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The Rice Inversion Project

Published byClaire Newman Modified over 6 years ago

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Presentation on theme: "The Rice Inversion Project"— Presentation transcript:

1 The Rice Inversion Project
An automatic wave equation migration velocity analysis by differential semblance optimization The Rice Inversion Project

2 Objective Simultaneous optimization for velocity and image
Shot-record wave-equation migration.

3 Theory Nonlinear Local Optimization Remark: Objective function
Gradient of the objective function Remark: Objective function requires to be smooth . Differential semblance objective function is smooth.

4 Differential semblance criteria
z x offset image angle image z z h h

5 Objective function I : offset domain image c : velocity
h : offset parameter P : differential semblance operator || ||: L2 norm M : set of smooth velocity functions

6

7 Gradient calculation Definitions:
Downward continuation and upward continuation S0 R0 gradient derivative cross correlate* down down SZ RZ DS* DR* cross correlate up up S*z R*z image cross correlate reference field

8 Gradient smoothing using spline evaluation
Vimage I gimage spline spline* Vmodel gmodel migration differential migration* M : set of smooth velocity functions

9 Optimization cout Iout BFGS algorithm for nonlinear iteration
Objective function evaluation Gradient calculation loop Update search direction cout Iout

10 Synthetic Examples Flat reflector, constant velocity Marmousi data set

11 Experiment of flat reflector at constant velocity
Ccorrect = 2km/sec z

12 Initial iterate: Image (v0 = 1.8km/sec) Offset image Angle image
Image space: 401 by 80 Model space: 4 by 4 Offset image Angle image

13 Iteration 5: Image Offset image Angle image

14 Iterations v5: Output velocity at iteration 5 vbest - v5

15 Marmousi data set

16 Marmousi data set

17 V

18 Initial iterate: Image (v0=1.8km/sec) Offset image Angle image
Image space: 921 by 60 Model space: 6 by 6 Offset image Angle image

19 Iterate 5: Image Offset image Angle image

20 v5 - vbest iterations v5: output velocity at iteration 5
vbest: best spline interpolated velocity v5 - vbest iterations

21 Low velocity lense + constant velocity background
Vbackground = 2 km/sec

22 Seismogram Shot gathers far away from the low velocity lense
Shot gathers near the low velocity lense

23 Iteration 1 Start with v0 = 2km/sec Iteration 2 Iteration 3 Iteration 4

24

25 Conclusions Offset domain DSO is a good substitute for angle domain DSO. Image domain gradient needs to be properly smoothed. DSO is sensitive to the quality of the image. Differential semblance optimization by wave equation migration is promising.

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