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1.5 -1.5 6.0-6.0 2100 Depth (m) Time (s) Raw Seismograms 0 2100 Four-Layer Sand Channel Model 0 0 0.8 Midpoint (m)

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Presentation on theme: "1.5 -1.5 6.0-6.0 2100 Depth (m) Time (s) Raw Seismograms 0 2100 Four-Layer Sand Channel Model 0 0 0.8 Midpoint (m)"— Presentation transcript:

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2 1.5 -1.5 6.0-6.0 2100 Depth (m) Time (s) Raw Seismograms 0 2100 Four-Layer Sand Channel Model 0 0 0.8 Midpoint (m)

3 Interferometric Seismic Imaging J. Yu, J. Sheng, and G. Schuster

4 Claerbout, Katz, 70’s xx Earthquake 1900’s xx Utah+LLNL 1997 Migrate Claerbout, Rickett 1999 xyxyxyxy xyxyxyxyMigrate Arbitrary Unknown Src V(z) V(x,y,z) W(t) Location W(t) Location NOYESYESYES NO YESYESYES YES/NO YESNO? NOYESYES YESNO YES YES YES SELECTIVE HISTORY PASSIVE IMAGING Validity

5 Outline Passive data for IVSP while Drilling Imaging of Free Surface CDP Multiples Imaging of Hydo-Frac Location Transmission PS Migration Interferometric Principle: Interferometric Principle: Time Diff. between Arrivals Structure Diff. Interferometric Imaging Applications: Interferometric Imaging Applications:

6 Interference Pattern Optical Lens LASER t

7 Interference Pattern Optical Lens ss t LASER Lens Deformation Time Differences

8 Outline Passive data for IVSP while Drilling Interferometric Principle: Interferometric Principle: Time Diff. between Arrivals Structure Diff. Interferometric Imaging Applications: Interferometric Imaging Applications:

9 Seismic Ghost Reflection Direct Ghost ? Find R(x,z) but not know source location

10 Direct Ghost 12Directx Directx Master Seismic Ghost Reflection Seismic Interferogram: Correlate Traces t }M m(x) = (g, t + t ) gx g MxMxMxMxgx M Kirchhoff Migrate psuedo-shot gathers Kirchhoff Migrate psuedo-shot gathers

11 Geological Model 0 Depth (m) 3 40 X (m) V1 V2 V4 V3 V5 V6

12 Shot Gather and Crosscorrelogram 1 200 0 4 Time (s) 1 200 0 4 Time (s) Traces CSG 10 and Master trace at 80 Traces

13 Crosscorrelogram Migration Results 1.6 2.1 0 2.2 Time (s) X (km) 1.6 2.1 X (km) With primaryWithout primary

14 Source Geophone Bit Position? Problems in RVSPWD Pilot signal? Wavelet ?

15 Well Drill bit Receiver Primary Direct Wave Ghost What is Joint Migration

16 Acquisition Survey 0 04.5 -5 East (kft) North (kft) Well Rig 3C Receivers Drill bit 10 Depth (kft) 0

17 Autocorrelograms of CSG 96 1 10 0 4 Time (s) 1 10 8 s 12 s16 s

18 Acquisition Survey Map Well Rig 3C Receivers Drill bit 0 0 150030004500 -5000 East (ft) North (ft) C Line AC4

19 3.0 2.0 1.0 Time (s) SP1255 1235 1215 Drilling hole Joint Migration ( insert) and CDP Section

20 Outline Passive data for IVSP while Drilling Imaging of Free Surface CDP Multiples Interferometric Principle: Interferometric Principle: Time Diff. between Arrivals Structure Diff. Interferometric Imaging Applications: Interferometric Imaging Applications:

21 Primary Ghost 12 Free-Surface Multiple

22 Primary Ghost 12 x PrimaryxPrimary Seismic Interferogram: Correlate Traces Caution: Ghostx Primary = R 3 t } m(x) = (g, t + t ) gx g MxMxMxMxgx M Kirchhoff Migrate psuedo-shot gathers Kirchhoff Migrate psuedo-shot gathers

23 SEG/EAGE Salt Model 0 600 1200 1800 2400 Depth (m) 3000 3600 0 5000 10000 15000 Distance (m) 320 shots 176 traces per shot

24 Kirchhoff Image 0 600 1200 1800 2400 Depth (m) 3000 3600 0 5000 10000 15000 Distance (m)

25 XcorM0 600 1200 1800 2400 Depth (m) 3000 3600 0 5000 10000 15000 Distance (m)

26 0 600 1200 1800 2400 Depth (m) 3000 3600 0 5000 10000 15000 Distance (m) KMXcorM

