Presentation is loading. Please wait.

Presentation is loading. Please wait.

Fast 3D Least-squares Migration with a Deblurring Filter Wei Dai.

Published byReynard Fields Modified over 8 years ago

Similar presentations

Presentation on theme: "Fast 3D Least-squares Migration with a Deblurring Filter Wei Dai."— Presentation transcript:

1 Fast 3D Least-squares Migration with a Deblurring Filter Wei Dai

2 Outline ObjectiveObjective Numerical TestsNumerical Tests 3D U model3D U model ConclusionConclusion Preconditioned Conjugate GradientPreconditioned Conjugate Gradient IntroductionIntroduction Theory of Deblurring filterTheory of Deblurring filter

3 Introduction Standard migration: Least-squares migration: Standard migrationLSM ProsFast, robustHigh resolution images ConsImages of low qualityHigh computation cost Forward modeling:

4 Conjugate Gradient Misfit functional: Normal equation: Direct solver: Need to invert huge matrix. Iterative solver: Iterative conjugate gradient method:

5 Conjugate Gradient vs Steepest Descent

6 Conjugate Gradient Gradient: Step length: Conjugate direction: Update:

7 Objective: Reduce the iteration numbers required for LSM Proposal: A good preconditioner to accelerate the convergence. Objective

8 Preconditioned Conjugate Gradient To improve the condition number: Solution: to decompose and solve: By change of variables: Problem: is not symmetric.

9 Preconditioned Conjugate Gradient Gradient: Step length: Conjugate direction: Update: Problem: Need to calculate

10 Preconditioned Conjugate Gradient By change of variables: Conjugate direction: Gradient:

11 Preconditioned Conjugate Gradient Step length: Update: Advantage: only need M. Requirement: M to be SPD.

12 Reference model : grid model with evenly distributed point scatterers. Theory of the Deblurring Calculate its standard migration image:

13 Construct an image, which is an approximation of Rewrite in matrix notation so,

14 Numerical Tests model: 3D U model grid: grid interval: 10m background velocity: 1500 m/s 300 shots and 300 receivers on the surface Recording geometry X (m)01500 Y (m) 0 Fig. 1. Recording geometry. Red stars indicate sources and blue triangles indicate receivers.

15 3D U model Fig. 2. 3D view of the U model. Courtesy of Naoshi Aoki

16 3D U model Fig. 3. One horizontal and one vertical slices of the U model. X (m)01500 Y (m) 0 X (m) 0 1500 Z (m) 0

17 Fig. 4. Standard migration result. The same slices as previous figure are shown here. Standard migration image X (m) 0 1500 Y (m) 0 0.02 -0.12 X (m)0 1500 Z (m) 0 0.2 -0.1

18 Fig. 5. Vertical slice of the reference model and its corresponding standard migration image. Reference model X (m) 01500 Z (m) 0 X (m)01500 Z (m) 0

19 Fig. 6. Standard migration image and deblurred image for the reference model (vertical slices). X (m)01500 Z (m) 0 X (m)01500 Z (m) 0 0.5 -0.3 Standard migration image vs Deblurred image

20 X (m)01500 Y (m) 0 0.02 -0.12 X (m) 0 1500 Y (m) 0 0.1 -0.6 Standard migration image vs Deblurred image Fig. 7. Standard migration image and deblurred image for the 3D U model (horizontal slice along 2 nd reflectivity layer).

21 Fig. 8. Standard migration image and deblurred image for the 3D U model (vertical slice y=500m) X (m) 0 1500 Z (m) 0 0.2 -0.1 X (m)01500 Z (m) 0 0.6 -0.4 Standard migration image vs Deblurred image

22 Fig. 9. Standard migration image and deblurred image for the 3D U model (vertical slice x=550m) Y (m) 0 1500 Z (m) 0 0.25 -0.15 Y (m)01500 Z (m) 0 0.5 -0.5 Standard migration image vs Deblurred image

23 Fig. 10. Residual curves for SD, PSD, CG and PCG. Iteration number0 30 0.7 Data residual 0 Residual curves

24 Fig. 11. Image after 3 iterations of PCG. 0.1 -0.8 X (m)01500 Y (m) 0 X (m)01500 Z (m) 0 0.8 -0.6 Three iterations result

25 Fig. 12. Image after 5 iterations of PCG. 0 X (m)01500 Y (m) 0 X (m)0 1500 Z (m) 0 1 -0.8 Five iterations result

26 0 X (m)01500 Y (m) 0 X (m)0 1500 Z (m) 0 1 -0.8 Fig. 13. Image after 10 iterations of PCG. Ten iterations result

27 0 X (m) 0 1500 Y (m) 0 X (m) 0 1500 Z (m) 0 0 -0.9 Fig. 14. 30 iterations results of PCG and CG (horizontal slices). PCG vs CG

28 1 X (m) 0 1500 Z (m) 0 X (m)0 1500 Z (m) 0 0.8 -0.8 Fig. 15. 30 iterations result of PCG and CG (vertical slices). PCG vs CG

29 Conclusions Our deblurring filter is a good approximation to the Hessian inverse. It can improve the standard migration image and reduce its data residual by about 50%. Our deblurring filter as a preconditioner in LSM can speed up convergence rate by several times 3 iterations of PCG are equivalent to 10 iterations of CG.

