1. Thin sub-resolution shaly-sands
Well logs
Seismic
Shale Cap Rock
Shale Underburden
Thin sub-resolution shaly-sands

2. Distance based sensitivity analysis and cascaded interpretation scheme for subtle seismic signatures in thin shaly-sand reservoirs
Piyapa Dejtrakulwong1, Tapan Mukerji2, and Gary Mavko1
1Stanford Rock Physics Laboratory (SRB),
Department of Geophysics,
2Stanford Center for Reservoir Forecasting (SCRF),
Department of Energy Resources and Engineering,
Stanford University

3. Motivation Limitation in seismic resolvability
Interpretations of the sub-resolution layers
Goal: To infer properties and understand effects of spatial patterns of thin shaly-sand reservoirs with statistical distance-based attributes

4. Distance-based seismic attributes
Seismic signatures and statistical attributes extracted from multiple realizations of thin sand-shale sequences.
Distance-based feature extraction
Distance based sensitivity analysis

5. Thin sand-shale sequences Attributes MDS-Kernel
Workflow
Markov Chains
Rock Physics
Sand/shale model
Thin sand-shale sequences
Interpretation
Net-to-gross ratios
Saturations
Feature Extraction
Attributes MDS-Kernel
Seismic Responses

6. Thin sand-shale sequences
Workflow
Markov Chains
Thin sand-shale sequences

7. Markov chain for lithologies
Discrete states: sand, shaly sand, sandy shale, shale
Transition probability matrix:
100 m

8. Markov chain for lithologies
Discrete states: sand, shaly sand, sandy shale, shale
Thin layers: thickness = 0.5m
Wavelength/thickness ~ 100
(sub-resolution)
100 m

9. Retrograding Prograding Aggrading
Transition Matrices
Retrograding Prograding Aggrading
(fining-upwards) (coarsening-upwards)
Fixed

10. Thin sand-shale sequences
Workflow
Markov Chains
Rock Physics
Sand/shale model
Thin sand-shale sequences

11. Properties from rock physics
Sand Shaly-sand Sandy-Shale Shale
Dvorkin and Gutierrez (2001)

12. Properties from rock physics
Marion (1990) and Yin (1992)

13. Thin sand-shale sequences
Workflow
Markov Chains
Rock Physics
Sand/shale model
Thin sand-shale sequences
Seismic Responses

14. Generate Seismic Response
Full waveform, normally-incident, reflected seismograms are simulated using the Kennett algorithm (Kennett, 1983) with a 30-Hz, zero-phase Ricker wavelet
Standard convolution model does not handle
sub-resolution layers correctly

15. Generate Seismic Response
Multiple realizations (Monte Carlo simulation)

16. Thin sand-shale sequences
Workflow
Markov Chains
Rock Physics
Sand/shale model
Thin sand-shale sequences
Feature Extraction
Attributes MDS/KPCA
Seismic Responses

17. Projections of seismograms
Eigen decompose
Compute all pairwise distance/dissimilarity between seismograms
Construct dissimilarity/kernel matrix
Results: projections of input seismograms onto selected principal coordinates/components

18. Projections of seismograms
Eigen decompose
Compute all pairwise distance/dissimilarity between seismograms
Construct dissimilarity/kernel matrix
Configuration of points color-coded by net-to-gross ratios or other properties

19. Projections of seismograms
Eigen decompose
Compute all pairwise distance/dissimilarity between seismograms
Construct dissimilarity/kernel matrix
Configuration of points color-coded by net-to-gross ratios or other properties

20. Projections of seismograms?
Eigen decompose
Compute all pairwise distance/dissimilarity between seismograms
Construct dissimilarity/kernel matrix
Configuration of points color-coded by net-to-gross ratios or other properties

21. Kernel functions Gaussian kernel
Dynamic similarity kernel (Yan et al., 2006)
Inverse multi-quadric kernel
Polynomial kernel
(Li et al., 2003)
and Δm = {the smallest m δ’s of (δ1,…, δn)}

22. Net-to-gross ratio discrimination
Classification of 3 NTG classes: high, medium, low
Stratified 10-fold cross validation

23. Net-to-gross ratio discrimination
Kernel
Gaussian
Dynamic similarity
Inverse multi-quadric
Polynomial
Classification
success rate
81%
90%
79%
59%
Classification of 3 NTG classes
Stratified 10-fold cross validation

24. Interpreting seismic signatures??
Time
Coordinate 2 X ??
Coordinate 1
well unknown
N/G

25. Interpreting seismic signatures
Good discrimination, but for fixed overburden/underburden impedance

26. Seismic signatures in subresolution shaly sands
Seismic section
Shale Cap Rock
Shale underburden
Thin sub-resolution shaly-sands
Overburden and underburden impedance contrast /Overall thickness
Overwhelm subtle signatures of net-to-gross/saturation

27. Seismic signatures in subresolution shaly sands
Overburden impedance multiplier
Underburden impedance multiplier
Overall thickness

28. Seismic signatures in subresolution shaly sands
NTG
Vary:
Overburden impedance multiplier
Underburden impedance multiplier
Overall thickness
NTG
No discrimination of net-to-gross ratio

29. Distance based sensitivity analysis (dGSA) of
seismic signatures in subresolution shaly sands
Parameters:
Overburden impedance multiplier
Underburden impedance multiplier
Overall thickness
NTG
3 classes in MDS space
Distance between class-conditioned CDFs and prior CDF of each parameter.

30. Distance based sensitivity analysis (dGSA) of
seismic signatures in subresolution shaly sands

31. Distance based sensitivity analysis of
seismic signatures in subresolution shaly sands
Underburden
Overburden
Parameters:
Overburden impedance multiplier
Underburden impedance multiplier
Overall thickness
NTG
Thickness
NTG

32. Cascaded interpretation of
seismic signatures in subresolution shaly sands
Step through sensitive parameters:
For each seismic data trace:
get posterior density of sensitive parameters in MDS space
vary sensitive parameters within narrow posterior
get density of desired subtle parameter from new MDS plot

33. Cascaded interpretation of
seismic signatures in subresolution shaly sands
Color: NTG
Color: NTG
Good discrimination
Non-stationary

34. Cascaded interpretation of
seismic signatures in subresolution shaly sands

35. Conclusions Seismic attributes from distance-based feature extraction
Distance-based sensitivity analysis and cascaded approach can be applied to extract subtle attributes in thin shaly-sand reservoirs.

36. Acknowledgements
Stanford Center for Reservoir Forecasting (SCRF); Stanford Rock Physics and Borehole Geophysics project (SRB)

37. Using distance-based sensitivity analysis to interpret seismic signatures of thin shaly-sand reservoirs
Piyapa Dejtrakulwong1, Tapan Mukerji2, and Gary Mavko1
1Stanford Rock Physics Laboratory (SRB),
Department of Geophysics,
2Stanford Center for Reservoir Forecasting (SCRF),
Department of Energy Resources and Engineering,
Stanford University