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Main Authors: Reissel, Christina, Lai, Devin, Dwivedi, Shivanshu, Bonilla, Edgard, Geer, Claudia, Wipf, Christopher, Mittleman, Richard, Harris, Philip, Schwartz, Eyal, Poznanski, Dovi, Lantz, Brian, Katsavounidis, Erik
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2511.19682
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_version_ 1866912727463624704
author Reissel, Christina
Lai, Devin
Dwivedi, Shivanshu
Bonilla, Edgard
Geer, Claudia
Wipf, Christopher
Mittleman, Richard
Harris, Philip
Schwartz, Eyal
Poznanski, Dovi
Lantz, Brian
Katsavounidis, Erik
author_facet Reissel, Christina
Lai, Devin
Dwivedi, Shivanshu
Bonilla, Edgard
Geer, Claudia
Wipf, Christopher
Mittleman, Richard
Harris, Philip
Schwartz, Eyal
Poznanski, Dovi
Lantz, Brian
Katsavounidis, Erik
contents The unprecedented sensitivity of the Laser Interferometer Gravitational-Wave Observatory, which enables the detection of distant astrophysical sources, also renders the detectors highly susceptible to low-frequency ground motion. Persistent microseisms in the 0.1-0.3 Hz band couple into the instruments, degrade lock stability, and contribute substantially to detector downtime during observing runs. The multi-stage seismic isolation system has achieved remarkable success in mitigating such disturbances through active feedback control, yet residual platform motion remains a key factor limiting low-frequency sensitivity and duty cycle. Further reduction of this residual motion is therefore critical for improving the long-term stability and overall astrophysical reach of the observatories. In this work, we develop a data-driven approach that uses machine learning to model and suppress residual seismic motion within the isolation system. Ground and platform sensor data from the detectors are used to train a neural network that predicts platform motion driven by microseismic activity. When incorporated into the control scheme, the network's predictions yield up to an order-of-magnitude reduction in residual motion compared to conventional linear filtering methods, revealing that nonlinear couplings play a significant role in limiting current isolation performance. These results demonstrate that machine-learning-based control can provide a powerful new pathway for enhancing active seismic isolation, improving lock robustness, and extending the low-frequency observational capabilities of gravitational-wave detectors.
format Preprint
id arxiv_https___arxiv_org_abs_2511_19682
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Microseismic Noise Mitigation with Machine Learning for Advanced LIGO
Reissel, Christina
Lai, Devin
Dwivedi, Shivanshu
Bonilla, Edgard
Geer, Claudia
Wipf, Christopher
Mittleman, Richard
Harris, Philip
Schwartz, Eyal
Poznanski, Dovi
Lantz, Brian
Katsavounidis, Erik
General Relativity and Quantum Cosmology
Instrumentation and Methods for Astrophysics
The unprecedented sensitivity of the Laser Interferometer Gravitational-Wave Observatory, which enables the detection of distant astrophysical sources, also renders the detectors highly susceptible to low-frequency ground motion. Persistent microseisms in the 0.1-0.3 Hz band couple into the instruments, degrade lock stability, and contribute substantially to detector downtime during observing runs. The multi-stage seismic isolation system has achieved remarkable success in mitigating such disturbances through active feedback control, yet residual platform motion remains a key factor limiting low-frequency sensitivity and duty cycle. Further reduction of this residual motion is therefore critical for improving the long-term stability and overall astrophysical reach of the observatories. In this work, we develop a data-driven approach that uses machine learning to model and suppress residual seismic motion within the isolation system. Ground and platform sensor data from the detectors are used to train a neural network that predicts platform motion driven by microseismic activity. When incorporated into the control scheme, the network's predictions yield up to an order-of-magnitude reduction in residual motion compared to conventional linear filtering methods, revealing that nonlinear couplings play a significant role in limiting current isolation performance. These results demonstrate that machine-learning-based control can provide a powerful new pathway for enhancing active seismic isolation, improving lock robustness, and extending the low-frequency observational capabilities of gravitational-wave detectors.
title Microseismic Noise Mitigation with Machine Learning for Advanced LIGO
topic General Relativity and Quantum Cosmology
Instrumentation and Methods for Astrophysics
url https://arxiv.org/abs/2511.19682