Download ppt "Fast 3D Least-squares Migration with a Deblurring Filter Wei Dai."

Similar presentations

Curved Trajectories towards Local Minimum of a Function Al Jimenez Mathematics Department California Polytechnic State University San Luis Obispo, CA 93407.

Curved Trajectories towards Local Minimum of a Function Al Jimenez Mathematics Department California Polytechnic State University San Luis Obispo, CA
Mathematical Models Chapter 2

Mathematical Models Chapter 2
Optimization.

Optimization.
Multi-source Least-squares Migration with Topography Dongliang Zhang and Gerard Schuster King Abdullah University of Science and Technology.

Multi-source Least-squares Migration with Topography Dongliang Zhang and Gerard Schuster King Abdullah University of Science and Technology.
Multi-source Least Squares Migration and Waveform Inversion

Multi-source Least Squares Migration and Waveform Inversion
1 Numerical Solvers for BVPs By Dong Xu State Key Lab of CAD&CG, ZJU.

1 Numerical Solvers for BVPs By Dong Xu State Key Lab of CAD&CG, ZJU.
Sensitivity kernels for finite-frequency signals: Applications in migration velocity updating and tomography Xiao-Bi Xie University of California at Santa.

Sensitivity kernels for finite-frequency signals: Applications in migration velocity updating and tomography Xiao-Bi Xie University of California at Santa.
Steepest Decent and Conjugate Gradients (CG). Solving of the linear equation system.

Steepest Decent and Conjugate Gradients (CG). Solving of the linear equation system.
Modern iterative methods For basic iterative methods, converge linearly Modern iterative methods, converge faster –Krylov subspace method Steepest descent.

Modern iterative methods For basic iterative methods, converge linearly Modern iterative methods, converge faster –Krylov subspace method Steepest descent.
Jonathan Richard Shewchuk Reading Group Presention By David Cline

Jonathan Richard Shewchuk Reading Group Presention By David Cline
1 L-BFGS and Delayed Dynamical Systems Approach for Unconstrained Optimization Xiaohui XIE Supervisor: Dr. Hon Wah TAM.

1 L-BFGS and Delayed Dynamical Systems Approach for Unconstrained Optimization Xiaohui XIE Supervisor: Dr. Hon Wah TAM.
Numerical Optimization

Numerical Optimization
Lecture 2 Linear Variational Problems (Part II). Conjugate Gradient Algorithms for Linear Variational Problems in Hilbert Spaces 1.Introduction. Synopsis.

Lecture 2 Linear Variational Problems (Part II). Conjugate Gradient Algorithms for Linear Variational Problems in Hilbert Spaces 1.Introduction. Synopsis.
1 L-BFGS and Delayed Dynamical Systems Approach for Unconstrained Optimization Xiaohui XIE Supervisor: Dr. Hon Wah TAM.

1 L-BFGS and Delayed Dynamical Systems Approach for Unconstrained Optimization Xiaohui XIE Supervisor: Dr. Hon Wah TAM.
12 1 Variations on Backpropagation. 12 2 Variations Heuristic Modifications –Momentum –Variable Learning Rate Standard Numerical Optimization –Conjugate.

12 1 Variations on Backpropagation Variations Heuristic Modifications –Momentum –Variable Learning Rate Standard Numerical Optimization –Conjugate.
Advanced Topics in Optimization

Advanced Topics in Optimization
Monica Garika Chandana Guduru. METHODS TO SOLVE LINEAR SYSTEMS Direct methods Gaussian elimination method LU method for factorization Simplex method of.

Monica Garika Chandana Guduru. METHODS TO SOLVE LINEAR SYSTEMS Direct methods Gaussian elimination method LU method for factorization Simplex method of.
PETE 603 Lecture Session #29 Thursday, 7/29/10. 29.1 Iterative Solution Methods Older methods, such as PSOR, and LSOR require user supplied iteration.

PETE 603 Lecture Session #29 Thursday, 7/29/ Iterative Solution Methods Older methods, such as PSOR, and LSOR require user supplied iteration.

ECE 530 – Analysis Techniques for Large-Scale Electrical Systems Prof. Hao Zhu Dept. of Electrical and Computer Engineering University of Illinois at Urbana-Champaign.

ECE 530 – Analysis Techniques for Large-Scale Electrical Systems Prof. Hao Zhu Dept. of Electrical and Computer Engineering University of Illinois at Urbana-Champaign.

Similar presentations

Ads by Google