Presentation is loading. Please wait.

Presentation is loading. Please wait.

3D Tomography using Efficient Wavefront Picking of Traveltimes Abdullah AlTheyab and G. T. Schuster King Abdullah University of Science and Technology.

Published byMervyn Chapman Modified over 8 years ago

Similar presentations

Presentation on theme: "3D Tomography using Efficient Wavefront Picking of Traveltimes Abdullah AlTheyab and G. T. Schuster King Abdullah University of Science and Technology."— Presentation transcript:

1 3D Tomography using Efficient Wavefront Picking of Traveltimes Abdullah AlTheyab and G. T. Schuster King Abdullah University of Science and Technology (KAUST) 1

2 Outline Introduction Areal Picking 3D Tomography using Areal Picks Conclusion 2

3 Introduction For conventional acquisition geometry, receiver lines are sparse. Picking is done on time- offset sections. first-arrivals x y t 3

4 Field Data Example 4 3D OBS data parameters: – 234 OBS stations – 129 source-lines – 50m inline spacing – 400m OBS spacing – 40-50m water depth Source boat sail lines Receiver stations

5 Human picking time 30,186 sections to pick, each with 360 receivers. Estimated picking time: – 2 section/minute → 251hrs – 8 hr/day: 31 days 5 12 km 0 3 Time [sec] CRG Shingling Low SNR

6 Quality Control and Cycle-skipping 12 km 0 3 Time [sec] Shingling Traveltime [sec] Traveltime Map 14 2 Distance [km] 1 3 Shot 73Shot 74Shot 75 6

7 Memory Footprint The size of the data is 80 GB (at 4ms sampling, after windowing). Interactive picking software require: – Large memory, – Swapping to hard drives. Memory access pattern for QC is complex. 7

8 Conventional Picking Approach Disadvantages: 1.Large human piking time (31 days) 2.Laborious to QC and correct picks 3.Large memory footprint (80 GB) 8

9 Outline Introduction Areal Picking 3D Tomography using Areal Picks Conclusion 9

10 Areal picking For conventional acquisition geometry, receiver lines are sparse. Picking is done on time- offset sections. first-arrivals x y t 10

11 x y t Areal picking For dense-receiver acquisition geometry We propose picking on time- slices (Areal Picking). 11

12 Areal picking For dense-receiver acquisition geometry We propose picking on time- slices (Areal Picking). y t x 12

13 Areal picking For dense-receiver acquisition geometry We propose picking on time- slices (Areal Picking). y t x 13

14 Areal picking For dense-receiver acquisition geometry We propose picking on time- slices (Areal Picking). y t x 14

15 Areal picking: Interpolation We implemented a program that does real-time interpolation. 15 Cartesian picks Polar interpolation Continuous Polygon Picks are interpolated in polar-coordinates.

16 Field Data Example 2 4 y[km] 14 x [km] 19 4 Time slice @ 0.8 sec 16

17 Field Data Example 2 4 y[km] 14 x [km] 19 4 Time slice @ 0.8 sec 17

18 Field Data Example y[km] 14 x [km] 19 4 Time slice @ 2.4 sec 18

19 Field Data Example y[km] 14 x [km] 19 4 Time slice @ 2.4 sec 19

20 Field Data Example: Human picking time 20 200 ms time-slice spacing for 5 Hz FWI. 234 shots x 15 slices/shot= 3,510 slices (vs. 30,186 sections) to pick. Estimated picking-time: – @2 slices/minute: 30 hrs – @8 hr/day: 4 days (vs. 31 days)

21 Field Data Example: Quality Control Polygon must not cross. y[km] 14 x [km] 19 4 Time slice @ 2.4 sec 21

22 Field Data Example: Quality Control Min Apparent velocity Max 22 Detect mispicks. Apparent Velocity Map Explore regional trend

23 Field Data Example: Memory footprint 80 GB → Slicing for 5Hz FWI → 2 GB Slices are spaced at ½ of the shortest period. 23

24 Outline Introduction Areal Picking 3D Tomography using Areal Picks Conclusion 24

25 Polygon resampling y[km] 14 x [km] 19 4 Picked Traveltime Map Regularized Traveltime Tomography 0 3 Traveltime [sec] 25

26 Tomography using Areal Picks y[km] 14 x [km] 19 4 Picked Traveltime Residual Regularized Traveltime Tomography -0.1 0.1 Residuals [sec] 26

27 Tomography using Areal Picks Cycle skipping Count Traveltime Error [sec] -0.50.10.5-0.10 Traveltime Error Histogram 27

28 Final Traveltime Tomogram 28 0 3.5 10 depth slice x [km] y [km] 10 inline xline 0 z [km] y [km] 0 15004500 Velocity [m/s] 018 Structural cross-section

29 Field Data Example: Waveform Comparison 29 12 km 0 3 Time [sec] Observed

30 Field Data Example: Waveform Comparison 30 12 km 0 3 Time [sec] Calculated

31 Field Data Example: Waveform Comparison 31 12 km 0 3 Time [sec] Observed

32 Field Data Example: Waveform Comparison 32 12 km 0 3 Time [sec] Calculated

33 Field Data Example: Waveform Comparison 33 12 km 0 3 Time [sec] Observed

34 Field Data Example: Waveform comparison 34 12 km 0 3 Time [sec] Calculated

35 Field Data Example: Waveform Comparison 35 12 km 0 3 Time [sec] Observed

36 Field Data Example: Waveform Comparison 36 12 km 0 3 Time [sec] Calculated

37 Outline Introduction Areal Picking 3D Tomography using Areal Picks Conclusion 37

38 Conclusions Areal picking allows for building 3D tomograms in reasonable time. Advantages of areal picking: – About 70-90% reduction in human picking time (31 vs. 4 days) – Easier QC and correct mispicks – Much lower memory footprint (80 GB vs. 2 GB) 38

