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

Slides:

Advertisements

Similar presentations

Depth Imaging: Todays Tool for Risk Reduction Todays Tool for Risk Reduction.

Advertisements

Warping for Trim Statics

Multiple attenuation in the image space Paul Sava & Antoine Guitton Stanford University SEP.

Multiple Removal with Local Plane Waves

Multi-Component Seismic Data Processing

Differential Semblance Optimization for Common Azimuth Migration

Overview of SEP research Paul Sava. The problem Modeling operator Seismic image Seismic data.

Sensitivity kernels for finite-frequency signals: Applications in migration velocity updating and tomography Xiao-Bi Xie University of California at Santa.

Riemannian Wavefield Migration: Wave-equation migration from Topography Jeff Shragge, Guojian Shan, Biondo Biondi Stanford.

Reverse-Time Migration

Wave-equation migration velocity analysis beyond the Born approximation Paul Sava* Stanford University Sergey Fomel UT Austin (UC.

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.

Paul Sava* Stanford University Sergey Fomel UT Austin (UC Berkeley) Angle-domain common-image gathers.

Wave-Equation Interferometric Migration of VSP Data Ruiqing He Dept. of Geology & Geophysics University of Utah.

Wave-Equation Interferometric Migration of VSP Data Ruiqing He Dept. of Geology & Geophysics University of Utah.

Wave-equation MVA by inversion of differential image perturbations Paul Sava & Biondo Biondi Stanford University SEP.

Primary-Only Imaging Condition Yue Wang. Outline Objective Objective POIC Methodology POIC Methodology Synthetic Data Tests Synthetic Data Tests 5-layer.

Wave-equation migration velocity analysis Paul Sava* Stanford University Biondo Biondi Stanford University Sergey Fomel UT Austin.

Prestack Stolt residual migration Paul Sava* Stanford University Biondo Biondi Stanford University.

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

Analytical image perturbations for wave-equation migration velocity analysis Paul Sava & Biondo Biondi Stanford University.

Wave-equation common-angle gathers for converted waves Paul Sava & Sergey Fomel Bureau of Economic Geology University of Texas.

Amplitude-preserving wave-equation migration Paul Sava* Stanford University Biondo Biondi Stanford University.

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.

Applications of Time-Domain Multiscale Waveform Tomography to Marine and Land Data C. Boonyasiriwat 1, J. Sheng 3, P. Valasek 2, P. Routh 2, B. Macy 2,

Time-shift imaging condition Paul Sava & Sergey Fomel Bureau of Economic Geology University of Texas at Austin.

Earth Study 360 Technology overview

Wave-equation imaging Paul Sava Stanford University.

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

Amplitude-preserved wave-equation migration Paul Sava & Biondo Biondi SEP108 (pages 1-27)

Surface wave tomography： part3: waveform inversion, adjoint tomography

Multisource Least-squares Reverse Time Migration Wei Dai.

Raanan Dafni,  Dual BSc in Geophysics and Chemistry (Tel-Aviv University).  PhD in Geophysics (Tel-Aviv University).  Paradigm Geophysics R&D ( ).

Implicit 3-D depth migration with helical boundary conditions James Rickett, Jon Claerbout & Sergey Fomel Stanford University.

V.2 Wavepath Migration Overview Overview Kirchhoff migration smears a reflection along a fat ellipsoid, so that most of the reflection energy is placed.

Angle-domain Wave-equation Reflection Traveltime Inversion

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

An array analysis of seismic surface waves

© 2013, PARADIGM. ALL RIGHTS RESERVED. Long Offset Moveout Approximation in Layered Elastic Orthorhombic Media Zvi Koren and Igor Ravve.

Migration In a Nutshell Migration In a Nutshell Migration In a Nutshell D.S. Macpherson.

Seismic Imaging in GLOBE Claritas

Wave-equation migration Wave-equation migration of reflection seismic data to produce images of the subsurface entails four basic operations: Summation.

Multiples Waveform Inversion

Introduction to Seismology

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

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

Pitfalls in seismic processing : The origin of acquisition footprint Sumit Verma, Marcus P. Cahoj, Bryce Hutchinson, Tengfei Lin, Fangyu Li, and Kurt J.

Wave-Equation Waveform Inversion for Crosswell Data M. Zhou and Yue Wang Geology and Geophysics Department University of Utah.

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

1 Prestack migrations to inversion John C. Bancroft CREWES 20 November 2001.

Shot-profile migration of GPR data Jeff Shragge, James Irving, and Brad Artman Geophysics Department Stanford University.

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

Migrating elastic data

Raanan Dafni,  PhD in Geophysics (Tel-Aviv University)  Paradigm R&D ( )  Post-Doc (Rice University) Current Interest: “Wave-equation based.

Lee M. Liberty Research Professor Boise State University.