27 Kirchhoff Image 0 600 1200 1800 2400 Depth (m) 3000 3600 0 5000 10000 15000 Distance (m)

28 Outline Passive data for IVSP while Drilling Imaging of Free Surface CDP Multiples Imaging of Hydo-Frac Location Interferometric Principle: Interferometric Principle: Time Diff. between Arrivals Structure Diff. Interferometric Imaging Applications: Interferometric Imaging Applications:

29 Hydro-Fracturing=Unknown Source ? P P P P x12?

30 P S P P MasterP*P P*P x12 Hydro-Fracturing=Unknown Source t } m(x) = (g, t - t ) gx g MxMxMxMxgx M Kirchhoff Migrate psuedo-shot gathers Kirchhoff Migrate psuedo-shot gathers Difference between Paths

31 -1.5 0 2100 2100 m 70 Ringy 30 Hz Seismograms 0.8 0 Time (s) 1.0 0 2100 m 0 1.0 1.0 Kirchhoff Migration Image Correlogram Migration Image Midpoint (m)

32 1.5 -1.5 Migration Image: 1-s Stack 6.0 -6.0 Migration Image: 40-s Stack 0 2100 2100 m 70 Raw Seismograms 0.8 0 Time (s) 1.0 0 2100 m 0 Migration Image: 40-s Stack Migration Image: 1-s Stack

33 Outline Passive data for IVSP while Drilling Imaging of Free Surface CDP Multiples Imaging of Hydo-Frac Location Transmission PS Migration Interferometric Principle: Interferometric Principle: Time Diff. between Arrivals Structure Diff. Interferometric Imaging Applications: Interferometric Imaging Applications:

34 Seismic P and PS Transmission S P P S ? Find R(x,z)

35 S P P S MasterS*S P*S Seismic P and PS Transmission P and PS Transmission Interferograms P and PS Transmission Interferograms x12 t } m(x) = (g, t - t ) gx g MxMxMxMx M Kirchhoff Migrate psuedo-shot gathers Kirchhoff Migrate psuedo-shot gathers Difference between Paths

36 0 km 200 km 0 s 1.6 s

37 2. Possible Applications: Horizontal Drill Bit Imaging, CDP Mult. Reservoir Monitoring, Mars/Sun Seismology 2 3. Limitations: 3. Limitations: Virtual Multiples Reflectivity Imaging > Source Imaging N Traces N Correlograms Coherent Noise Summary m(x) = (g, t + t ) g gx MxMxMxMx M 1. New Passive Seismic Imaging Capability: Valid for V(x,y,z) Arbitrary Sources Src & R Images Poststack & Prestack

38 Acknowledgements Thanks for support of UTAM sponsors. Thank J. Rickett and J. Claerbout for fruitful discussions. fruitful discussions.

39 Reduced-Time Migration Shift Traces by R1 Traveltime R1 Traveltime R1 R2 Mitigate Src-Rec Statics m(x)= d(x, t + t - t ) sxgxred.

40 Interference Pattern Phase Difference Phase of Rays with Common Path Cancels We only “see” Phase Difference

41 Outline Interferometric Principle: Phase Differences Interferometric Principle: Phase Differences Synthetic Data Results Synthetic Data Results Passive Seismic Data: Ghost Reflection Imaging Passive Seismic Data: Ghost Reflection Imaging CDP Multiple Data: Ghost Reflection Imaging CDP Multiple Data: Ghost Reflection Imaging Synthetic Data Results Synthetic Data Results Source Imaging & Transmission PS Imaging Source Imaging & Transmission PS Imaging Summary Summary

42 1.5 -1.5 6.0-6.0 2100 Depth (m) Time (s) Raw Seismograms 0 2100 Four-Layer Sand Channel Model 0 0 0.8 Midpoint (m)

43 Outline Interferometric Principle: Phase Differences Interferometric Principle: Phase Differences Synthetic Data Results Synthetic Data Results Passive Seismic Data: Ghost Reflection Imaging Passive Seismic Data: Ghost Reflection Imaging

44 Outline Interferometric Principle: Phase Differences Interferometric Principle: Phase Differences Synthetic Data Results Synthetic Data Results Passive Seismic Data: Ghost Reflection Imaging Passive Seismic Data: Ghost Reflection Imaging CDP Multiple Data: Ghost Reflection Imaging CDP Multiple Data: Ghost Reflection Imaging

45 Outline Interferometric Principle: Phase Differences Interferometric Principle: Phase Differences Synthetic Data Results Synthetic Data Results Passive Seismic Data: Ghost Reflection Imaging Passive Seismic Data: Ghost Reflection Imaging CDP Multiple Data: Ghost Reflection Imaging CDP Multiple Data: Ghost Reflection Imaging Synthetic Data Results Synthetic Data Results

