$Detection of point scatterers using diffraction imaging and deep learning$

Detection of point scatterers using diffraction imaging and deep learning

ABSTRACT Diffracted waves carry high‐resolution information that can help interpreting fine structural details at a scale smaller than the seismic wavelength. However, the diffraction energy tends to be weak compared to the reflected energy and is also sensitive to inaccuracies in the migration velo...

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Veröffentlicht in:	Geophysical Prospecting 2020-03, Vol.68 (3), p.830-844
Hauptverfasser:	Tschannen, Valentin, Ettrich, Norman, Delescluse, Matthias, Keuper, Janis
Format:	Artikel
Sprache:	eng
Schlagworte:	Algorithms Artificial neural networks Datasets Deep learning Domains Earth Sciences Geophysics Imaging Imaging techniques Machine Learning Mathematical models Modelling Pattern recognition Resolution Scattering Sciences of the Universe Seismics Signal processing Signal reflection Spatial data Statistics Velocity Wave diffraction Wave equations Wavelength Workflow
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creator	Tschannen, Valentin Ettrich, Norman Delescluse, Matthias Keuper, Janis
description	ABSTRACT Diffracted waves carry high‐resolution information that can help interpreting fine structural details at a scale smaller than the seismic wavelength. However, the diffraction energy tends to be weak compared to the reflected energy and is also sensitive to inaccuracies in the migration velocity, making the identification of its signal challenging. In this work, we present an innovative workflow to automatically detect scattering points in the migration dip angle domain using deep learning. By taking advantage of the different kinematic properties of reflected and diffracted waves, we separate the two types of signals by migrating the seismic amplitudes to dip angle gathers using prestack depth imaging in the local angle domain. Convolutional neural networks are a class of deep learning algorithms able to learn to extract spatial information about the data in order to identify its characteristics. They have now become the method of choice to solve supervised pattern recognition problems. In this work, we use wave equation modelling to create a large and diversified dataset of synthetic examples to train a network into identifying the probable position of scattering objects in the subsurface. After giving an intuitive introduction to diffraction imaging and deep learning and discussing some of the pitfalls of the methods, we evaluate the trained network on field data and demonstrate the validity and good generalization performance of our algorithm. We successfully identify with a high‐accuracy and high‐resolution diffraction points, including those which have a low signal to noise and reflection ratio. We also show how our method allows us to quickly scan through high dimensional data consisting of several versions of a dataset migrated with a range of velocities to overcome the strong effect of incorrect migration velocity on the diffraction signal.
doi_str_mv	10.1111/1365-2478.12889
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subjects	Algorithms Artificial neural networks Datasets Deep learning Domains Earth Sciences Geophysics Imaging Imaging techniques Machine Learning Mathematical models Modelling Pattern recognition Resolution Scattering Sciences of the Universe Seismics Signal processing Signal reflection Spatial data Statistics Velocity Wave diffraction Wave equations Wavelength Workflow
title	Detection of point scatterers using diffraction imaging and deep learning
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