Transfer Learning Adapts to Changing PSD in Gravitational Wave Data
- URL: http://arxiv.org/abs/2410.11911v2
- Date: Fri, 18 Oct 2024 20:08:01 GMT
- Title: Transfer Learning Adapts to Changing PSD in Gravitational Wave Data
- Authors: Beka Modrekiladze,
- Abstract summary: Noise in gravitational wave data poses major challenges in signal identification.
Traditional noise suppression methods often fall short in fully addressing the non-Gaussian effects in the data.
We develop a novel training methodology that enables it to accurately detect gravitational waves amidst highly complex noise.
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- Abstract: The detection of gravitational waves has opened unparalleled opportunities for observing the universe, particularly through the study of black hole inspirals. These events serve as unique laboratories to explore the laws of physics under conditions of extreme energies. However, significant noise in gravitational wave (GW) data from observatories such as Advanced LIGO and Virgo poses major challenges in signal identification. Traditional noise suppression methods often fall short in fully addressing the non-Gaussian effects in the data, including the fluctuations in noise power spectral density (PSD) over short time intervals. These challenges have led to the exploration of an AI approach that, while overcoming previous obstacles, introduced its own challenges, such as scalability, reliability issues, and the vanishing gradient problem. Our approach addresses these issues through a simplified architecture. To compensate for the potential limitations of a simpler model, we have developed a novel training methodology that enables it to accurately detect gravitational waves amidst highly complex noise. Employing this strategy, our model achieves over 99% accuracy in non-white noise scenarios and shows remarkable adaptability to changing noise PSD conditions. By leveraging the principles of transfer learning, our model quickly adapts to new noise profiles with just a few epochs of fine-tuning, facilitating real-time applications in dynamically changing noise environments.
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