Improved binary black hole searches through better discrimination against noise transients

Abstract

Short-duration noise transients in LIGO and Virgo detectors significantly affect the search sensitivity of compact binary coalescence (CBC) signals, especially in the high mass region. In a previous work by the authors Joshi2021, a 2 statistic was proposed to distinguish them, when modeled as sine-Gaussians, from non-spinning CBCs. The present work is an extension where we demonstrate the better noise-discrimination of an improved 2 statistic -- called the optimized sine-Gaussian 2 -- in real LIGO data. The extension includes accounting for the initial phase of the noise transients and use of a well-informed choice of sine-Gaussian basis vectors selected to discern how CBC signals and some of the most worrisome noise-transients project differently on them~sunil2022. To demonstrate this improvement, we use data with blip glitches from the third observational run (O3) of LIGO-Hanford and LIGO-Livingston detectors. Blips are a type of short-duration non-Gaussian noise disturbance known to adversely affect high-mass CBC searches. For CBCs, spin-aligned binary black hole signals were simulated using the IMRPhenomPv2 waveform and injected into real LIGO data from the same run. We show that in comparison to the sine-Gaussian 2, the optimized sine-Gaussian 2 improves the overall true positive rate by around 6\% in a lower-mass bin (m1,m2 ∈ [20,40]M) and by more than 3\% in a higher-mass bin (m1,m2 ∈ [60,80]M). On the other hand, we see a larger improvement -- of more than 20\% -- in both mass bins in comparison to the traditional 2.

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