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Making Marchenko imaging work with field data and the bumpy road to 3D

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Presentation on theme: "Making Marchenko imaging work with field data and the bumpy road to 3D"— Presentation transcript:

1 Making Marchenko imaging work with field data and the bumpy road to 3D
Alex Jia*, Antoine Guitton, and Roel Snieder Center for Wave Phenomena, Colorado School of Mines

2

3 RTM Marchenko Imaging pros whole model easy implementation target orientated remove artifacts by internal multiples cons artifacts by internal multiples require wavelet learning curve (e.g. acquisition geometry)

4 outline Complications: Marchenko imaging: how and why?
missing near offsets data calibration Why is 3D Marchenko necessary and challenging?

5 surface response to virtual source
Marchenko equations background velocity model surface data surface response to virtual source (reverse VSP data) first arrival

6 up-going and down-going Green’s function
Marchenko equations background velocity model surface data up-going and down-going Green’s function first arrival

7 up-going and down-going Green’s function
Marchenko equations background velocity model surface data up-going and down-going Green’s function Marchenko image first arrival

8 1 G+ 2 3

9 a b G-

10 missing near offsets: 7 traces, 214 m

11 retrieved Green’s function
full offset missing near offsets difference

12 missing near offset stronger for shallow events and near offset events
maximum missing near offset D: depth of reflector T: dominant wave period assumption: hyperbolic assumption for flat multi-layered earth (details in CWP report)

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14 full offset missing near offsets RTM

15 data calibration input 1: surface reflection response
input 2 : first arrival amplitude should match

16 retrieved Green’s function
scale=0.5 scale=1 scale=1.5

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18 data calibration scale=0.5 scale=1 scale=1.5

19 * synthetic first arrival field 0.001 0.001
The question you may ask is how we calibrate the field data? Because we have a background velocity model and we use this model to construct our first arrival. We can also use this model to simulate surface data with amplitudes that can match the first arrival. Thus, we now have the simulated surface data that has the required amplitude, and we have the field data we need to calibrated. Hence, we can obtain a scaling factor by comparing the amplitude the field data and modelled data, and use this scaling factor to calibrate the field data.

20 0.001 synthetic first arrival 0.001 * field (scaled)

21 2D can be deceptive

22 Green’s function in 3D structure
x=0.5, y=1, z=0.5 x=0.5, y=1, z=0 Goal: retrieve the Green’s function from a VS at (x=0.5, y=1, z=0.5) to a surface receiver at (x=0.5, y=1,z=0)

23 retrieved x=0.5, y=1, z=0.5 x=0.5, y=1, z=0

24 retrieved x=0.5, y=1, z=0.5 x=0.5, y=1, z=0

25 retrieved modelled x=0.5, y=1, z=0.5 x=0.5, y=1, z=0

26 (dense in-line, sparse x-line)
3D Marchenko ocean bottom data streamer data (dense in-line, sparse x-line) ( (Wang et al. 2009)

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