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dc.contributorThe Univ. of Warwick (United Kingdom)
dc.contributorMonash Univ. (Australia)
dc.contributorUniv. of Sheffield (United Kingdom)
dc.contributorUniv. of Leicester (United Kingdom)
dc.contributorArmagh Observatory and Planetarium (United Kingdom)
dc.contributorNational Astronomical Research Institute of Thailand (Thailand)
dc.contributorUniv. of Turku (Finland)
dc.contributorThe Univ. of Manchester (United Kingdom)
dc.contributorUniv. of Portsmouth (United Kingdom)
dc.contributorInstituto de Astrofísica de Canarias (Spain)
dc.contributor.authorO'Neill, David
dc.contributor.authorLyman, Joseph
dc.contributor.authorAckley, Kendall
dc.contributor.authorSteeghs, Danny
dc.contributor.authorGalloway, Duncan
dc.contributor.authorDhillon, Vik
dc.contributor.authorO'Brien, Paul
dc.contributor.authorRamsay, Gavin
dc.contributor.authorNoysena, Kanthanakorn
dc.contributor.authorKotak, Rubina
dc.contributor.authorBreton, Rene
dc.contributor.authorNuttall, Laura
dc.contributor.authorPallé, Enric
dc.contributor.authorPollacco, Don
dc.contributor.authorUlaczyk, Krzysztof
dc.contributor.authorDyer, Martin
dc.contributor.authorJiménez-Ibarra, Felipe
dc.contributor.authorKillestein, Tom
dc.contributor.authorKumar, Amit
dc.contributor.authorKelsey, Lisa
dc.contributor.authorGodson, Ben
dc.contributor.authorJarvis, Dan
dc.date.accessioned2024-11-08T13:35:25Z
dc.date.available2024-11-08T13:35:25Z
dc.date.issued2024-07-01T00:00:00Z
dc.identifier.doi10.1117/12.3018319
dc.identifier.doi10.48550/arXiv.2407.18642
dc.identifier.other2024arXiv240718642O
dc.identifier.otherastro-ph.IM
dc.identifier.otherastro-ph.HE
dc.identifier.other2024arXiv240718642O
dc.identifier.otherarXiv:2407.18642
dc.identifier.other2024SPIE13098E..18O
dc.identifier.other10.1117/12.3018319
dc.identifier.other10.48550/arXiv.2407.18642
dc.identifier.other-
dc.identifier.urihttp://hdl.handle.net/20.500.14302/2141
dc.description.abstractThe search for the electromagnetic counterparts to Gravitational Wave (GW) events has been rapidly gathering pace in recent years thanks to the increasing number and capabilities of both gravitational wave detectors and wide field survey telescopes. Difficulties remain, however, in detecting these counterparts due to their inherent scarcity, faintness and rapidly evolving nature. To find these counterparts, it is important that one optimizes the observing strategy for their recovery. This can be difficult due to the large number of potential variables at play. Such follow-up campaigns are also capable of detecting hundreds or potentially thousands of unrelated transients, particularly for GW events with poor localization. Even if the observations are capable of detecting a counterpart, finding it among the numerous contaminants can prove challenging. Here we present the Gravitational wave Electromagnetic RecovRY code (GERRY) to perform detailed analysis and survey-agnostic quantification of observing campaigns attempting to recover electromagnetic counterparts. GERRY considers the campaign's spatial, temporal and wavelength coverage, in addition to Galactic extinction and the expected counterpart light curve evolution from the GW 3D localization volume. It returns quantified statistics that can be used to: determine the probability of having detected the counterpart, identified the most promising sources, and assessed and refine strategy. Here we demonstrate the code to look at the performance and parameter space probed by current and upcoming wide-field surveys such as GOTO and VRO.
dc.publisherObservatory Operations: Strategies, Processes, and Systems X
dc.titleGERry: A code to optimise the hunt for the electromagnetic counter-parts to gravitational wave events
dc.typeinproceedings
dc.source.journalSPIE
dc.source.journalSPIE13098
dc.source.volume13098
dc.identifier.bibcode2024SPIE13098E..18O


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