Hardware-accelerated Inference for Real-Time Gravitational-Wave Astronomy

TL;DR

This paper presents a hardware-accelerated deep learning inference system for real-time gravitational-wave data analysis, enabling faster, scalable, and reliable alerts crucial for multi-messenger astronomy.

Contribution

It introduces a novel Inference-as-a-Service framework that integrates hardware accelerators for low-latency gravitational-wave data denoising and source identification.

Findings

Achieved sub-millisecond inference latency.

Demonstrated seamless integration with hardware accelerators.

Proposed a scalable, reliable data analysis paradigm for future gravitational-wave detectors.

Abstract

The field of transient astronomy has seen a revolution with the first gravitational-wave detections and the arrival of multi-messenger observations they enabled. Transformed by the first detection of binary black hole and binary neutron star mergers, computational demands in gravitational-wave astronomy are expected to grow by at least a factor of two over the next five years as the global network of kilometer-scale interferometers are brought to design sensitivity. With the increase in detector sensitivity, real-time delivery of gravitational-wave alerts will become increasingly important as an enabler of multi-messenger followup. In this work, we report a novel implementation and deployment of deep learning inference for real-time gravitational-wave data denoising and astrophysical source identification. This is accomplished using a generic Inference-as-a-Service model that is capable of adapting to the future needs of gravitational-wave data analysis. Our implementation allows seamless incorporation of hardware accelerators and also enables the use of commercial or private (dedicated) as-a-service computing. Based on our results, we propose a paradigm shift in low-latency and offline computing in gravitational-wave astronomy. Such a shift can address key challenges in peak-usage, scalability and reliability, and provide a data analysis platform particularly optimized for deep learning applications. The achieved sub-millisecond scale latency will also be relevant for any machine learning-based real-time control systems that may be invoked in the operation of near-future and next generation ground-based laser interferometers, as well as the front-end collection, distribution and processing of data from such instruments.