Prestack plane‐wave Kirchhoff depth migration using a cluster of workstations

A beam implementation is presented for efficient full‐volume 3-D prestack Kirchhoff depth migration of seismic data. Unlike conventional Kirchhoff migration in which the input seismic traces in time are migrated one trace at a time into the 3-D image volume for the earth’s subsurface, the beam migration processes a group of input traces (a supergather) together. The requirement for a supergather is that the source and receiver coordinates of the traces fall into two small surface patches. The patches are small enough that a single set of time maps pertaining to the centers of the patches can be used to migrate all the traces within the supergather by Taylor expansion or interpolation. The migration of a supergather consists of two major steps: stacking the traces into a τ-P beam volume, and mapping the beams into the image volume. Since the beam volume is much smaller than the image volume, the beam migration cost is roughly proportional to the number of input supergathers. The computational speedup of beam migration over conventional Kirchhoff migration is roughly proportional to [Formula: see text], the average number of traces per supergather, resulting a theoretical speedup up to two orders of magnitudes. The beam migration was successfully implemented and has been in production use for several years. A factor of 5–25 speedup has been achieved in our in‐house depth migrations. The implementation made 3-D prestack full‐volume depth imaging feasible in a parallel distributed environment.

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A Plane Wave Depth Migration Method for Pre-Stack Seismic Data

Chinese Journal of Geophysics ◽

10.1002/cjg2.438 ◽

2003 ◽

Vol 46 (6) ◽

pp. 1176-1185 ◽

Cited By ~ 5

Author(s):

Shengchang CHEN ◽

Jingzhong CAO ◽

Zaitian MA

Keyword(s):

Plane Wave ◽

Seismic Data ◽

Depth Migration ◽

Migration Method

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Prestack Kirchhoff depth migration of shallow seismic data

Geophysics ◽

10.1190/1.1444425 ◽

1998 ◽

Vol 63 (4) ◽

pp. 1241-1247 ◽

Cited By ~ 22

Author(s):

Linus Pasasa ◽

Friedemann Wenzel ◽

Ping Zhao

Keyword(s):

Waste Disposal ◽

Seismic Data ◽

Signal To Noise Ratio ◽

Disposal Site ◽

Model Estimation ◽

Waste Disposal Site ◽

Depth Migration ◽

Prestack Migration ◽

Shallow Seismic ◽

Kirchhoff Depth Migration

Prestack Kirchhoff depth migration is applied successfully to shallow seismic data from a waste disposal site near Arnstadt in Thuringia, Germany. The motivation behind this study was to locate an underground building buried in a waste disposal. The processing sequence of the prestack migration is simplified significantly as compared to standard common (CMP) data processing. It includes only two parts: (1) velocity‐depth‐model estimation and (2) prestack depth migration. In contrast to conventional CMP stacking, prestack migration does not require a separation of reflections and refractions in the shot data. It still provides an appropriate image. Our data example shows that a superior image can be achieved that would contain not just subtle improvements but a qualitative step forward in resolution and signal‐to‐noise ratio.

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Leading-order seismic imaging using curvelets

Geophysics ◽

10.1190/1.2785047 ◽

2007 ◽

Vol 72 (6) ◽

pp. S231-S248 ◽

Cited By ~ 59

Author(s):

Huub Douma ◽

Maarten V. de Hoop

Keyword(s):

Seismic Data ◽

Order Approximation ◽

Angular Frequency ◽

Leading Order ◽

Numerical Examples ◽

Depth Migration ◽

Map Migration ◽

Kirchhoff Depth Migration ◽

Homogeneous Media ◽

Spatial Support

Curvelets are plausible candidates for simultaneous compression of seismic data, their images, and the imaging operator itself. We show that with curvelets, the leading-order approximation (in angular frequency, horizontal wavenumber, and migrated location) to common-offset (CO) Kirchhoff depth migration becomes a simple transformation of coordinates of curvelets in the data, combined with amplitude scaling. This transformation is calculated using map migration, which employs the local slopes from the curvelet decomposition of the data. Because the data can be compressed using curvelets, the transformation needs to be calculated for relatively few curvelets only. Numerical examples for homogeneous media show that using the leading-order approximation only provides a good approximation to CO migration for moderate propagation times. As the traveltime increases and rays diverge beyond the spatial support of a curvelet; however, the leading-order approximation is no longer accurate enough. This shows the need for correction beyond leading order, even for homogeneous media.

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