Presentation is loading. Please wait.

Presentation is loading. Please wait.

A cross-equalization processing flow for off-the-shelf 4-D seismic data James Rickett Stanford University David E. Lumley Chevron Petroleum Technology.

Published byCornelia French Modified over 7 years ago

Similar presentations

Presentation on theme: "A cross-equalization processing flow for off-the-shelf 4-D seismic data James Rickett Stanford University David E. Lumley Chevron Petroleum Technology."— Presentation transcript:

1 A cross-equalization processing flow for off-the-shelf 4-D seismic data James Rickett Stanford University David E. Lumley Chevron Petroleum Technology Company

2 A cross-equalization processing flow for off-the-shelf 4-D seismic data James Rickett Stanford University David E. Lumley Chevron Petroleum Technology Company

3 Summary Gulf of Mexico dataset Motivation Cross-equalization issues Processing flow Results & conclusions

4

5 1979 survey

6 1991 survey

7 Motivation Cross-equalization important for 4D study –Remove processing/acquisition differences –Remaining differences are due to production Post-stack vs pre-stack –Pre-stack data not easily available –Post-stack analysis quicker and cheaper

8

9 Cross-equalization issues Geometry/binning Wavelet/spectra Gain functions Differential phase/statics Migration imaging/positioning

10

11 Cross-equalization issues Geometry/binning Wavelet/spectra Gain functions Differential phase/statics Migration imaging/positioning

12 34  difference in azimuth Bin-size: 41 x 41ft vs. 247 x 82ft 1979 1991

13 Cross-equalization issues Geometry/binning Wavelet/spectra Gain functions Differential phase/statics Migration imaging/positioning

14 Before matched-filteringAfter matched-filtering 1979 1991

15 Cross-equalization issues Geometry/binning Wavelet/spectra Gain functions Differential phase/statics Migration imaging/positioning

16 19791991Envelope

17 Cross-equalization issues Geometry/binning Wavelet/spectra Gain functions Differential phase/statics Migration imaging/positioning

18

19 Cross-equalization issues Geometry/binning Wavelet/spectra Gain functions Differential phase/statics Migration imaging/positioning

20 1979 survey1991 survey

21 Cross-equalization flow Survey co-alignment Global operators –Matched-filtering & gain correction Non-stationary operators –Matched-filtering & gain correction Warping

22 Cross-equalization flow Survey co-alignment Global operators –Matched-filtering & gain correction Non-stationary operators –Matched-filtering & gain correction Warping

23 Survey co-alignment 1979 survey –Bandpass and gain correction –Resampled from 4 to 6ms 1991 survey –Remapped onto 1979 grid –Spatial anti-alias filter –Rotation with linear interpolation Common window and mask

24 Cross-equalization flow Survey co-alignment Global operators –Matched-filtering & gain correction Non-stationary operators –Matched-filtering & gain correction Warping

25 19791991difference After co-alignment...

26 Cross-equalization flow Survey co-alignment Global operators –Matched-filtering & gain correction Non-stationary operators –Matched-filtering & gain correction Warping

27 Global corrections Matched-filter –Bandwidth and phase –Least squares –Bulk shift Amplitude scale

28 19791991difference After co-alignment...

29 19791991difference After global corrections...

30 Cross-equalization flow Survey co-alignment Global operators –Matched-filtering & gain correction Non-stationary operators –Matched-filtering & gain correction Warping

31 Non-stationary matched filtering Separate filters for each trace Design window: –0.5 s to 2 s depth (reservoir at 3 s) –3 traces wide Short operator (23 points)

32 Cross-equalization flow Survey co-alignment Global operators –Matched-filtering & gain correction Non-stationary operators –Matched-filtering & gain correction Warping

33 Amplitude balancing Corrects for –Different T.V. gain functions –Incorrect amplitudes from matched-filters Assume signal >> noise –Scale data based on R.M.S. energy

34 19791991difference After global corrections...

35 19791991difference After non-stationary filtering/gain correction...

36 Cross-equalization flow Survey co-alignment Global operators –Matched-filtering & gain correction Non-stationary operators –Matched-filtering & gain correction Warping

37 Different velocity fields –Effects positioning of imaged events –Need residual migration operator  v unknown –Need estimate operator from the data

38 Warping Algorithm –Calculate local 3-D cross-correlation functions –Pick maxima –Obtain smoothly varying warp function –Apply vector shifts by interpolation

39 Typical “warp function”... (magnified x2)

40 After non-stationary filtering/gain correction... 19791991difference

41 19791991difference After warping...

42 After realignment to common grid After global corrections

43 After non-stationary corrections After warping

44 "Normalized difference energy" = RMS(difference)  [ RMS(79 survey) + RMS(91 survey) ]

45 After global corrections After non-stationary corrections After warping After co-alignment Normalized difference energy

46 Conclusions Cross-equalization processing flow important for 4-D seismic monitoring Global operators not sufficient Spatially-variable operators required –Balance non-stationarity vs. degrees of freedom Warping –Residual map migration to correct for event mispositioning (e.g. due to migration velocity)

47 Conclusions Reduced non-reservoir differences using physical processing operators Enhanced reservoir differences –Now ready for 4-D interpretation

48 Acknowledgements CPTC’s 4-D team in La Habra Chevron for providing the data Sponsors of Stanford Exploration Project

Download ppt "A cross-equalization processing flow for off-the-shelf 4-D seismic data James Rickett Stanford University David E. Lumley Chevron Petroleum Technology."

