Deep learning for low frequency extrapolation of multicomponent data in elastic full waveform inversion

Sun, Hongyu; Demanet, Laurent

doi:10.48550/arxiv.2101.00099

Cited by 2 publications

(1 citation statement)

References 45 publications

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“…The majority of deep learning methods for bandwidth extension are focusing on the time/offset format of the data. Sun and Demanet [40,41] proposed and developed a traceby-trace approach for frequency extrapolation in the time domain. The method operates on full-duration time series and is powered by the WaveNet architecture.…”

Section: B Reconstruction Of Missing Low-frequency Datamentioning

confidence: 99%

Multi-Task Learning for Low-Frequency Extrapolation and Elastic Model Building From Seismic Data

Ovcharenko

Kazei

Alkhalifah

et al. 2022

IEEE Trans. Geosci. Remote Sensing

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Low-frequency signal content in seismic data as well as a realistic initial model are key ingredients for robust and efficient full-waveform inversions. However, acquiring low-frequency data is challenging in practice for active seismic surveys. Data-driven solutions show promise to extrapolate low-frequency data given a high-frequency counterpart. While being established for synthetic acoustic examples, the application of bandwidth extrapolation to field datasets remains non-trivial. Rather than aiming to reach superior accuracy in bandwidth extrapolation, we propose to jointly reconstruct low-frequency data and a smooth background subsurface model within a multi-task deep learning framework. We automatically balance data, model and trace-wise correlation loss terms in the objective functional and show that this approach improves the extrapolation capability of the network. We also design a pipeline for generating synthetic data suitable for field data applications. Finally, we apply the same trained network to synthetic and real marine streamer datasets and run an elastic full-waveform inversion from the extrapolated dataset.

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Section: B Reconstruction Of Missing Low-frequency Datamentioning

confidence: 99%

Multi-Task Learning for Low-Frequency Extrapolation and Elastic Model Building From Seismic Data

Ovcharenko

Kazei

Alkhalifah

et al. 2022

IEEE Trans. Geosci. Remote Sensing

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Progressive multitask learning for high-resolution prediction of reservoir elastic parameters

Liu

Guo

et al. 2023

GEOPHYSICS

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Reservoir elastic parameters play an important role in resource exploration; however, the band-limited characteristics of seismic data and ill-posed nature of seismic inversion significantly affect inversion accuracy. To alleviate this problem, a high-resolution prediction method for reservoir elastic parameters based on the progressive multitask learning network (PMLN) is proposed. The proposed network consists of three parts: Network 1 for low-frequency extension (LFE), Network 2 for reservoir parameter inversion, and Network 3 for image super-resolution (SR). Taking the seismic frequency band as the link, Network 1 is first used to predict the low-frequency information of seismic data. Then, the nonlinear mapping relationship among the high-pass filtered seismic data (and its envelope) and full-frequency seismic data is established. Second, Network 2 directly predicts the reservoir elastic parameters using the seismic data after LFE. Finally, SR of the inversion results is achieved from the image perspective based on Network 3. The three networks have a progressive relationship and can share network features, which is beneficial for improving computing efficiency. As the features extracted by the network represent different contributions to the prediction target, a channel attention mechanism is introduced. Furthermore, the loss function of Network 2 is improved using dip constraints to obtain high-precision reservoir parameters. Synthetic and field data analyses show that all three networks are competent for their respective tasks, and the PMLN can obtain high-resolution prediction results of reservoir elastic parameters. Compared with traditional full-waveform inversion, the PMLN effectively improves the prediction accuracy. Therefore, the PMLN is expected to become a powerful tool for predicting the elastic parameters of reservoirs.

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Deep learning for low frequency extrapolation of multicomponent data in elastic full waveform inversion

Cited by 2 publications

References 45 publications

Multi-Task Learning for Low-Frequency Extrapolation and Elastic Model Building From Seismic Data

Multi-Task Learning for Low-Frequency Extrapolation and Elastic Model Building From Seismic Data

Progressive multitask learning for high-resolution prediction of reservoir elastic parameters

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