Comparing advanced-era interferometric gravitational-wave detector network configurations: sky localization and source properties
Comparing advanced-era interferometric gravitational-wave detector network configurations: sky localization and source properties
The expansion and upgrade of the global network of ground-based gravitational-wave detectors promises to improve our capacity to infer the sky localization of transient sources, enabling more effective multimessenger follow-ups. At the same time, the increase in the signal-to-noise ratio of detected events allows for more precise estimates of the source parameters. This study aims to assess the performance of advanced-era networks of ground-based detectors, focusing on the Hanford, Livingston, Virgo, and KAGRA instruments. We use full Bayesian parameter estimation procedures to predict the scientific potential of a network. Assuming a fixed configuration of the LIGO Hanford and Livingston detectors, we find that the addition of the Virgo detector is beneficial to the sky localization starting from a binary neutron star range of 20 Mpc and improves significantly from 40 Mpc onward for both a single and double LIGO detector network, reducing the inferred mean sky area by up to 95%. Similarly, the KAGRA detector tightens the constraints, starting from a binary neutron star range of 10 Mpc. Looking at highly spinning binary black holes, we find significant improvements with increasing sensitivity in constraining the intrinsic source parameters when adding Virgo to the two LIGO detectors. Finally, we also examine the impact of the low-frequency cutoff data on the signal-to-noise ratio. We find that existing 20 Hz thresholds are sufficient and propose a metric to monitor this to study detector performance. Our findings quantify how future enhancements in detector sensitivity and network configurations will improve the localization of gravitational-wave sources and allow for more precise identification of their intrinsic properties.
Emma, Mattia
f991761f-2c21-4bea-b9ca-97e582d176f3
de Nobrega, Tiago Fernandes
6f29a0ed-883c-4f06-bf86-57eb15dfe343
Ashton, Gregory
a8cec4b1-3c98-4b28-af2a-1e37cb3b9f2a
23 September 2024
Emma, Mattia
f991761f-2c21-4bea-b9ca-97e582d176f3
de Nobrega, Tiago Fernandes
6f29a0ed-883c-4f06-bf86-57eb15dfe343
Ashton, Gregory
a8cec4b1-3c98-4b28-af2a-1e37cb3b9f2a
Emma, Mattia, de Nobrega, Tiago Fernandes and Ashton, Gregory
(2024)
Comparing advanced-era interferometric gravitational-wave detector network configurations: sky localization and source properties.
Physical Review D, 110 (6), [064068].
(doi:10.1103/PhysRevD.110.064068).
Abstract
The expansion and upgrade of the global network of ground-based gravitational-wave detectors promises to improve our capacity to infer the sky localization of transient sources, enabling more effective multimessenger follow-ups. At the same time, the increase in the signal-to-noise ratio of detected events allows for more precise estimates of the source parameters. This study aims to assess the performance of advanced-era networks of ground-based detectors, focusing on the Hanford, Livingston, Virgo, and KAGRA instruments. We use full Bayesian parameter estimation procedures to predict the scientific potential of a network. Assuming a fixed configuration of the LIGO Hanford and Livingston detectors, we find that the addition of the Virgo detector is beneficial to the sky localization starting from a binary neutron star range of 20 Mpc and improves significantly from 40 Mpc onward for both a single and double LIGO detector network, reducing the inferred mean sky area by up to 95%. Similarly, the KAGRA detector tightens the constraints, starting from a binary neutron star range of 10 Mpc. Looking at highly spinning binary black holes, we find significant improvements with increasing sensitivity in constraining the intrinsic source parameters when adding Virgo to the two LIGO detectors. Finally, we also examine the impact of the low-frequency cutoff data on the signal-to-noise ratio. We find that existing 20 Hz thresholds are sufficient and propose a metric to monitor this to study detector performance. Our findings quantify how future enhancements in detector sensitivity and network configurations will improve the localization of gravitational-wave sources and allow for more precise identification of their intrinsic properties.
Text
PhysRevD.110.064068
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Accepted/In Press date: 2 September 2024
Published date: 23 September 2024
Identifiers
Local EPrints ID: 508246
URI: http://eprints.soton.ac.uk/id/eprint/508246
ISSN: 2470-0010
PURE UUID: 2f97a3c7-96a2-4463-9046-fdd506e89550
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Date deposited: 15 Jan 2026 17:40
Last modified: 16 Jan 2026 03:13
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Author:
Mattia Emma
Author:
Tiago Fernandes de Nobrega
Author:
Gregory Ashton
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