Rapid likelihood free inference of compact binary coalescences using accelerated hardware

D. Chatterjee; E. Marx; W. Benoit; R. Kumar; M. Desai; E. Govorkova; A. Gunny; E. Moreno; R. Omer; R. Raikman; M. Saleem; S. Aggarwal; M. W. Coughlin; P. Harris; E. Katsavounidis

doi:10.1088/2632-2153/ad8982

Rapid likelihood free inference of compact binary coalescences using accelerated hardware

D. Chatterjee, E. Marx, W. Benoit, R. Kumar, M. Desai, E. Govorkova, A. Gunny, E. Moreno, R. Omer, R. Raikman, M. Saleem, S. Aggarwal, M. W. Coughlin, P. Harris, E. Katsavounidis

Physics and Astronomy (Twin Cities)

Research output: Contribution to journal › Article › peer-review

Abstract

We report a gravitational-wave parameter estimation algorithm, AMPLFI, based on likelihood-free inference using normalizing flows. The focus of AMPLFI is to perform real-time parameter estimation for candidates detected by machine-learning based compact binary coalescence search, Aframe. We present details of our algorithm and optimizations done related to data-loading and pre-processing on accelerated hardware. We train our model using binary black-hole (BBH) simulations on real LIGO-Virgo detector noise. Our model has ∼ 6 million trainable parameters with training times ≲ 24 h. Based on online deployment on a mock data stream of LIGO-Virgo data, Aframe + AMPLFI is able to pick up BBH candidates and infer parameters for real-time alerts from data acquisition with a net latency of ∼ 6 s.

Original language	English (US)
Article number	045030
Journal	Machine Learning: Science and Technology
Volume	5
Issue number	4
DOIs	https://doi.org/10.1088/2632-2153/ad8982
State	Published - Dec 1 2024

Bibliographical note

Publisher Copyright:
© 2024 The Author(s). Published by IOP Publishing Ltd.

Keywords

Gravitational waves
Likelihood-free Inference
Multi-messenger astronomy
Self-supervised learning

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10.1088/2632-2153/ad8982

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Chatterjee, D., Marx, E., Benoit, W., Kumar, R., Desai, M., Govorkova, E., Gunny, A., Moreno, E., Omer, R., Raikman, R., Saleem, M., Aggarwal, S., Coughlin, M. W., Harris, P., & Katsavounidis, E. (2024). Rapid likelihood free inference of compact binary coalescences using accelerated hardware. Machine Learning: Science and Technology, 5(4), Article 045030. https://doi.org/10.1088/2632-2153/ad8982

Chatterjee, D, Marx, E, Benoit, W, Kumar, R, Desai, M, Govorkova, E, Gunny, A, Moreno, E, Omer, R, Raikman, R, Saleem, M, Aggarwal, S, Coughlin, MW, Harris, P & Katsavounidis, E 2024, 'Rapid likelihood free inference of compact binary coalescences using accelerated hardware', Machine Learning: Science and Technology, vol. 5, no. 4, 045030. https://doi.org/10.1088/2632-2153/ad8982

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abstract = "We report a gravitational-wave parameter estimation algorithm, AMPLFI, based on likelihood-free inference using normalizing flows. The focus of AMPLFI is to perform real-time parameter estimation for candidates detected by machine-learning based compact binary coalescence search, Aframe. We present details of our algorithm and optimizations done related to data-loading and pre-processing on accelerated hardware. We train our model using binary black-hole (BBH) simulations on real LIGO-Virgo detector noise. Our model has ∼ 6 million trainable parameters with training times ≲ 24 h. Based on online deployment on a mock data stream of LIGO-Virgo data, Aframe + AMPLFI is able to pick up BBH candidates and infer parameters for real-time alerts from data acquisition with a net latency of ∼ 6 s.",

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AU - Govorkova, E.

AU - Gunny, A.

AU - Moreno, E.

AU - Omer, R.

AU - Raikman, R.

AU - Saleem, M.

AU - Aggarwal, S.

AU - Coughlin, M. W.

AU - Harris, P.

AU - Katsavounidis, E.

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N2 - We report a gravitational-wave parameter estimation algorithm, AMPLFI, based on likelihood-free inference using normalizing flows. The focus of AMPLFI is to perform real-time parameter estimation for candidates detected by machine-learning based compact binary coalescence search, Aframe. We present details of our algorithm and optimizations done related to data-loading and pre-processing on accelerated hardware. We train our model using binary black-hole (BBH) simulations on real LIGO-Virgo detector noise. Our model has ∼ 6 million trainable parameters with training times ≲ 24 h. Based on online deployment on a mock data stream of LIGO-Virgo data, Aframe + AMPLFI is able to pick up BBH candidates and infer parameters for real-time alerts from data acquisition with a net latency of ∼ 6 s.

AB - We report a gravitational-wave parameter estimation algorithm, AMPLFI, based on likelihood-free inference using normalizing flows. The focus of AMPLFI is to perform real-time parameter estimation for candidates detected by machine-learning based compact binary coalescence search, Aframe. We present details of our algorithm and optimizations done related to data-loading and pre-processing on accelerated hardware. We train our model using binary black-hole (BBH) simulations on real LIGO-Virgo detector noise. Our model has ∼ 6 million trainable parameters with training times ≲ 24 h. Based on online deployment on a mock data stream of LIGO-Virgo data, Aframe + AMPLFI is able to pick up BBH candidates and infer parameters for real-time alerts from data acquisition with a net latency of ∼ 6 s.

KW - Gravitational waves

KW - Likelihood-free Inference

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KW - Self-supervised learning

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Rapid likelihood free inference of compact binary coalescences using accelerated hardware

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