46 Outline Interferometric Principle: Phase Differences Interferometric Principle: Phase Differences Synthetic Data Results Synthetic Data Results Passive Seismic Data: Ghost Reflection Imaging Passive Seismic Data: Ghost Reflection Imaging CDP Multiple Data: Ghost Reflection Imaging CDP Multiple Data: Ghost Reflection Imaging Synthetic Data Results Synthetic Data Results Source Imaging & Transmission PS Imaging Source Imaging & Transmission PS Imaging

47 Outline Interferometric Principle: Phase Differences Interferometric Principle: Phase Differences F.S. CDP Multiples IVSPWD ? ? ? ? F.S. CDP Multiple Migration F.S. CDP Multiple Migration

48 Outline Interferometric Principle: Phase Differences Interferometric Principle: Phase Differences F.S. CDP Multiples ? IVSPWD ? Hydro-Frac ? ? ? ? ? Locating Hydro-Fractures in EOR Locating Hydro-Fractures in EOR

49 ? Outline Interferometric Principle: Phase Differences Interferometric Principle: Phase Differences F.S. CDP Multiples ? IVSPWD ? Hydro-Frac ? PS Transmission Migration Migration PS ? ? ? ? ? PS Transmission Migration PS Transmission Migration

50 ? Outline Interferometric Principle: Phase Differences Interferometric Principle: Phase Differences Passive Seismic Data: Ghost Reflection Imaging Passive Seismic Data: Ghost Reflection ImagingIVSPWD ? ?

51 Outline Interferometric Principle: Phase Differences Interferometric Principle: Phase Differences F.S. CDP Multiples ? IVSPWD ? Hydro-Frac ? ? ? ? ? Locating Hydro-Fractures in EOR Locating Hydro-Fractures in EOR

52 Outline Interferometric Principle: Phase Differences Interferometric Principle: Phase Differences F.S. CDP Multiples IVSPWD ? ? ? ? ? Locating Hydro-Fractures in EOR Locating Hydro-Fractures in EOR

53 Outline Interferometric Principle: Phase Differences Interferometric Principle: Phase Differences F.S. CDP Multiples ? IVSPWD ? Hydro-Frac ? ? ? ? ? PS Transmission Migration PS Transmission Migration

54 Outline Interferometric Principle: Phase Differences Interferometric Principle: Phase Differences F.S. CDP Multiples ? IVSPWD ? Hydro-Frac ? PS Transmission Migration MigrationPS ? ? ? ? ? ? PS Transmission Migration PS Transmission Migration

55 Crosscorrelogram R*G Migration 1. Construct M pseudo-shot gathers (g, t ) M m(x) = (g, t + t ) gx g MxMxMxMxgx M 2. Migrate psuedo-shot gathers by sum M, g M shifted time shifted time R G R*R R*G

56 Outline Interferometric Principle: Phase Differences Interferometric Principle: Phase DifferencesIVSPWD ? ? ? F.S. CDP Multiple Migration F.S. CDP Multiple Migration

57 Outline Interferometric Principle: Phase Differences Interferometric Principle: Phase Differences Passive Seismic Data: Ghost Reflection Imaging Passive Seismic Data: Ghost Reflection Imaging F.S. CDP Multiples IVSPWD ? ? ? ? ? F.S. CDP Multiple Migration F.S. CDP Multiple Migration

58 Direct Ghost Specular Ray Ray Master DG

59 Ghost Direct D*D D*G

60 Crosscorrelogram R*G Migration 1. Construct N pseudo-shot gathers (g, t ) N m(x) = (g, t + t ) gx g NxNxNxNxgx N 2. Migrate psuedo-shot gathers by sum N, g N shifted time shifted time MP

61 0 2100 Midpoint (m) 2100 0 Depth (m) 1.5 -1.5 6.0-6.0 70 Raw Seismograms 0.8 0 Time (s) 4-Layer Model

62 0 2100 Midpoint (m) 2100 0 Depth (m) 1.5 -1.5 6.0-6.0 70 Raw Seismograms 0.8 0 Time (s) R G 4-Layer Model

63 0 2100 Midpoint (m) 2100 0 Depth (m) 1.5 -1.5 6.0-6.0 70 Raw Seismograms 0.8 0 Time (s) Correlogram Migration Image Others Imaged Incorrectly Ghosts Imaged Correctly

64 1.5 -1.5 6.0-6.0 0 0.8 0 2100 Depth (m) Time (s) Raw Seismograms 0 2100 Four-Layer Sand Channel Model 0 0 0.8 Midpoint (m)

65 1.5 -1.5 6.0-6.0 0 0.8 0 2100 Depth (m) Time (s) 0 2100 Raw Seismograms Migration Image: 1-s Stack Midpoint (m)

66 0 2100 Midpoint (m) 2100 0 Depth (m) 1.5 -1.5 6.0-6.0 70 Raw Seismograms 0.8 0 Time (s) Migration Image: 50 1-s Stacks

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