Rapid identification of strongly lensed gravitational-wave events with machine learning
Srashti Goyal, D. Harikrishnan, S. J. Kapadia, P. Ajith
Abstract
A small fraction of the gravitational-wave signals that will be detected by second and third generation detectors are expected to be strongly lensed by galaxies and clusters, producing multiple observable copies. While optimal Bayesian model selection methods are developed to identify lensed signals, processing tens of thousands (billions) of possible pairs of events detected with second (third) generation detectors is both computationally intensive and time consuming. To mitigate this problem, we propose to use machine learning to rapidly rule out a vast majority of candidate lensed pairs. As a proof of principle, we simulate nonspinning binary black hole events added to Gaussian noise, and train the machine on their time-frequency maps (Q transforms) and localization skymaps (using Bayestar), both of which can be generated in seconds. We show that the trained machine is able to accurately identify lensed pairs with efficiencies comparable to existing Bayesian methods.