Non-local Means (NLM) Filter for Trim Statics

Slides:

Advertisements

Similar presentations

Multisource Full Waveform Inversion of Marine Streamer Data with Frequency Selection Multisource Full Waveform Inversion of Marine Streamer Data with Frequency.

Advertisements

Warping for Trim Statics

Computational Challenges for Finding Big Oil by Seismic Inversion.

Multi-source Least Squares Migration and Waveform Inversion

Reverse Time Migration of Multiples for OBS Data Dongliang Zhang KAUST.

Specular-Ray Parameter Extraction and Stationary Phase Migration Jing Chen University of Utah.

Wavepath Migration versus Kirchhoff Migration: 3-D Prestack Examples H. Sun and G. T. Schuster University of Utah.

TARGET-ORIENTED LEAST SQUARES MIGRATION Zhiyong Jiang Geology and Geophysics Department University of Utah.

Joint Migration of Primary and Multiple Reflections in RVSP Data Jianhua Yu, Gerard T. Schuster University of Utah.

Arbitrary Parameter Extraction, Stationary Phase Migration, and Tomographic Velocity Analysis Jing Chen University of Utah.

FAST VELOCITY ANALYSIS BY PRESTACK WAVEPATH MIGRATION H. Sun Geology and Geophysics Department University of Utah.

3-D PRESTACK WAVEPATH MIGRATION H. Sun Geology and Geophysics Department University of Utah.

Migration Deconvolution vs Least Squares Migration Jianhua Yu, Gerard T. Schuster University of Utah.

1 Fast 3D Target-Oriented Reverse Time Datuming Shuqian Dong University of Utah 2 Oct

1 Local Reverse Time Migration: P-to-S Converted Wave Case Xiang Xiao and Scott Leaney UTAM, Univ. of Utah Feb. 7, 2008.

Demonstration of Super-Resolution and Super-Stacking Properties of Time Reversal Mirrors in Locating Seismic Sources Weiping Cao, Gerard T. Schuster, Ge.

Multisource Least-squares Reverse Time Migration Wei Dai.

1 © 2011 HALLIBURTON. ALL RIGHTS RESERVED. VSP modeling, velocity analysis, and imaging in complex structures Yue Du With Mark Willis, Robert Stewart May.

Making the Most from the Least (Squares Migration) G. Dutta, Y. Huang, W. Dai, X. Wang, and Gerard Schuster G. Dutta, Y. Huang, W. Dai, X. Wang, and Gerard.

Overview of Multisource Phase Encoded Seismic Inversion Wei Dai, Ge Zhan, and Gerard Schuster KAUST.

Angle-domain Wave-equation Reflection Traveltime Inversion

Attribute- Assisted Seismic Processing and Interpretation 3D CONSTRAINED LEAST-SQUARES KIRCHHOFF PRESTACK TIME MIGRATION Alejandro.

Superresolution Imaging with Resonance Scatterring Gerard Schuster, Yunsong Huang, and Abdullah AlTheyab King Abdullah University of Science and Technology.

Mitigation of RTM Artifacts with Migration Kernel Decomposition Ge Zhan* and Gerard T. Schuster King Abdullah University of Science and Technology June.

Least Squares Migration of Stacked Supergathers Wei Dai and Gerard Schuster KAUST vs.

Subwavelength Imaging using Seismic Scanning Tunneling Macroscope Field Data Example G. Dutta, A. AlTheyab, S. Hanafy, G. Schuster King Abdullah University.

Impact of MD on AVO Inversion

Theory of Multisource Crosstalk Reduction by Phase-Encoded Statics G. Schuster, X. Wang, Y. Huang, C. Boonyasiriwat King Abdullah University Science &

Prestack Migration Intuitive Least Squares Migration Green’s Theorem.

Multiples Waveform Inversion

Moveout Correction and Migration of Surface-related Resonant Multiples Bowen Guo*,1, Yunsong Huang 2 and Gerard Schuster 1 1 King Abdullah University of.

Migration Velocity Analysis 01. Outline  Motivation Estimate a more accurate velocity model for migration Tomographic migration velocity analysis 02.

Multisource Least-squares Migration of Marine Data Xin Wang & Gerard Schuster Nov 7, 2012.

Wave-equation migration velocity analysis Biondo Biondi Stanford Exploration Project Stanford University Paul Sava.

