Calibrating gravitational-wave search algorithms with conformal prediction
Calibrating gravitational-wave search algorithms with conformal prediction
In astronomy, we frequently face the decision problem: does this data contain a signal Typically, a statistical approach is used, which requires a threshold. The choice of threshold presents a common challenge in settings where signals and noise must be delineated, but their distributions overlap. Gravitational-wave astronomy, which has gone from the first discovery to catalogs of hundreds of events in less than a decade, presents a fascinating case study. For signals from colliding compact objects, the field has evolved from a frequentist to a Bayesian methodology. However, the issue of choosing a threshold and validating noise contamination in a catalog persists. Confusion and debate often arise due to the misapplication of statistical concepts, the complicated nature of the detection statistics, and the inclusion of astrophysical background models. We introduce conformal prediction (CP), a framework developed in machine learning to provide distribution-free uncertainty quantification to point predictors. We show that CP can be viewed as an extension of the traditional statistical frameworks whereby thresholds are calibrated such that the uncertainty intervals are statistically rigorous and the error rate can be validated. Moreover, we discuss how CP offers a framework to optimally build a metapipeline combining the outputs from multiple independent searches. We introduce CP with a toy cosmic-ray detector, which captures the salient features of most astrophysical search problems and allows us to demonstrate the features of CP in a simple context. We then apply the approach to a recent gravitational-wave mock data challenge using multiple search algorithms for compact binary coalescence signals in interferometric gravitational-wave data. Finally, we conclude with a discussion on the future potential of the method for gravitational-wave astronomy.
Ashton, Gregory
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Colombo, Nicolo
1a85d51e-357f-48b7-b7be-ce36aeebf535
Harry, Ian
8bb4c6c1-1f95-4cd5-94e6-0c3ff249bc0c
Sachdev, Surabhi
ee100781-4c9f-4770-a273-f01729abdfe5
17 June 2024
Ashton, Gregory
a8cec4b1-3c98-4b28-af2a-1e37cb3b9f2a
Colombo, Nicolo
1a85d51e-357f-48b7-b7be-ce36aeebf535
Harry, Ian
8bb4c6c1-1f95-4cd5-94e6-0c3ff249bc0c
Sachdev, Surabhi
ee100781-4c9f-4770-a273-f01729abdfe5
Ashton, Gregory, Colombo, Nicolo, Harry, Ian and Sachdev, Surabhi
(2024)
Calibrating gravitational-wave search algorithms with conformal prediction.
Physical Review D, 109 (12).
(doi:10.1103/PhysRevD.109.123027).
Abstract
In astronomy, we frequently face the decision problem: does this data contain a signal Typically, a statistical approach is used, which requires a threshold. The choice of threshold presents a common challenge in settings where signals and noise must be delineated, but their distributions overlap. Gravitational-wave astronomy, which has gone from the first discovery to catalogs of hundreds of events in less than a decade, presents a fascinating case study. For signals from colliding compact objects, the field has evolved from a frequentist to a Bayesian methodology. However, the issue of choosing a threshold and validating noise contamination in a catalog persists. Confusion and debate often arise due to the misapplication of statistical concepts, the complicated nature of the detection statistics, and the inclusion of astrophysical background models. We introduce conformal prediction (CP), a framework developed in machine learning to provide distribution-free uncertainty quantification to point predictors. We show that CP can be viewed as an extension of the traditional statistical frameworks whereby thresholds are calibrated such that the uncertainty intervals are statistically rigorous and the error rate can be validated. Moreover, we discuss how CP offers a framework to optimally build a metapipeline combining the outputs from multiple independent searches. We introduce CP with a toy cosmic-ray detector, which captures the salient features of most astrophysical search problems and allows us to demonstrate the features of CP in a simple context. We then apply the approach to a recent gravitational-wave mock data challenge using multiple search algorithms for compact binary coalescence signals in interferometric gravitational-wave data. Finally, we conclude with a discussion on the future potential of the method for gravitational-wave astronomy.
Text
PhysRevD.109.123027
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Accepted/In Press date: 17 May 2024
Published date: 17 June 2024
Identifiers
Local EPrints ID: 508247
URI: http://eprints.soton.ac.uk/id/eprint/508247
ISSN: 2470-0010
PURE UUID: 5cfc10cd-57e5-4b22-8780-222c381dcc10
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Date deposited: 15 Jan 2026 17:40
Last modified: 16 Jan 2026 03:13
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Author:
Gregory Ashton
Author:
Nicolo Colombo
Author:
Ian Harry
Author:
Surabhi Sachdev
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