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Autores principales: Wadekar, Digvijay, Pimpalkar, Arush, Cheung, Mark Ho-Yeuk, Wandelt, Benjamin, Berti, Emanuele, Mehta, Ajit Kumar, Venumadhav, Tejaswi, Roulet, Javier, Islam, Tousif, Zackay, Barak, Mushkin, Jonathan, Zaldarriaga, Matias
Formato: Preprint
Publicado: 2025
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Acceso en línea:https://arxiv.org/abs/2507.08318
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author Wadekar, Digvijay
Pimpalkar, Arush
Cheung, Mark Ho-Yeuk
Wandelt, Benjamin
Berti, Emanuele
Mehta, Ajit Kumar
Venumadhav, Tejaswi
Roulet, Javier
Islam, Tousif
Zackay, Barak
Mushkin, Jonathan
Zaldarriaga, Matias
author_facet Wadekar, Digvijay
Pimpalkar, Arush
Cheung, Mark Ho-Yeuk
Wandelt, Benjamin
Berti, Emanuele
Mehta, Ajit Kumar
Venumadhav, Tejaswi
Roulet, Javier
Islam, Tousif
Zackay, Barak
Mushkin, Jonathan
Zaldarriaga, Matias
contents We introduce a machine learning (ML) framework called $\texttt{TIER}$ for improving the sensitivity of gravitational wave search pipelines. Typically, search pipelines only use a small region of strain data in the vicinity of a candidate signal to construct the detection statistic. However, extended strain data ($\sim 10$ s) in the candidate's vicinity can also carry valuable complementary information. We show that this information can be efficiently captured by ML classifier models trained on sparse summary representation/features of the extended data. Our framework is easy to train and can be used with already existing candidates from any search pipeline, and without requiring expensive injection campaigns. Furthermore, the output of our model can be easily integrated into the detection statistic of a search pipeline. Using $\texttt{TIER}$ on triggers from the $\texttt{IAS-HM}$ pipeline, we find up to $\sim 20\%$ improvement in sensitive volume time in LIGO-Virgo-Kagra O3 data, with improvements concentrated in regions of high masses and unequal mass ratios. Applying our framework increases the significance of several near-threshold gravitational-wave candidates, especially in the pair-instability mass gap and intermediate-mass black hole (IMBH) ranges.
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publishDate 2025
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spellingShingle Improving gravitational wave search sensitivity with TIER: Trigger Inference using Extended strain Representation
Wadekar, Digvijay
Pimpalkar, Arush
Cheung, Mark Ho-Yeuk
Wandelt, Benjamin
Berti, Emanuele
Mehta, Ajit Kumar
Venumadhav, Tejaswi
Roulet, Javier
Islam, Tousif
Zackay, Barak
Mushkin, Jonathan
Zaldarriaga, Matias
General Relativity and Quantum Cosmology
Instrumentation and Methods for Astrophysics
Machine Learning
We introduce a machine learning (ML) framework called $\texttt{TIER}$ for improving the sensitivity of gravitational wave search pipelines. Typically, search pipelines only use a small region of strain data in the vicinity of a candidate signal to construct the detection statistic. However, extended strain data ($\sim 10$ s) in the candidate's vicinity can also carry valuable complementary information. We show that this information can be efficiently captured by ML classifier models trained on sparse summary representation/features of the extended data. Our framework is easy to train and can be used with already existing candidates from any search pipeline, and without requiring expensive injection campaigns. Furthermore, the output of our model can be easily integrated into the detection statistic of a search pipeline. Using $\texttt{TIER}$ on triggers from the $\texttt{IAS-HM}$ pipeline, we find up to $\sim 20\%$ improvement in sensitive volume time in LIGO-Virgo-Kagra O3 data, with improvements concentrated in regions of high masses and unequal mass ratios. Applying our framework increases the significance of several near-threshold gravitational-wave candidates, especially in the pair-instability mass gap and intermediate-mass black hole (IMBH) ranges.
title Improving gravitational wave search sensitivity with TIER: Trigger Inference using Extended strain Representation
topic General Relativity and Quantum Cosmology
Instrumentation and Methods for Astrophysics
Machine Learning
url https://arxiv.org/abs/2507.08318