for large stationary covariance matrices, as used in the Bayesian and generalized-least-squares analysis of pulsar-timing data

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classification astro-ph.IM gr-qc
keywords matricesanalysiscovariancemethodsstationarybayesiandata-analysisdescribe
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Many data-analysis problems involve large dense matrices that describe the covariance of stationary noise processes; the computational cost of inverting these matrices, or equivalently of solving linear systems that contain them, is often a practical limit for the analysis. We describe two general, practical, and accurate methods to approximate stationary covariance matrices as low-rank matrix products featuring carefully chosen spectral components. These methods can be used to greatly accelerate data-analysis methods in many contexts, such as the Bayesian and generalized-least-squares analysis of pulsar-timing residuals.

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