Parameterised population models of transient non-Gaussian noise in the LIGO gravitational-wave detectors
Parameterised population models of transient non-Gaussian noise in the LIGO gravitational-wave detectors
The two interferometric LIGO gravitational-wave observatories provide the most sensitive data to date to study the gravitational-wave universe. As part of a global network, they have completed their third observing run in which they observed many tens of signals from merging compact binary systems. It has long been known that a limiting factor in identifying transient gravitational-wave signals is the presence of transient non-Gaussian noise, which reduce the ability of astrophysical searches to detect signals confidently. Significant efforts are taken to identify and mitigate this noise at the source, but its presence persists, leading to the need for software solutions. Taking a set of transient noise artefacts categorised by the GravitySpy software during the O3a observing era, we produce parameterised population models of the noise projected into the space of astrophysical model parameters of merging binary systems. We compare the inferred population properties of transient noise artefacts with observed astrophysical systems from the GWTC2.1 catalogue. We find that while the population of astrophysical systems tend to have near equal masses and moderate spins, transient noise artefacts are typically characterised by extreme mass ratios and large spins. This work provides a new method to calculate the consistency of an observed candidate with a given class of noise artefacts. This approach could be used in assessing the consistency of candidates found by astrophysical searches (i.e. determining if they are consistent with a known glitch class). Furthermore, the approach could be incorporated into astrophysical searches directly, potentially improving the reach of the detectors, though only a detailed study would verify this.
gravitational-waves, black holes, data analysis
Ashton, Gregory
a8cec4b1-3c98-4b28-af2a-1e37cb3b9f2a
Thiele, Sarah
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Lecoeuche, Yannick
ca3172a5-c4eb-4770-ac84-5c05ce921b98
McIver, Jess
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Nuttall, Laura K.
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9 August 2022
Ashton, Gregory
a8cec4b1-3c98-4b28-af2a-1e37cb3b9f2a
Thiele, Sarah
5263b0f7-c302-4b15-96ea-4b30581cb56d
Lecoeuche, Yannick
ca3172a5-c4eb-4770-ac84-5c05ce921b98
McIver, Jess
89e7bb4b-79bc-4ee1-9c12-afc0ec19751f
Nuttall, Laura K.
33d73f95-9a8e-4b0b-adbd-10d480573fe3
Ashton, Gregory, Thiele, Sarah, Lecoeuche, Yannick, McIver, Jess and Nuttall, Laura K.
(2022)
Parameterised population models of transient non-Gaussian noise in the LIGO gravitational-wave detectors.
Classical and Quantum Gravity, 39 (17), [175004].
(doi:10.1088/1361-6382/ac8094).
Abstract
The two interferometric LIGO gravitational-wave observatories provide the most sensitive data to date to study the gravitational-wave universe. As part of a global network, they have completed their third observing run in which they observed many tens of signals from merging compact binary systems. It has long been known that a limiting factor in identifying transient gravitational-wave signals is the presence of transient non-Gaussian noise, which reduce the ability of astrophysical searches to detect signals confidently. Significant efforts are taken to identify and mitigate this noise at the source, but its presence persists, leading to the need for software solutions. Taking a set of transient noise artefacts categorised by the GravitySpy software during the O3a observing era, we produce parameterised population models of the noise projected into the space of astrophysical model parameters of merging binary systems. We compare the inferred population properties of transient noise artefacts with observed astrophysical systems from the GWTC2.1 catalogue. We find that while the population of astrophysical systems tend to have near equal masses and moderate spins, transient noise artefacts are typically characterised by extreme mass ratios and large spins. This work provides a new method to calculate the consistency of an observed candidate with a given class of noise artefacts. This approach could be used in assessing the consistency of candidates found by astrophysical searches (i.e. determining if they are consistent with a known glitch class). Furthermore, the approach could be incorporated into astrophysical searches directly, potentially improving the reach of the detectors, though only a detailed study would verify this.
Text
Ashton_2022_Class._Quantum_Grav._39_175004
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Accepted/In Press date: 12 July 2022
Published date: 9 August 2022
Keywords:
gravitational-waves, black holes, data analysis
Identifiers
Local EPrints ID: 508301
URI: http://eprints.soton.ac.uk/id/eprint/508301
ISSN: 0264-9381
PURE UUID: e364eec8-8979-42ee-a4c3-164fc6b312f5
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Date deposited: 16 Jan 2026 17:37
Last modified: 17 Jan 2026 03:47
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Contributors
Author:
Gregory Ashton
Author:
Sarah Thiele
Author:
Yannick Lecoeuche
Author:
Jess McIver
Author:
Laura K. Nuttall
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