Ameliorating transient noise bursts in gravitational-wave searches for intermediate-mass black holes

TL;DR

This paper presents a machine learning approach to distinguish intermediate-mass black hole gravitational-wave signals from detector noise glitches, improving detection confidence in real gravitational-wave data.

Contribution

It introduces a multi-layer perceptron classifier that effectively differentiates IMBH signals from noise glitches in LIGO data, demonstrating high true positive rates.

Findings

Over 90% true positive rate on simulated signals in O3a data

Over 70% true positive rate on O3b data for generalization

Effective in real detector noise with significance measure

Abstract

The direct observation of intermediate-mass black holes (IMBH) populations would not only strengthen the possible evolutionary link between stellar and supermassive black holes, but unveil the details of the pair-instability mechanism and elucidate their influence in galaxy formation. Conclusive observation of IMBHs remained elusive until the detection of gravitational-wave (GW) signal GW190521, which lies with high confidence in the mass gap predicted by the pair-instability mechanism. Despite falling in the sensitivity band of current GW detectors, IMBH searches are challenging due to their similarity to transient bursts of detector noise, known as glitches. In this proof-of-concept work, we combine a matched-filter algorithm with a Machine Learning (ML) method to differentiate IMBH signals from non-transient burst noise, known as glitches. In particular, we build a multi-layer perceptron network to perform a multi-class classification of the output triggers of matched-filter. In this way we are able to distinguish simulated GW IMBH signals from different classes of glitches that occurred during the third observing run (O3) {in single detector data}. {We train, validate, and test our model on O3a data, reaching a true positive rate of over $90\%$ for simulated IMBH signals. To test the generalization ability over the evolutionary observing run, we test on the useen data of O3b, which yields a true positive rate of over $70\%$} . We also combine data from multiple detectors to search for simulated IMBH signals in real detector noise, providing a significance measure for the output of our ML method.