Similar presentations

ECE 8443 – Pattern Recognition ECE 8423 – Adaptive Signal Processing Objectives: The Linear Prediction Model The Autocorrelation Method Levinson and Durbin.

ECE 8443 – Pattern Recognition ECE 8423 – Adaptive Signal Processing Objectives: The Linear Prediction Model The Autocorrelation Method Levinson and Durbin.
11/11/02 IDR Workshop Dealing With Location Uncertainty in Images Hasan F. Ates Princeton University 11/11/02.

11/11/02 IDR Workshop Dealing With Location Uncertainty in Images Hasan F. Ates Princeton University 11/11/02.
(t,x) domain, pattern-based ground roll removal Morgan P. Brown* and Robert G. Clapp Stanford Exploration Project Stanford University.

(t,x) domain, pattern-based ground roll removal Morgan P. Brown* and Robert G. Clapp Stanford Exploration Project Stanford University.
Designer Seismic VSP Ernie Majer (LBNL) J. Queen ( Hi –Q Geophysics) T. Dalely (LBNL) Roy Long ( DOE)

Designer Seismic VSP Ernie Majer (LBNL) J. Queen ( Hi –Q Geophysics) T. Dalely (LBNL) Roy Long ( DOE)
Multi-Component Seismic Data Processing

Multi-Component Seismic Data Processing
Introduction to GeoProbe

Introduction to GeoProbe
Realigning and Unwarping MfD

Realigning and Unwarping MfD
The recovery of seismic reflectivity in an attenuating medium Gary Margrave, Linping Dong, Peter Gibson, Jeff Grossman, Michael Lamoureux University of.

The recovery of seismic reflectivity in an attenuating medium Gary Margrave, Linping Dong, Peter Gibson, Jeff Grossman, Michael Lamoureux University of.
74 th EAGE Conference & Exhibition incorporating SPE EUROPEC 2012 Automated seismic-to-well ties? Roberto H. Herrera and Mirko van der Baan University.

74 th EAGE Conference & Exhibition incorporating SPE EUROPEC 2012 Automated seismic-to-well ties? Roberto H. Herrera and Mirko van der Baan University.
Prestack Stolt residual migration Paul Sava* Stanford University Biondo Biondi Stanford University.

Prestack Stolt residual migration Paul Sava* Stanford University Biondo Biondi Stanford University.
Joint Migration of Primary and Multiple Reflections in RVSP Data Jianhua Yu, Gerard T. Schuster University of Utah.

Joint Migration of Primary and Multiple Reflections in RVSP Data Jianhua Yu, Gerard T. Schuster University of Utah.
Bedrock Delineation by a Seismic Reflection/Refraction Survey at TEAD Utah David Sheley and Jianhua Yu.

Bedrock Delineation by a Seismic Reflection/Refraction Survey at TEAD Utah David Sheley and Jianhua Yu.
Analytical image perturbations for wave-equation migration velocity analysis Paul Sava & Biondo Biondi Stanford University.

Analytical image perturbations for wave-equation migration velocity analysis Paul Sava & Biondo Biondi Stanford University.
Autocorrelogram Migration of Drill-Bit Data Jianhua Yu, Lew Katz, Fred Followill, and Gerard T. Schuster.

Autocorrelogram Migration of Drill-Bit Data Jianhua Yu, Lew Katz, Fred Followill, and Gerard T. Schuster.
Xi’an Jiaotong University 1 Quality Factor Inversion from Prestack CMP data using EPIF Matching Jing Zhao, Jinghuai Gao Institute of Wave and Information,

Xi’an Jiaotong University 1 Quality Factor Inversion from Prestack CMP data using EPIF Matching Jing Zhao, Jinghuai Gao Institute of Wave and Information,
Youli Quan & Jerry M. Harris

Youli Quan & Jerry M. Harris
MD + AVO Inversion Jianhua Yu, University of Utah Jianxing Hu GXT.

MD + AVO Inversion Jianhua Yu, University of Utah Jianxing Hu GXT.
Interferometric Multiple Migration of UPRC Data

Interferometric Multiple Migration of UPRC Data
Autocorrelogram Migration for Field Data Generated by A Horizontal Drill-bit Source Jianhua Yu, Lew Katz Fred Followill and Gerard T. Schuster.

Autocorrelogram Migration for Field Data Generated by A Horizontal Drill-bit Source Jianhua Yu, Lew Katz Fred Followill and Gerard T. Schuster.
Wave-equation migration velocity analysis Paul Sava* Stanford University Biondo Biondi Stanford University.

Wave-equation migration velocity analysis Paul Sava* Stanford University Biondo Biondi Stanford University.

Similar presentations

Ads by Google