Litcius/Paper detail

Real-Time Gravitational Wave Science with Neural Posterior Estimation

Maximilian Dax, Stephen R. Green, Jonathan Gair, Jakob H. Macke, Alessandra Buonanno, Bernhard Schölkopf

2021Physical Review Letters240 citationsDOIOpen Access PDF

Abstract

We demonstrate unprecedented accuracy for rapid gravitational wave parameter estimation with deep learning. Using neural networks as surrogates for Bayesian posterior distributions, we analyze eight gravitational wave events from the first LIGO-Virgo Gravitational-Wave Transient Catalog and find very close quantitative agreement with standard inference codes, but with inference times reduced from O(day) to 20 s per event. Our networks are trained using simulated data, including an estimate of the detector noise characteristics near the event. This encodes the signal and noise models within millions of neural-network parameters and enables inference for any observed data consistent with the training distribution, accounting for noise nonstationarity from event to event. Our algorithm-called "DINGO"-sets a new standard in fast and accurate inference of physical parameters of detected gravitational wave events, which should enable real-time data analysis without sacrificing accuracy.

Topics & Concepts

InferenceGravitational waveNoise (video)PhysicsBayesian probabilityBayesian inferenceDetectorArtificial neural networkEvent (particle physics)Computer sciencePosterior probabilityStatistical inferenceStatistical physicsTransient (computer programming)AlgorithmEstimation theorySIGNAL (programming language)Pattern recognition (psychology)Deep neural networksGravitationArtificial intelligenceBackground noiseSignal processingAcousticsPulsars and Gravitational Waves ResearchGaussian Processes and Bayesian InferenceStatistical Mechanics and Entropy