Laplace HypoPINN: Physics-Informed Neural Network for hypocenter localization and its predictive uncertainty

Izzatullah, Muhammad; Yıldırım, İsa; Waheed, Umair bin; Alkhalifah, Tariq

doi:10.48550/arxiv.2205.14439

2022

DOI: 10.48550/arxiv.2205.14439

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Laplace HypoPINN: Physics-Informed Neural Network for hypocenter localization and its predictive uncertainty

Muhammad Izzatullah¹,

İsa Yıldırım²,

Umair bin Waheed³

et al.

Abstract: Several techniques have been proposed over the years for automatic hypocenter localization. While those techniques have pros and cons that trade-off computational efficiency and the susceptibility of getting trapped in local minima, an alternate approach is needed that allows robust localization performance and holds the potential to make the elusive goal of real-time microseismic monitoring possible. Physics-informed neural networks (PINNs) have appeared on the scene as a flexible and versatile framework for … Show more

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Simulating seismic multifrequency wavefields with the Fourier feature physics-informed neural network

Song

Wang

2022

Geophysical Journal International

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Summary To simulate seismic wavefields with a frequency-domain wave equation, conventional numerical methods must solve the equation sequentially to obtain the wavefields for different frequencies. The monofrequency equation has the form of a Helmholtz equation. When solving the Helmholtz equation for seismic wavefields with multiple frequencies, a physics-informed neural network (PINN) can be used. However, the PINN suffers from the problem of spectral bias when approximating high-frequency components. We propose to simulate seismic multi-frequency wavefields using a PINN with an embedded Fourier feature. The input to the Fourier feature PINN for simulating multi-frequency wavefields is four-dimensional, namely the horizontal and vertical spatial coordinates of the model, the horizontal position of the source, and the frequency, and the output is multi-frequency wavefields at arbitrary source positions. While an effective Fourier feature initialization strategy can lead to optimal convergence in training this network, the Fourier feature PINN simulates multi-frequency wavefields with reasonable efficiency and accuracy.

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Simulating seismic multifrequency wavefields with the Fourier feature physics-informed neural network

Song

Wang

2022

Geophysical Journal International

View full text Add to dashboard Cite

show abstract

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Laplace HypoPINN: Physics-Informed Neural Network for hypocenter localization and its predictive uncertainty

Cited by 1 publication

References 18 publications

Simulating seismic multifrequency wavefields with the Fourier feature physics-informed neural network

Simulating seismic multifrequency wavefields with the Fourier feature physics-informed neural network

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