Abstract
Gaussian beam migration (GBM) is an effective and robust depth seismic imaging method, which overcomes the disadvantage of Kirchhoff migration in imaging multiple arrivals and has no steep-dip limitation of one-way wave equation migration. However, its imaging quality depends on the initial beam parameters, which can make the beam width increase and wave-front spread with the propagation of the central ray, resulting in poor migration accuracy at depth, especially for exploration areas with complex geological structures. To address this problem, we present an adaptive focused beam method for shot-domain prestack depth migration. Using the information of the input smooth velocity field, we first derive an adaptive focused parameter, which makes a seismic beam focused along the whole central ray to enhance the wave-field construction accuracy in both the shallow and deep regions. Then we introduce this parameter into the GBM, which not only improves imaging quality of deep reflectors but also makes the shallow small-scale geological structures well-defined. As well, using the amplitude-preserved extrapolation operator and deconvolution imaging condition, the concept of amplitude-preserved imaging has been included in our method. Typical numerical examples and the field data processing results demonstrate the validity and adaptability of our method.
Highlights
With the development of petroleum exploration, seismic surveys have gradually extended into areas with complex geological conditions, such as regions with continental faulted basins and offshore salt deposits
Gaussian beam migration (GBM) is an effective and robust depth seismic imaging method, which overcomes the disadvantage of Kirchhoff migration in imaging multiple arrivals and has no steep-dip limitation of one-way wave equation migration
Using the information of the input velocity field to control the beams shape, we have developed an amplitude-preserved adaptive focused beam method for shot-domain prestack depth migration
Summary
With the development of petroleum exploration, seismic surveys have gradually extended into areas with complex geological conditions, such as regions with continental faulted basins and offshore salt deposits This situation presents new challenges for seismic imaging, which compel us to explore a more efficient, accurate, and robust migration method than the existing ones. Gaussian beam migration (GBM) is an elegant and effective depth imaging method, which retains the advantage of ray-based migration, such as flexibility and efficiency, and has an imaging accuracy comparable with wave equation migration. The imaging accuracy varies along the central ray, highest at the focus point and decreasing as moving away from the focus point Aiming at this problem, Nowack (2009) has provided a dynamically focused beam method, which improves the deep imaging quality to some extent. Typical numerical examples and the field data processing results demonstrate the feasibility and validity of the proposed method
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