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Automatic Wave Equation Migration Velocity Analysis Peng Shen, William. W. Symes HGRG, Total E&P CAAM, Rice University This work supervised by Dr. Henri Calandra at Total E&P Thank to Dr. Scott Morton at Amerada Hess Corp.
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Velocity Analysis The coefficients of wave equation (relevant to imaging) are separable –Long scale –Short scale Challenges –Nonlinear effect –Coupling of long scale and short scale –Multiple
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Methods of Velocity Analysis Data domain objectives –Waveform inversion –Stereotomography Image domain objectives –WE-Migration forward, ray tracing inverse –WE-Migration forward, WE-Migration inverse
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Outline Theory –Objective function –Gradient Calculation Physical meaning Smoothing –Aliasing Examples –Angle ~ Offset –Reconstruct short scale and large scale variations
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Generalized Born Modeling Reflection occurs instantaneously with no separation in space. Reflection occurs instantaneously separated by a finite distance. Do not require to use the true velocity.
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Subsurface Image Measure
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Example Data generated with caustic, migrated using correct and background velocity.
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Differential Semblance Offset domain: Angle domain: Pseudo-differential operator of The objective function is smooth in velocity and is suitable for automatic velocity updating (Stolk & Symes, 2003).
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Gradient Calculation Offset: Angle:
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Gradient: Physical Meaning Single scattering, constructive interference occurs at zero offset.
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Gradient: Physical Meaning “Two scatterings”, constructive interference occurs on ray segments.
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Smoothing Problem –The raw gradient is singular with full data bandwidth. Solution –Confine the velocity model to the space of B-splines. Controlled degree of smoothness Compactly supported basis Implication –Projection to B-spline model space. –B : forward interpolation - sparse dense –B*: adjoint projection - sparse dense
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Example Flat reflector, constant velocity Projected gradient using BB* for one shot The gradient + B-spline projection reconstructs wide ray paths which are controlled by the degree of smoothness supplied.
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Optimization on B-spline space
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Aliasing We care not only the image in zero offset but also its move-out in non-zero offsets. There are many non-zero offset aliasing effects. –Data pre-conditioning. –Acquisition edge effect.
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Kinematics
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Kinematics of Image in Offset u<cu=cu>c
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Examples
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Anti-aliasing Aliasing reduced but loose some imageStrong aliasing
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Examples Born data Full data with rough model Initial model construction Optimization starting with v(z)
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Born Data Examples Smooth Marmousi velocity model, singular reflectivity, one-way wave simulation, acquisition full spread, receiver dense on surface.
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Starting Model Starting model, large horizontal scales, assumed to be obtainable through conventional velocity analysis tools. Optimization: 150m x 200m B-spline grid.
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Initial Image
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Optimized Image Optimized image using angle domain DSO. Optimized image using offset domain DSO.
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Optimized Velocity Optimized using angle domain DSO. Optimized using offset domain DSO.
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Initial Angle and Offset Gathers Top: offset gathers, bottom: angle gathers
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Optimized Gathers (angle driven) Top: offset gathers (not used in the optimization), bottom: angle gathers.
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Optimized Gathers (offset driven) Top: offset gathers, bottom: angle gathers (not used in the optimization)
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Velocity Difference Difference between optimized velocity and the projected true velocity (optimized by angle DSO). Difference between optimized velocity and the projected true velocity (optimized by offset DSO).
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Rough Marmousi Model Data generated using full wave equation simulation, acquisition split spread, receiver spacing 25m, receiver array across entire surface. Optimization: offset driven, B-spline grid 120m by 22m.
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Initial Velocity and Image Initial velocity model, corresponds to B-spline grid 900m by 300m. Initial image
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Optimized Velocity and Image Optimized velocity at 99 th iterationOptimized image at 99 th iteration
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Optimized Velocity and Image Optimized velocity at 49 th iterationOptimized image at 49 th iteration The optimization is stable and convergent.
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Obtain a Starting Model A v(z) starting model. Optimization: run up to 10Hz, coarse B-spline grid 800m by 400m, 500m by 200m.
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Optimized Velocity 800m by 400m, DSO optimized.Projected from the true model. 500m by 200m, DSO optimized.Projected from the true model.
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Null Space Optimized image at 20 th iteration.Optimized image at 49 th iteration.
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Starting with v(z) Velocity Start from v(z) velocity model, increase frequency and spatial resolution in two steps.
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Conclusions The angle domain DSO is not superior to offset domain DSO. The velocity analysis within migration is a promising direction to pursue. The adjoint-differential-migration provides an ideal platform for AWEMVA.
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