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Training strategies for deep learning gravitational-wave searches

Marlin B. Schäfer, Ondřej Zelenka, A. Nitz, F. Ohme, Bernd Brügmann

2022Physical review. D/Physical review. D.46 citationsDOIOpen Access PDF

Abstract

Compact binary systems emit gravitational radiation which is potentially detectable by current Earth bound detectors. Extracting these signals from the instruments' background noise is a complex problem and the computational cost of most current searches depends on the complexity of the source model. Deep learning may be capable of finding signals where current algorithms hit computational limits. Here we restrict our analysis to signals from nonspinning binary black holes and systematically test different strategies by which training data is presented to the networks. To assess the impact of the training strategies, we reanalyze the first published networks and directly compare them to an equivalent matched-filter search. We find that the deep learning algorithms can generalize low signal-to-noise ratio (SNR) signals to high SNR ones but not vice versa. As such, it is not beneficial to provide high SNR signals during training, and fastest convergence is achieved when low SNR samples are provided early on. During testing we found that the networks are sometimes unable to recover any signals when a false alarm probability $<{10}^{\ensuremath{-}3}$ is required. We resolve this restriction by applying a modification we call unbounded Softmax replacement (USR) after training. With this alteration we find that the machine learning search retains $\ensuremath{\ge}91.5%$ of the sensitivity of the matched-filter search down to a false-alarm rate of 1 per month.

Topics & Concepts

Softmax functionComputer scienceFalse alarmConstant false alarm rateGravitational waveFilter (signal processing)Noise (video)Signal-to-noise ratio (imaging)Deep learningArtificial intelligenceDetectorBinary numberSIGNAL (programming language)Convergence (economics)Sensitivity (control systems)AlgorithmPhysicsMathematicsElectronic engineeringTelecommunicationsAstrophysicsComputer visionImage (mathematics)EconomicsProgramming languageEngineeringArithmeticEconomic growthPulsars and Gravitational Waves ResearchGamma-ray bursts and supernovaeAstrophysical Phenomena and Observations
Training strategies for deep learning gravitational-wave searches | Litcius