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Closure Phase Statics Correction Closure Phase Statics Correction University of Utah Jianhua Yu.

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Presentation on theme: "Closure Phase Statics Correction Closure Phase Statics Correction University of Utah Jianhua Yu."— Presentation transcript:

1 Closure Phase Statics Correction Closure Phase Statics Correction University of Utah Jianhua Yu

2 Outline Objective Close Phase Statics Correction Examples Summary

3 Outline Objective Close Phase Statics Correction Examples Summary

4 STATICS CORRECTION PROBLEMS STATICS CORRECTION PROBLEMS Poor quality image caused by and source and receiver static errors Near-surface velocity model Irregular acquisition geometry False structure and misinterpretation

5 Objective Eliminate source and receiver time errorsEliminate source and receiver time errors First Arrival Reflection Closure phase

6 Outline Objective Close Phase Statics Correction Examples Summary

7 i+1i j+1 i-1 j j-1 Diagram of Three Pair Source and Receivers for Reflections

8 i+1 i j+1 i-1 j j-1 Diagram of Reflections After Applying “Mirror principle”

9 T i-1,1 =t (i-1,1)+  t si-1+  t r1  T i,i-1 = t (i,1) - t (i-1,1) +  t si -  t si-1 T i,1 =t (i,1)+  t si+  t r1  T i+1,i = t (i+1,2) - t (i,2) +  t si+1 -  t si  Ti-1,i+1 = t (i-1,3) - t (i+1,3) +  t si-1 -  t si+1 Closure Phase Method 1 32  t r3  t r2  t r1 i-1 ii+1  t si-1  t si  t si+1 Mirror principle t t (i,1) t t (i-1,1) Trume time

10 Closure Phase Method Moveout difference between adjacent traces

11 Closure Phase Method After NMO

12 The final estimation of static shifts at source position i+1 is: Closure Phase Method

13 Outline Objective Close Phase Statics Correction Examples Overthrust model data Saudi data Texas data Summary

14 Overthrust Data SP Time (s) 0 2.8 SP 14 2 314 2 3

15 Overthrust Result SP Time (s) 14 0 0.8 Common source gathers before (left) and after(right) eliminating source/receiver static errors 2 3 SP 14 2 3

16 Overthrust Result X (km) Time (s) 0150 0 0 2.8 Model without (left) and with (middle) shot/receiver static error, and the result after eliminating static errors

17 Outline Objective Close Phase Statics Correction Examples Overthrust model data Saudi data Texas data Summary

18 Acquisition Geometry 87 m R81R81R81R81 RmRmRmRm Rm-1Rm-1Rm-1Rm-1 R1R1R1R1 R 80 R2R2R2R2 Variable 30 m

19 Aramco Data Features: Data has strong scatter energy noiseData has strong scatter energy noise Ground rollGround roll Multiples from sand duneMultiples from sand dune First arrivals were influenced in far offsetsFirst arrivals were influenced in far offsets

20 Test of Static Correction Method on SAUDI Desert Data: Preliminary Results Two Raw CSGs Time (s) 4.0 0 X (m) 873840 874440

21 LMO Data Before and After CP Static Correction LMO Data Before and After CP Static Correction Time (ms) 160 80 Shot Number 1 2 3 4 1 2 3 4 Time (ms) 160 80 Before CP After CP

22 Stack Sections Before and After CP Static Correction Applied Time (s) 3.0 0.38 X (m) 03500 0 `````````` BB AA Not any preprocessing step was applied except band-pass filtering ``````````

23 Zoom View of Window “A” Time (s) 2.0 0.38 X (m) 15753600 1575

24 Zoom View of Window “B” Time (s) 2.5 1.3 X (m) 4002760 400

25 Outline Objective Close Phase Statics Correction Examples Overthrust model data Saudi data Texas data Summary

26 Acquisition Geometry 25 m R81R81R81R81 R 1 60 R 159 R1R1R1R1 R 80 R2R2R2R2 12.5 m 75 m

27 Time (s) 2.5 0 Traces 1 TEXAS CSG DATA 156 Ground roll

28 Time (s) 2.5 0 Trace Number 1 ZOOM VIEW OF CSG 140

29 Time (s) 0.16 0 Trace Number 1 TEXAS DATA AFTER LMO 135 Time (s) 0.16 0 No Static correction No Static correction After CP Static correction After CP Static correction

30 Time (s) 2.5 0.35 X (m) 03750 0 Stacked Section With Conventional Plus-minus method

31 Time (s) 2.5 0.35 X (m) 03750 0 Stacked Section With Closure Phase method

32 Time (s) 2.5 0.35 X (m) 1.83.7 Stacked Section With Conventional Plus-minus method

33 Time (s) 2.5 0.35 X (m) 1.83.7 Stacked Section With Closure Phase method

34 Outline Objective Close Phase Statics Correction Examples Summary

35 Summary The test results show : No need near-surface velocity model No need near-surface velocity model CP method can eliminate static shifts at source and receiver positions and improve the stacked image CP method can eliminate static shifts at source and receiver positions and improve the stacked image

36 Summary Waveform variation influences the correlation accuracy and robust. Waveform variation influences the correlation accuracy and robust. NO need to solve system of equations NO need to solve system of equations

37 What’s next Combination of refraction and reflection Improve the robustness of algorithm for noisy data Improve the robustness of algorithm for noisy data Long wavelength static correction ?

38 Acknowledgements I greatly appreciate Saudi Aramco for providing this data and permission to publishI greatly appreciate Saudi Aramco for providing this data and permission to publish I am grateful to the 2000 sponsors of the UTAM consortium for financial supportI am grateful to the 2000 sponsors of the UTAM consortium for financial support I thank all of people who give me some suggestions and help for this workI thank all of people who give me some suggestions and help for this work

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