Wavefield Reconstruction Inversion via Physics-Informed Neural Networks

Song, Chao; Alkhalifah, Tariq

doi:10.1109/tgrs.2021.3123122

Cited by 51 publications

(10 citation statements)

References 77 publications

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“…For forward problems, PINNs have been applied to the eikonal equation for traveltime calculation in isotropic and anisotropic media (Smith et al., 2020; Taufik et al., 2022; Waheed, Alkhalifah, et al., 2021; Waheed et al., 2020; Waheed, Haghighat, et al., 2021) and directly simulate wave equation solutions for acoustic and elastic wave propagation (Alkhalifah et al., 2020; Karimpouli & Tahmasebi, 2020; Moseley, Markham, & Nissen‐Meyer, 2020; Moseley, Nissen‐Meyer, & Markham, 2020; Song & Wang, 2023; Song et al., 2021, 2022). For inverse problems, PINNs have been proposed for exploration‐scale seismic tomography with the factored eikonal equation (Gou et al., 2022; Waheed, Alkhalifah, et al., 2021; Waheed, Haghighat, et al., 2021) and wavefield reconstruction inversion (Song & Alkhalifah, 2021). A PINN algorithm has also been developed for full waveform inversion, as demonstrated through various synthetic case studies (Rasht‐Behesht et al., 2022).…”

Section: Introductionmentioning

confidence: 99%

Physics‐Informed Neural Networks for Elliptical‐Anisotropy Eikonal Tomography: Application to Data From the Northeastern Tibetan Plateau

Chen,

de Ridder,

Rost

et al. 2023

JGR Solid Earth

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We develop a novel approach for multi‐frequency, elliptical‐anisotropic eikonal tomography based on physics‐informed neural networks (pinnEAET). This approach simultaneously estimates the medium properties controlling anisotropic Rayleigh waves and reconstructs the traveltimes. The physics constraints built into pinnEAET's neural network enable high‐resolution results with limited inputs by inferring physically plausible models between data points. Even with a single source, pinnEAET can achieve stable convergence on key features where traditional methods lack resolution. We apply pinnEAET to ambient noise data from a dense seismic array (ChinArray‐Himalaya II) in the northeastern Tibetan Plateau with only 20 quasi‐randomly distributed stations as sources. Anisotropic phase velocity maps for Rayleigh waves in the period range from 10–40 s are obtained by training on observed traveltimes. Despite using only about 3% of the total stations as sources, our results show low uncertainties, good resolution and are consistent with results from conventional tomography.

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Section: Introductionmentioning

confidence: 99%

Physics‐Informed Neural Networks for Elliptical‐Anisotropy Eikonal Tomography: Application to Data From the Northeastern Tibetan Plateau

Chen,

de Ridder,

Rost

et al. 2023

JGR Solid Earth

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“…This idea is highly beneficial to seismic tomography for avoiding the iterative process required by the nonlinearity and can directly extract the predicted parameters (e.g., velocity) for the model. The PINN framework has already shown great potential in solving the seismic forward problem (Moseley et al., 2020; Smith et al., 2020; Song et al., 2021; Waheed, Haghighat, et al., 2021) and seismic inverse problem (Song & Alkhalifah, 2021). Waheed, Alkhalifah, et al.…”

Section: Introductionmentioning

confidence: 99%

Eikonal Tomography With Physics‐Informed Neural Networks: Rayleigh Wave Phase Velocity in the Northeastern Margin of the Tibetan Plateau

Chen

Ridder

Rost

et al. 2022

Geophysical Research Letters

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We present a novel eikonal tomography approach using physics‐informed neural networks (PINNs) for Rayleigh wave phase velocities based on the eikonal equation. The PINN eikonal tomography (pinnET) neural network utilizes deep neural networks as universal function approximators and extracts traveltimes and velocities of the medium during the optimization process. Whereas classical eikonal tomography uses a generic non‐physics based interpolation and regularization step to reconstruct traveltime surfaces, optimizing the network parameters in pinnET means solving a physics constrained traveltime surface reconstruction inversion tackling measurement noise and satisfying physics. We demonstrate this approach by applying it to 25 s surface wave data from ChinArray II sampling the northeastern Tibetan plateau. We validate our results by comparing them to results from conventional eikonal tomography in the same area and find good agreement.

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“…Besides, the complexity of the wave equation in elastic or anisotropic media can considerably add to the computational burden. The recently developed physicsinformed neural network (PINN) for solving the Helmholtz equation showed considerable potential in modeling because of its flexibility, low memory requirement, and no limitations are imposed on the shape of the solution space [1]. However, it is hard to train, admitting less than optimal solutions for practical Xinquan Huang and Tariq Alkhalifah are with the Physical science and engineering division, KAUST e-mail: (xinquan.huang@kaust.edu.sa, tariq.alkhalifah@kaust.edu.sa).…”

Section: Introductionmentioning

confidence: 99%

Single Reference Frequency Loss for Multifrequency Wavefield Representation Using Physics-Informed Neural Networks

Huang

Alkhalifah

2022

IEEE Geosci. Remote Sensing Lett.

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Physics-informed neural networks (PINNs) can offer approximate multidimensional functional solutions to the Helmholtz equation that are flexible, require low memory, and have no limitations on the shape of the solution space. However, the neural network (NN) training can be costly and the cost dramatically increases as we train for multi-frequency wavefields by adding frequency as an additional input to the NN multidimensional function. In this case, the often large variation of the wavefield features (specifically wavelength) with frequency adds more complexity to the NN training. Thus, we propose a new loss function for the NN multidimensional input training that allows us to seamlessly include frequency as a dimension. We specifically utilize the linear relation between frequency and wavenumber (the wavefield space representation) to incorporate a reference frequency scaling to the loss function. As a result, the effective wavenumber of the wavefield solution as a function of frequency remains almost stationary, which reduces the learning burden on the NN function. We demonstrate the effectiveness of this modified loss function on a layered model.

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Wavefield Reconstruction Inversion via Physics-Informed Neural Networks

Cited by 51 publications

References 77 publications

Physics‐Informed Neural Networks for Elliptical‐Anisotropy Eikonal Tomography: Application to Data From the Northeastern Tibetan Plateau

Physics‐Informed Neural Networks for Elliptical‐Anisotropy Eikonal Tomography: Application to Data From the Northeastern Tibetan Plateau

Eikonal Tomography With Physics‐Informed Neural Networks: Rayleigh Wave Phase Velocity in the Northeastern Margin of the Tibetan Plateau

Single Reference Frequency Loss for Multifrequency Wavefield Representation Using Physics-Informed Neural Networks

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