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Published as Interpretation, 1, no. 1, SA109-SA116, (2013)

Automated spectral recomposition with application in stratigraphic interpretation

Yihua Cai% latex2html id marker 900 \setcounter{footnote}{1}\fnsymbol{footnote}% latex2html id marker 900 ootnote}{1}<IMG WIDTH=% latex2html id marker 902 \setcounter{footnote}{2}\fnsymbol{footnote}% latex2html id marker 902 ootnote}{2}<IMG WIDTH=% latex2html id marker 903 }{0}<IMG WIDTH=, Sergey Fomel% latex2html id marker 905 \setcounter{footnote}{2}\fnsymbol{footnote}, and Hongliu Zeng% latex2html id marker 906 \setcounter{footnote}{2}\fnsymbol{footnote}
Currently Shell EPCO
200 N Dairy Ashford Rd
Houston, TX 77079-1101
Bureau of Economic Geology
Jackson School of Geosciences
The University of Texas at Austin
Austin, TX 78713-8924

Abstract:

Analyzing seismic attributes in the frequency domain is helpful for reservoir characterization. To analyze the reservoir interval of interest in detail, it is important to capture the seismic response at each frequency subset. Spectral recomposition can be used to extract significant components from the seismic spectrum. We propose a separable nonlinear least-squares algorithm for spectral recomposition, which estimates both linear and nonlinear parts automatically in separate steps. Our approach is applied to estimate fundamental signal parameters, peak frequencies and amplitudes, with which the seismic spectrum can be reconstructed. Automated spectral recomposition helps us visualize frequency-dependent geological features on both cross sections and time slices by extracting significant frequency components. Spectral recomposition can also indicate how frequency contents attenuate with time.


next up previous Automated spectral recomposition with application in stratigraphic interpretation [pdf]

Next: Introduction Up: Reproducible Documents

2013-08-19