39 Thank you Acknowledgments: Pemex for providing the data. Sponsors of CSIM Saudi Aramco for supporting the FWI project. Research Computing at KAUST. 39

Download ppt "3D Tomography using Efficient Wavefront Picking of Traveltimes Abdullah AlTheyab and G. T. Schuster King Abdullah University of Science and Technology."

Similar presentations

Tutorial 3 Refractor assignment, Analysis, Modeling and Statics

Tutorial 3 Refractor assignment, Analysis, Modeling and Statics
Multisource Full Waveform Inversion of Marine Streamer Data with Frequency Selection Multisource Full Waveform Inversion of Marine Streamer Data with Frequency.

Multisource Full Waveform Inversion of Marine Streamer Data with Frequency Selection Multisource Full Waveform Inversion of Marine Streamer Data with Frequency.
Using 3D Seismic Imaging for Mine and Mineral Exploration G. Schuster University of Utah.

Using 3D Seismic Imaging for Mine and Mineral Exploration G. Schuster University of Utah.
Computational Challenges for Finding Big Oil by Seismic Inversion.

Computational Challenges for Finding Big Oil by Seismic Inversion.
3D Super-virtual Refraction Interferometry Kai Lu King Abdullah University of Science and Technology.

3D Super-virtual Refraction Interferometry Kai Lu King Abdullah University of Science and Technology.
Reverse Time Migration of Multiples for OBS Data Dongliang Zhang KAUST.

Reverse Time Migration of Multiples for OBS Data Dongliang Zhang KAUST.
First Arrival Traveltime and Waveform Inversion of Refraction Data Jianming Sheng and Gerard T. Schuster University of Utah October, 2002.

First Arrival Traveltime and Waveform Inversion of Refraction Data Jianming Sheng and Gerard T. Schuster University of Utah October, 2002.
Closure Phase Statics Correction Closure Phase Statics Correction University of Utah Jianhua Yu.

Closure Phase Statics Correction Closure Phase Statics Correction University of Utah Jianhua Yu.
Interferometric Interpolation of 3D OBS Data Weiping Cao, University of Utah Oct. 29 2009.

Interferometric Interpolation of 3D OBS Data Weiping Cao, University of Utah Oct
Prestack Migration Deconvolution Jianxing Hu and Gerard T. Schuster University of Utah.

Prestack Migration Deconvolution Jianxing Hu and Gerard T. Schuster University of Utah.
Wavepath Migration versus Kirchhoff Migration: 3-D Prestack Examples H. Sun and G. T. Schuster University of Utah.

Wavepath Migration versus Kirchhoff Migration: 3-D Prestack Examples H. Sun and G. T. Schuster University of Utah.
Reduced-Time Migration of Converted Waves David Sheley and Gerard T. Schuster University of Utah.

Reduced-Time Migration of Converted Waves David Sheley and Gerard T. Schuster University of Utah.
Wave-Equation Interferometric Migration of VSP Data Ruiqing He Dept. of Geology & Geophysics University of Utah.

Wave-Equation Interferometric Migration of VSP Data Ruiqing He Dept. of Geology & Geophysics University of Utah.
Wave-Equation Interferometric Migration of VSP Data Ruiqing He Dept. of Geology & Geophysics University of Utah.

Wave-Equation Interferometric Migration of VSP Data Ruiqing He Dept. of Geology & Geophysics University of Utah.
Multiscale Waveform Tomography C. Boonyasiriwat, P. Valasek *, P. Routh *, B. Macy *, W. Cao, and G. T. Schuster * ConocoPhillips.

Multiscale Waveform Tomography C. Boonyasiriwat, P. Valasek *, P. Routh *, B. Macy *, W. Cao, and G. T. Schuster * ConocoPhillips.
Advanced Seismic Imaging GG 6770 Variance Analysis of Seismic Refraction Tomography Data By Travis Crosby.

Advanced Seismic Imaging GG 6770 Variance Analysis of Seismic Refraction Tomography Data By Travis Crosby.
Primary-Only Imaging Condition Yue Wang. Outline Objective Objective POIC Methodology POIC Methodology Synthetic Data Tests Synthetic Data Tests 5-layer.

Primary-Only Imaging Condition Yue Wang. Outline Objective Objective POIC Methodology POIC Methodology Synthetic Data Tests Synthetic Data Tests 5-layer.
3-D Migration Deconvolution Jianxing Hu, GXT Bob Estill, Unocal Jianhua Yu, University of Utah Gerard T. Schuster, University of Utah.

3-D Migration Deconvolution Jianxing Hu, GXT Bob Estill, Unocal Jianhua Yu, University of Utah Gerard T. Schuster, University of Utah.
Improve Migration Image Quality by 3-D Migration Deconvolution Jianhua Yu, Gerard T. Schuster University of Utah.

Improve Migration Image Quality by 3-D Migration Deconvolution 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.

Similar presentations

Ads by Google