论文信息 - Application of the Empirical Mode Decomposition and Hilbert-Huang Transform to Seismic Reflection Data

Application of the Empirical Mode Decomposition and Hilbert-Huang Transform to Seismic Reflection Data

Advancements in signal processing may allow for improved imaging and analysis of complex geologic targets found in seismic reflection data. A recent contribution to signal processing is the empirical mode decomposition (EMD) which combines with the Hilbert transform as the Hilbert-Huang transform (HHT). The EMD empirically reduces a time series to several subsignals, each of which is input to the same time-frequency environment via the Hilbert transform. The HHT allows for signals describing stochastic or astochastic processes to be analyzed using instantaneous attributes in the time-frequency domain. The HHT is applied herein to seismic reflection data to: (1) assess the ability of the EMD and HHT to quantify meaningful geologic information in the time and time-frequency domains, and (2) use instantaneous attributes to develop superior filters for improving the signal-to-noise ratio. The objective of this work is to determine whether the HHT allows for empirically-derived characteristics to be used in filter design and application, resulting in better filter performance and enhanced signal-to-noise ratio. Two data sets are used to show successful application of the EMD and HHT to seismic reflection data processing. Nonlinear cable strum is removed from one data set while the other is used to show how the HHT compares to and outperforms Fourier-based processing under certain conditions.

[1] S. S. West. THREE‐LAYER RESISTIVITY CURVES FOR THE ELTRAN ELECTRODE CONFIGURATION , 1940 .

[2] Paulo Gonçalves,et al. Empirical Mode Decompositions as Data-Driven Wavelet-like Expansions , 2004, Int. J. Wavelets Multiresolution Inf. Process..

[3] Richard G. Baraniuk,et al. Empirical mode decomposition based time-frequency attributes , 1999 .

[4] Charles Hewitt Dix. ON THE MINIMUM OSCILLATORY CHARACTER OF SPHERICAL SEISMIC PULSES , 1949 .

[5] C.E. Shannon,et al. Communication in the Presence of Noise , 1949, Proceedings of the IRE.

[6] Gabriel Rilling,et al. Empirical mode decomposition as a filter bank , 2004, IEEE Signal Processing Letters.

[7] C. E. SHANNON,et al. A mathematical theory of communication , 1948, MOCO.

[8] Thomas M. McGee. Pushing the Limits of High-Resolution in Marine Seismic Profiling , 2000 .

[9] Gabriel Rilling,et al. Detrending and denoising with empirical mode decompositions , 2004, 2004 12th European Signal Processing Conference.

[10] D. Slepian,et al. On bandwidth , 1976, Proceedings of the IEEE.

[11] N. Huang,et al. The empirical mode decomposition and the Hilbert spectrum for nonlinear and non-stationary time series analysis , 1998, Proceedings of the Royal Society of London. Series A: Mathematical, Physical and Engineering Sciences.

[12] James H. Knapp,et al. Geophysical evidence for gas hydrates in the deep water of the South Caspian Basin, Azerbaijan , 2001 .