Signal Analysis and Imaging Group Department of Physics University of Alberta Regularized Migration/Inversion Henning Kuehl (Shell Canada) Mauricio Sacchi.

Reverse Time Migration of Prism Waves for Salt Flank Delineation

Fast Least Squares Migration with a Deblurring Filter Naoshi Aoki Feb. 5,

Super-virtual Interferometric Diffractions as Guide Stars Wei Dai 1, Tong Fei 2, Yi Luo 2 and Gerard T. Schuster 1 1 KAUST 2 Saudi Aramco Feb 9, 2012.

Migration Velocity Analysis of Multi-source Data Xin Wang January 7,

Benefits & Limitations of Least Squares Migration W.Dai,D.Zhang,X.Wang,GTSKAUST RTM Least Squares RTM GOM RTM GOM LSRTM.

Non-local Means (NLM) Filter for Trim Statics Yunsong Huang, Xin Wang, Yunsong Huang, Xin Wang, Gerard T. Schuster KAUST Kirchhoff Migration Kirchhoff+Trim.

Fast Least Squares Migration with a Deblurring Filter 30 October 2008 Naoshi Aoki 1.

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

Shuqian Dong and Sherif M. Hanafy February 2009 Interpolation and Extrapolation of 2D OBS Data Using Interferometry.

Migration of intermediate offset data from two-boat-survey Zongcai Feng Nov 3, 2015.

Reverse Time Migration

LSM Theory: Overdetermined vs Underdetermined

Zero-Offset Data d = L o ò r ) ( g = d dr r ) ( g = d

Processing of KAUST Golf Data

Fast Multisource Least Squares Migration of 3D Marine Data with

Making the Most from the Least (Squares Migration)

Iterative Non-Linear Optimization Methods

Fast Multisource Least Squares Migration of 3D Marine Data with

Skeletonized Wave-equation Inversion for Q

Skeletonized Wave-Equation Surface Wave Dispersion (WD) Inversion

Free Surface Multiple Elimination

Interferometric Least Squares Migration

Overview of Multisource Phase Encoded Seismic Inversion

Non-local Means (NLM) Filter for Trim Statics

The FOCI method versus other wavefield extrapolation methods

Overview of Multisource and Multiscale Seismic Inversion

Initial analysis and comparison of the wave equation and asymptotic prediction of a receiver experiment at depth for one-way propagating waves Chao Ma*,

Least-squares Reverse Time Migration with Frequency-selection Encoding for Marine Data Wei Dai, WesternGeco Yunsong Huang and Gerard T. Schuster, King.

Overview of Multisource and Multiscale Seismic Inversion

PS, SSP, PSPI, FFD KM SSP PSPI FFD.

Han Yu, Bowen Guo*, Sherif Hanafy, Fan-Chi Lin**, Gerard T. Schuster

Chaiwoot Boonyasiriwat

Super-virtual Refraction Interferometry: Theory

Wave Equation Dispersion Inversion of Guided P-Waves (WDG)

Lecture 7 Patch based methods: nonlocal means, BM3D, K- SVD, data-driven (tight) frame.

Presentation transcript:

Non-local Means (NLM) Filter for Trim Statics Yunsong Huang, Xin Wang, Gerard T. Schuster KAUST

Outline Motivations NLM filter Results (GOM data) Conclusions NLM filtering of images NLM+trim statics of migration images Results (GOM data) Conclusions My talk is organized in the following way: 1. The first part is motivation. I will talk about a least squares migration (LSM ) advantages and challenges. 2. The second part is theory for a deblurring filter, which is an alternative method to LSM. 3. In the third part, I will show a numerical result of a deblurring filter. 4. The fourth is the main part of my talk. Deblurred LSM (DLSM) is a fast LSM with a deblurring filter. I will explain how to use the filter in LSM algorithm. 5. Then I will show numerical results of the DLSM. 6. Then I will conclude my presentation. Each figure has a slide number is shown at the footer. 2

Motivation dim spots Velocity inaccuracies Stacking misaligned prestack migration images  blurred migration images dim spots

Motivation CIG 16/31

Motivation CIG 1/31

Motivation CIG 5/31

Outline Motivations NLM filter Results (GOM data) Conclusions NLM filtering of images NLM+trim statics of migration images Results (GOM data) Conclusions My talk is organized in the following way: 1. The first part is motivation. I will talk about a least squares migration (LSM ) advantages and challenges. 2. The second part is theory for a deblurring filter, which is an alternative method to LSM. 3. In the third part, I will show a numerical result of a deblurring filter. 4. The fourth is the main part of my talk. Deblurred LSM (DLSM) is a fast LSM with a deblurring filter. I will explain how to use the filter in LSM algorithm. 5. Then I will show numerical results of the DLSM. 6. Then I will conclude my presentation. Each figure has a slide number is shown at the footer. 7

