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

Huang, Xinquan; Alkhalifah, Tariq

doi:10.1109/lgrs.2022.3176867

Cited by 13 publications

(6 citation statements)

References 16 publications

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“…Recall that if we do the source imaging in the frequency domain, then the wavefield belonging to multiple frequencies is needed for the transformation to the time domain wavefield. As shown in Huang and Alkhalifah [2022b], direct use of the PINN with the loss (Equation 4) would decrease the accuracy and convergence speed. Similar to their implementation, we modify the loss function with a single reference frequency loss by replacing ω to αω ref and U (x, z, ω) to D(x, ω) + αzΦ(x, z, ω, θ), yielding…”

Section: A Modified Loss Functionmentioning

confidence: 99%

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Source location using physics-informed neural networks with hard constraints

Huang

Alkhalifah

2022

Second International Meeting for Applied Geoscience &Amp; Energy

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Locating subsurface seismic sources is crucial to both seismic monitoring and seismology. The exploding reflector assumption provides a direct imaging approach for focusing energy at microseismic source locations under the premise of timereversal imaging. However, the imaging process is prone to aliasing problems when the observed data are sparsely sampled. Physics-informed neural networks (PINNs) provide a feasible solution to obtain aliased free images of the sources by representing the frequency-domain wavefield by as a neural network function of spatial coordinates and angular frequency. Specifically, we use a modified representation of the Helmholtz equation, which incorporates the recorded data in the partial differential equation, as a physical loss for PINNs to avoid the challenge that PINNs face in dealing with boundary conditions. The additional frequency dimension of the neural network function allows for direct image extraction of the subsurface using inverse Fourier transform. Numerical tests on the Overthrust model demonstrate that the proposed method could admit reliable source locations in multiple scenarios with coarsely sampled data in a label-free manner.

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Section: A Modified Loss Functionmentioning

confidence: 99%

“…Accordingly, the dimensions of the velocity v is also scaled, by α, to v(αx, αz). For details, we refer the reader to [Huang and Alkhalifah, 2022b].…”

Section: A Modified Loss Functionmentioning

confidence: 99%

Source location using physics-informed neural networks with hard constraints

Huang

Alkhalifah

2022

Second International Meeting for Applied Geoscience &Amp; Energy

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“…At present, there are few reports on the PINN solution under unknown boundary conditions. 27 To address the issues mentioned above, a mesh-based PINN (M-PINN) approach is proposed in this paper. This approach is inspired by the idea of FEM, where the solution domain is partitioned by mesh.…”

Section: Introductionmentioning

confidence: 99%

“…For traditional numerical methods, the lack of boundary conditions makes it impossible to obtain reliable computational results. At present, there are few reports on the PINN solution under unknown boundary conditions 27 …”

Section: Introductionmentioning

confidence: 99%

M‐PINN: A mesh‐based physics‐informed neural network for linear elastic problems in solid mechanics

Wang,

Liu,

Wang

et al. 2024

Numerical Meth Engineering

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Physics‐informed neural networks (PINNs) have emerged as a promising approach for solving a wide range of numerical problems. Nevertheless, conventional PINNs frequently face challenges in model convergence and stability when optimizing complex loss functions containing complex gradients. In this study, a new mesh‐based PINN method, called M‐PINN, is proposed drawing the ideas of the finite element method (FEM). By partitioning the solution domain into several subdomains and incorporating finite element data distribution constraints to the prior estimates of the predicted data distribution of PINN on the solution domain, the M‐PINN approach effectively reduces the optimization difficulty of conventional PINNs. Moreover, it is sometimes difficult to directly obtain precise boundary conditions in some practical applications. This method can be used to solve PINN problems with unknown boundary conditions, thus having wider applicability. In this study, the efficiency of M‐PINN was demonstrated through a standard 2D linear elastic solid mechanics simulation experiment, and its applicability was investigated in depth. The results indicate that the M‐PINN method outperforms traditional PINN and exhibits superior applicability and convergence, especially in cases involving unknown boundary conditions.

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“…The proposed method allows the neural operators to simultaneously handle the modeling for various velocities, frequencies, and source locations. Moreover, to improve generalization for larger-domain velocities beyond the training sample scope, we propose incorporating the single reference frequency [11] to enhance the generalization ability. We demonstrate the effectiveness of the proposed method on the OpenFWI dataset [12] and more realistic models, e.g., extracted from Overthrust models.…”

Section: Introductionmentioning

confidence: 99%

High-Dimensional Wavefield Solutions Using Physics-Informed Neural Networks with Frequency-Extension

Huang

Alkhalifah

Wang

2022

83rd EAGE Annual Conference &Amp; Exhibition

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Solving the wave equation is essential to seismic imaging and inversion. The numerical solution of the Helmholtz equation, fundamental to this process, often encounters significant computational and memory challenges. We propose an innovative frequency-domain scattered wavefield modeling method employing neural operators adaptable to diverse seismic velocities. The source location and frequency information are embedded within the input background wavefield, enhancing the neural operator's ability to process source configurations effectively. In addition, we utilize a single reference frequency, which enables scaling from larger-domain forward modeling to higherfrequency scenarios, thereby improving our method's accuracy and generalization capabilities for larger-domain applications. Several tests on the OpenFWI datasets and realistic velocity models validate the accuracy and efficacy of our method as a surrogate model, demonstrating its potential to address the computational and memory limitations of numerical methods.

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

Cited by 13 publications

References 16 publications

Source location using physics-informed neural networks with hard constraints

Source location using physics-informed neural networks with hard constraints

M‐PINN: A mesh‐based physics‐informed neural network for linear elastic problems in solid mechanics

High-Dimensional Wavefield Solutions Using Physics-Informed Neural Networks with Frequency-Extension

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