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Imaging Multiple Reflections with Reverse- Time Migration Yue Wang University of Utah.

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Presentation on theme: "Imaging Multiple Reflections with Reverse- Time Migration Yue Wang University of Utah."— Presentation transcript:

1 Imaging Multiple Reflections with Reverse- Time Migration Yue Wang University of Utah

2 Outline BackgroundBackground Motivation & ObjectiveMotivation & Objective MethodologyMethodology Numerical ExamplesNumerical Examples ConclusionsConclusions

3 Forward Process Distance (km) Depth (km) 1 0 04.5 * Source Geophone Line

4 Forward Process Distance (km) Depth (km) 1 0 04.5 *  obs

5 Reverse Time Migration Distance (km) Depth (km) 1 0 04.5  obs Extrapolated Wavefield  obs Reversed traces

6 Reverse-Time Migration Extrapolated Wavefield Imaging Condition Migration Section

7 Outline BackgroundBackground Motivation & ObjectiveMotivation & Objective MethodologyMethodology Numerical ExamplesNumerical Examples ConclusionsConclusions

8 Ocean-Bottom Survey Distance (km) Depth (km) 1 0 04.5 * Source Geophone Line

9 Problem Distance (km) Depth (km) 1 0 04.5 * Receiver-side Multiples

10 Synthetic Shot Gather Time (s) Distance (km) Receiver side multiples 2 0 0.93.6

11 Field Data Time (s) Distance (m) 4 0 -80 1900 Receiver side multiples

12 Time Migration Time (s) Distance (m) 4 0 -80 1900 Receiver side multiples

13 Objective Using both primary and multiple reflections for imaging by reverse- time migration.Using both primary and multiple reflections for imaging by reverse- time migration.

14 Outline BackgroundBackground Motivation & ObjectiveMotivation & Objective MethodologyMethodology Numerical ExamplesNumerical Examples ConclusionsConclusions

15 Ocean-Bottom Survey Distance (km) Depth (km) 1 0 04.5 * Source Geophone Line

16 Ocean-Bottom Survey Distance (km) Depth (km) 1 0 0 *PV Up-going

17 Multi-Component Data pressure + particle velocity ( P & V ) ocean-bottom survey

18 Reverse Time Migration Distance (km) Depth (km) 1 0 0PV Down-going PV ( P & V Scheme )

19 Reverse Time Migration Distance (km) Depth (km) 1 0 0VV ( Particle Velocity Only )

20 Key Idea Primary + Multiple Correct Positions P & V Scheme

21 Key Idea Primary + Multiple Incorrect Positions V-Only Scheme

22 Ocean-Bottom Survey Distance (km) Depth (km) 1 0 0 *PV Up-going Waves

23 P & V Scheme Distance (km) Depth (km) 1 0 0PVPV Correct Position Down-going waves

24 Particle Velocity Only Scheme Distance (km) Depth (km) 1 0 0VV Incorrect

25 Ocean-Bottom Survey Distance (km) Depth (km) 1 0 0 *PV Down-going waves ( Multiples )

26 P & V Scheme Distance (km) Depth (km) 1 0 0PVPV Correct Position Up-going waves

27 Particle Velocity Only Scheme Distance (km) Depth (km) 1 0 0VV Incorrect

28 Outline BackgroundBackground Motivation & ObjectiveMotivation & Objective MethodologyMethodology Numerical ExamplesNumerical Examples Salt Dome Model Salt Dome Model ConclusionsConclusions

29 Salt Model Distance (km) Depth (km) 2.7 0 04.5

30 Shot Gather Normal Stress VerticalHorizontal Time (s) Distance (km) 2 0 0.93.6 0.93.6 0.93.6 Multiples

31 Kirchhoff Migration Distance (km) Depth (km) 2.5 0 0.454.05

32 Kirchhoff Migration Distance (km) Depth (km) 2.5 0 0.454.05

33 Particle Velocity Only Scheme Distance (km) Depth (km) 2.7 0 0.454.05

34 Particle Velocity Only Scheme Distance (km) Depth (km) 2.7 0 0.454.05

35 P & V Scheme Distance (km) Depth (km) 2.5 0 0.454.05

36 Distance (km) Depth (km) 2.5 0 0.454.05 P & V Scheme

37 Primary + Multiple Correct Positions Conclusion P + V RTM

38 Future Work: Field Data Test Time (s) Distance (m) 40-80 1900 Receiver side multiples

39 Acknowledgement We are grateful to the 1999 sponsors of the UTAM consortium for the financial support

40 Outline BackgroundBackground Motivation & ObjectiveMotivation & Objective MethodologyMethodology Numerical ExamplesNumerical Examples Plane-wave example Plane-wave example ConclusionsConclusions

41 Forward Process Distance Depth Up-going waves

42 P & V Scheme Distance Depth Down-going waves

43 P & V Scheme Time (s) Depth (km) 0 0.8 0 1.2 Down-going waves

44 Particle Velocity Only Scheme Distance Depth Down-going waves Up-going waves

45 Particle Velocity Only Scheme Time (s) Depth (km) 0 0.8 0 1.2 Down-going waves Up-going waves

46 P + V RTM Distance (km) Depth (km) 100 P+V Up-going waves Correct Position Distance (km) Depth (km) 1 0 0 P Down-going waves Up-going waves

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