Non-Local Mean Filter sensitivity controller normalization filtering weight best match survives pb patch pa search neighborhood Buades et al., 2005

Non-Local Mean Example favors repetitive structures A noisy image Endo-filtered by NLM filtering weights patch search neighborhood

Outline Motivations NLM filter Results (GOM data) Conclusions NLM filtering of images NLM+trim statics of migration images Results (GOM data) Conclusions My talk is organized in the following way: 1. The first part is motivation. I will talk about a least squares migration (LSM ) advantages and challenges. 2. The second part is theory for a deblurring filter, which is an alternative method to LSM. 3. In the third part, I will show a numerical result of a deblurring filter. 4. The fourth is the main part of my talk. Deblurred LSM (DLSM) is a fast LSM with a deblurring filter. I will explain how to use the filter in LSM algorithm. 5. Then I will show numerical results of the DLSM. 6. Then I will conclude my presentation. Each figure has a slide number is shown at the footer. 10

Poor candidate for pilot NLM filter+ correlate+shift Stacking Strategies Poor candidate for pilot Washed out Tree representation A1 NLM filter+ correlate+shift stack B1 B2 Out of phase

Recursive Stacking/Destacking Stacking prestack images (no pilot needed) 1 A Destacking 1 2 B 1 2 3 4 C

Outline Motivations NLM filter Results (GOM data) Conclusions NLM filtering of images NLM+trim statics of migration images Results (GOM data) Conclusions My talk is organized in the following way: 1. The first part is motivation. I will talk about a least squares migration (LSM ) advantages and challenges. 2. The second part is theory for a deblurring filter, which is an alternative method to LSM. 3. In the third part, I will show a numerical result of a deblurring filter. 4. The fourth is the main part of my talk. Deblurred LSM (DLSM) is a fast LSM with a deblurring filter. I will explain how to use the filter in LSM algorithm. 5. Then I will show numerical results of the DLSM. 6. Then I will conclude my presentation. Each figure has a slide number is shown at the footer. 13

Stacked Prestack Migration Images Z (km) 3.6 (31 plane-wave gathers) X (km) 15

Stacked Prestack+Trim Statics Migration Images Z (km) 3.6 (31 plane-wave gathers) X (km) 15

Stacked Prestack Migration Images Z (km) 3.6 (31 plane-wave gathers) X (km) 15

Stacked Prestack+Trim Statics Migration Images Z (km) 3.6 (31 plane-wave gathers) X (km) 15

Really? Too Good to be True (31 plane-wave gathers) Z (km) 3.6 X (km) (31 plane-wave gathers) Really? X (km) 15

Local Trim Statics Shifts * . poststack prestack l Scatter plot: * . x z Cluster mean 3s

Local Trim Statics Shifts Ideally, we want a v(x,y,z) that reduces scatter . . x . . . . . . z

Local Trim Statics Shifts Reduced scatter implies a more accurate velocity model: e = ½ S||Ri-R||2  MVA . . x over iterations . Ri z x 2h1 2h2 Relation to subsurface offset . . . . . z

Outline Motivations NLM filter Results (GOM data) Conclusions NLM filtering of images NLM+trim statics of migration images Results (GOM data) Conclusions My talk is organized in the following way: 1. The first part is motivation. I will talk about a least squares migration (LSM ) advantages and challenges. 2. The second part is theory for a deblurring filter, which is an alternative method to LSM. 3. In the third part, I will show a numerical result of a deblurring filter. 4. The fourth is the main part of my talk. Deblurred LSM (DLSM) is a fast LSM with a deblurring filter. I will explain how to use the filter in LSM algorithm. 5. Then I will show numerical results of the DLSM. 6. Then I will conclude my presentation. Each figure has a slide number is shown at the footer. 22

Conclusions Trim statics can align reflectors mispositioned across prestack images due to velocity inaccuracies Noticeable improvement in feature coherency Limitation: although features are clearly revealed, their locations might still be wrong We can quantify and reduce the locational variance of the revealed features, thereby inverting the velocity

Thanks to Sponsors of CSIM Consortium