Joint migration inversion; simultaneous determination of velocity fields and depth images using all orders of scattering

Joint migration inversion; simultaneous determination of velocity fields and depth images using all orders of scattering

The future in seismic exploration and seismic monitoring is the inclusion of all orders of scattering in the imaging and inversion algorithms. Using the full wavefield in an inversion process allows us to surpass imprints provided by incomplete acquisition and provide more accurate information on th...

Full description

Saved in:
Bibliographic Details
Published in:Leading edge (Tulsa, Okla.) Vol. 35; no. 12; pp. 1037 - 1046
Main Authors: Verschuur, D. J, Staal, X. R, Berkhout, A. J
Format: Journal Article
Language:English
Published: Society of Exploration Geophysicists 01-12-2016
Subjects:
applied (geophysical surveys & methods)
Arctic Ocean
Atlantic Ocean
data processing
Europe
geophysical methods
geophysical surveys
Geophysics
inverse problem
multiple reflections
North Atlantic
North Sea
Norway
Norwegian Sea
Scandinavia
seismic methods
seismic migration
surveys
Voring Basin
wave fields
Western Europe
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The future in seismic exploration and seismic monitoring is the inclusion of all orders of scattering in the imaging and inversion algorithms. Using the full wavefield in an inversion process allows us to surpass imprints provided by incomplete acquisition and provide more accurate information on the subsurface, as noise becomes signal. We describe an inversion process that does not use the standard parameters from finite-difference-type modeling (being local velocity and density) but that describes the seismic data in terms of elastic reflectivity operators and propagation operators. With these operators, our full-wavefield modeling process builds the complete two-way seismic response. A major advantage of our alternative to the traditional full-waveform inversion methodology is that reflectivity operators are traveltime-free and propagation operators are scattering-free, making the inversion problem significantly more linear. A major advantage of our algorithm is (1) that multiples are utilized to improve both image and velocity accuracy, and (2) that both image and velocities are utilized to make a contribution in the nonlinear migration process. Hence, in joint migration inversion, multiples have a twofold active role.
ISSN:1070-485X
1938-3789
DOI:10.1190/tle35121037.1