Oriented extrapolation of common‐midpoint gathers in the absence of near‐offset data using predictive painting

Khoshnavaz, M. Javad

doi:10.1111/1365-2478.13195

Cited by 3 publications

(2 citation statements)

References 51 publications

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“…The simplest method is to copy a normal moveout (NMO)‐corrected trace from the nearest available offset and use it to replace all the missing traces. More sophisticated interpolation techniques include wave‐equation trace interpolation (Ronen, 1987), trend‐spline interpolation (Vershuur, 1991), the parabolic Radon transform (Nurul Kabir & Verschuur, 1995), frequency–space (

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x

) domain gap‐filling algorithms (Sacchi & Ulrych, 1997), differential offset and shot continuation (Fomel, 2003), inverse shot record dip moveout (Baumstein, 2004), and predictive painting (Khoshnavaz, 2022). Additionally, there is a significant amount of work on interferometric interpolation methods using pseudoprimaries (cross‐correlations of multiples with primary reflections) together with prediction‐error or least‐squares matching filters to perform near offset reconstruction (Curry & Shan, 2010; Guo et al., 2011; Wang et al., 2009; Xu et al., 2018).…”

Section: Introductionmentioning

confidence: 99%

“…This is because trends in transformed domains are often easier to follow than the hyperbolic moveouts of seismic reflections, because there can be more heterogeneities in shot gathers compared to common midpoint (CMP) or common offset gathers, and because the near offset gap can consist of fewer traces to interpolate (for instance in CMP gathers vs. shots). Thus, many studies on seismic interpolation utilize transformations of the data, for example into the wavelet domain (Greiner et al., 2020), the CMP domain (Khoshnavas, 2022; Nurul Kabir & Verschuur, 1995), the Radon domain (Nurul Kabir & Verschuur, 1995; Xu et al., 2018), the common offset domain (Baumstein, 2004), Fourier domains such as

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x

and

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(Naghizadeh & Innanen, 2011; Schonewille et al., 2013; Spitz, 1991; Xu et al., 2005), or transformation through de‐migration into regularized source–receiver configurations (Hlebnikov et al., 2022).…”

Section: Introductionmentioning

confidence: 99%

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Near offset reconstruction for marine seismic data using a convolutional neural network

Huff,

Thorkildsen,

Greiner

et al. 2024

Geophysical Prospecting

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Marine seismic data is often missing near offset information due to separation between the source and receiver cables. To solve this problem, a convolutional neural network is trained on synthetic seismic data to reconstruct the near offset gap. The synthetic data is created using a two‐dimensional finite difference method within a heterogeneous velocity model. These synthetics are generated with a source‐over‐receiver acquisition geometry so that they contain complete near offset data. The convolutional neural network is then trained on input‐target synthetic pairs where the inputs are common midpoint gathers with the near offset section removed, and the targets are the same gathers with the near offset section retained. Following training, the robustness of the method is investigated with regards to common midpoint data sorting, normal moveout correction and changes in the velocity model. It is found that training on common midpoint‐sorted data results in 2.8 times lower error than training on shot gathers, that normal moveout correction of the training data makes no significant difference in error levels, and that the model can reconstruct realistic near offsets on synthetic data generated 10 km away within the heterogeneous velocity model. In field data testing, first a dataset with source‐over‐cable acquisition geometry from the Barents Sea is used to compare the reconstructed wavefields to ground truth values. Although the reconstructed amplitudes require minor scaling to match the true values, predictions on this dataset yield 2.5 times lower near offset reconstruction error compared to a simple Radon transform interpolation method. Furthermore, amplitude versus offset gradient and intercept sections from the Barents Sea dataset are estimated with half the error when including the convolutional neural network‐predicted near offset data, compared to only using the conventionally‐acquirable portion of the data (beyond 112.5 m of offset). In a secondary field data test, a conventional northern North Sea dataset is used to demonstrate how the method may be applied in practice. Here, the convolutional neural network generates more realistic predictions than the Radon method, and the gradient and intercept sections calculated using the convolutional neural network‐predicted traces have higher signal‐to‐noise ratios than the sections calculated using only the original data. The combination of high‐quality synthetic training data and interpolation in the common midpoint domain enables near offset reconstruction at significant depth (1 s of two‐way traveltime or more), which is demonstrated in both synthetic and field examples.

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