Related papers: Quantum Bayesian Inference with Renormalization for Gravitational Waves

Quantum Bayesian Inference with Renormalization for Gravitational Waves

URL: http://arxiv.org/abs/2403.00846v2
Date: Mon, 15 Jul 2024 12:00:48 GMT
Title: Quantum Bayesian Inference with Renormalization for Gravitational Waves
Authors: Gabriel Escrig, Roberto Campos, Hong Qi, M. A. Martin-Delgado,
Abstract summary: A hybrid quantum algorithm is proposed to carry out quantum inference of parameters from compact binary coalescences detected in gravitational-wave interferometers. We choose binary black hole (BBH) mergers from LIGO observatories as the first case to test the algorithm, but its application can be extended to more general instances.
Score: 1.4555521588662113
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Advancements in gravitational-wave interferometers, particularly the next generation, are poised to profoundly impact gravitational wave astronomy and multimessenger astrophysics. A hybrid quantum algorithm is proposed to carry out quantum inference of parameters from compact binary coalescences detected in gravitational-wave interferometers. It performs quantum Bayesian Inference with Renormalization and Downsampling (qBIRD). We choose binary black hole (BBH) mergers from LIGO observatories as the first case to test the algorithm, but its application can be extended to more general instances. The quantum algorithm is able to generate corner plots of relevant parameters such as chirp mass, mass ratio, spins, etc. by inference of simulated gravitational waves with known injected parameter values with zero noise, Gaussian noise and real data, thus recovering an accuracy equivalent to that of classical Markov Chain Monte Carlo inferences. The simulations are performed with sets of 2 and 4 parameters. These results enhance the possibilities to extend our capacity to track signals from coalescences over longer durations and at lower frequencies extending the accuracy and promptness of gravitational wave parameter estimation.

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