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Randomised postiterations for calibrated BayesCG

Randomised postiterations for calibrated BayesCG
Randomised postiterations for calibrated BayesCG
The Bayesian conjugate gradient method offers probabilistic solutions to linear systems but suffers from poor calibration, limiting its utility in uncertainty quantification tasks. Recent approaches leveraging postiterations to construct priors have improved computational properties but failed to correct calibration issues. In this work, we propose a novel randomised postiteration strategy that enhances the calibration of the BayesCG posterior while preserving its favourable convergence characteristics. We present theoretical guarantees for the improved calibration, supported by results on the distribution of posterior errors. Numerical experiments demonstrate the efficacy of the method in both synthetic and inverse problem settings, showing enhanced uncertainty quantification and better propagation of uncertainties through computational pipelines.
stat.ML, cs.LG, cs.NA, math.NA
2331-8422
arXiv
Vyas, Niall
e51f5a57-4eeb-4438-a829-461b17119986
Hegde, Disha
5e7d8e1b-5b2a-4828-9e49-42e9e94c9725
Cockayne, Jon
da87c8b2-fafb-4856-938d-50be8f0e4a5b
Vyas, Niall
e51f5a57-4eeb-4438-a829-461b17119986
Hegde, Disha
5e7d8e1b-5b2a-4828-9e49-42e9e94c9725
Cockayne, Jon
da87c8b2-fafb-4856-938d-50be8f0e4a5b

[Unknown type: UNSPECIFIED]

Record type: UNSPECIFIED

Abstract

The Bayesian conjugate gradient method offers probabilistic solutions to linear systems but suffers from poor calibration, limiting its utility in uncertainty quantification tasks. Recent approaches leveraging postiterations to construct priors have improved computational properties but failed to correct calibration issues. In this work, we propose a novel randomised postiteration strategy that enhances the calibration of the BayesCG posterior while preserving its favourable convergence characteristics. We present theoretical guarantees for the improved calibration, supported by results on the distribution of posterior errors. Numerical experiments demonstrate the efficacy of the method in both synthetic and inverse problem settings, showing enhanced uncertainty quantification and better propagation of uncertainties through computational pipelines.

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2504.04247v1 - Author's Original
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Accepted/In Press date: 5 April 2025
Published date: 5 April 2025
Keywords: stat.ML, cs.LG, cs.NA, math.NA
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Identifiers

Local EPrints ID: 502372
URI: http://eprints.soton.ac.uk/id/eprint/502372
DOI: doi:10.48550/arXiv.2504.04247
ISSN: 2331-8422
PURE UUID: c5d5038d-a634-4d47-8b47-f4d0bbc3074c
ORCID for Disha Hegde: ORCID iD orcid.org/0009-0009-0490-0130
ORCID for Jon Cockayne: ORCID iD orcid.org/0000-0002-3287-199X

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Date deposited: 24 Jun 2025 16:40
Last modified: 20 Sep 2025 02:20

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Contributors

Author: Niall Vyas
Author: Disha Hegde ORCID iD
Author: Jon Cockayne ORCID iD

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