LSM Theory: Overdetermined vs Underdetermined

R. G. Pratt1, L. Sirgue2, B. Hornby2, J. Wolfe3

Multi-dimensional depth imaging without an adequate velocity model

Vladimir Grechka Shell International E&P

Fang Liu, Arthur B. Weglein, Kristopher A. Innanen, Bogdan G. Nita

Paul Sava: WE seismic imaging

Non-local Means (NLM) Filter for Trim Statics

Multiple attenuation in the image space

Direct horizontal image gathers without velocity or “ironing”

Some remarks on the leading order imaging series

Non-local Means (NLM) Filter for Trim Statics

Prestack depth migration in angle-domain using beamlet decomposition:

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

Presentation transcript:

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

Fundamental ideas Correct 3-D imaging / attribute analysis require correct velocity –“Everything depends on V(x,y,z)” Jon Claerbout, 1999 Migration and velocity analysis are intrinsically connected –“The major tool to estimate velocity is to migrate the data” Samuel Gray, 1999 Wave phenomena are described by multipathing in complex geology

The goal Estimate 3-D velocity –iterative migration –wave-equation techniques Improve the quality of the migrated image –Exploit residual migration Fit the data

High-frequency vs. finite-frequency migration Kirchhoff Migration WE Migration High-frequencyFinite-frequency migration MVA Traveltime tomography Wave-equation MVA fast & inaccurateslow & accurate

WEMVA theory DATA SLOWNESS IMAGEWAVEFIELD DATA SLOWNESS WAVEFIELDIMAGEWAVEFIELD SLOWNESS perturbation Scattered wavefield WAVEFIELD perturbation IMAGE perturbation WAVEFIELD perturbation Scattered wavefield

WEMVA flow-chart Data Starting image Improved image Perturbation in image Perturbation in slowness Background slowness Background wavefield

Synthetic model

WEMVA theory DATA SLOWNESS IMAGEWAVEFIELD DATA SLOWNESS WAVEFIELDIMAGEWAVEFIELD SLOWNESS perturbation Scattered wavefield WAVEFIELD perturbation IMAGE perturbation WAVEFIELD perturbation Scattered wavefield

What is F? Linear operator –evaluated recursively during depth continuation –incorporates a scattering operator –first-order Born approximation »small perturbations a depth continuation operator the background wavefield

What is  R? What is  S?  S: the slowness perturbation that explains the improvement of the image. –What is an improved image?  R: the difference between the current image and an improved version of it.

What is an improved image? Pre-stack wave-equation migration –Pre-stack images - described by an “offset” axis offset aperture angle Angle-domain Common Image Gathers (CIG) –How to relate velocity and CIGs?

Velocity and CIGs Correct velocity - flat CIGs Incorrect velocity - non-flat CIGs more on angle-domain CIGs: Marie Prucha –(Wednesday, AVO applications) The goal: create an image with flat CIGs at every point

Velocity and CIGs A: original slowness D: true slowness

Velocity and CIGs A: original slowness D: true slowness

How do we flatten CIGs? Residual move-out energy does not move between midpoints Residual migration energy moves between midpoints –3-D pre-stack Stolt residual migration

Pre-stack Stolt residual migration Operates in the  k domain. Fast and robust Velocity-independent –new images do not depend on the new velocity, but on its ratio to the original velocity. Velocity ratio

Stolt pre-stack residual migration RST Original prestack image Extract Improved prestack image Interpretative QC Different ratios

Residual migration Flat CIGs = strong stack along the aperture angle axis. no residual migration for ratio=1

Residual migration Flat CIGs = strong stack along the aperture angle axis. no residual migration for ratio=1

Residual migration Flat CIGs = strong stack along the aperture angle axis. no residual migration for ratio=1

Best focused image –Extract the flattest image from the pre-stack images. depth location ratio –Stack along the angle axis »one stack value for each residual migration ratio –Pick the most energetic value on the stack.

Residual migration - picking For large perturbations scale down the picking ratio scale up the inverted velocity

WEMVA flow-chart Data Starting image Improved image Perturbation in image Perturbation in slowness Background slowness Background wavefield

Image perturbation

WEMVA flow-chart Data Starting image Improved image Perturbation in image Perturbation in slowness Background slowness Background wavefield

Inversion Iteration

Inversion Iteration

Inversion Iteration

Inversion

WEMVA flow-chart Data Starting image Improved image Perturbation in image Perturbation in slowness Background slowness Background wavefield

Image improvement A: original slowness B: updated slowness (first pass) C: updated slowness (second pass) D: true slowness

Image improvement A: original slowness B: updated slowness (first pass) C: updated slowness (second pass) D: true slowness

Image improvement A: original slowness B: updated slowness (first pass) C: updated slowness (second pass) D: true slowness

Image improvement A: original slowness B: updated slowness (first pass) C: updated slowness (second pass) D: true slowness

WEMVA - Conclusion wave-equation techniques iterative migration use the velocity information in CIGs improve the quality of the image interpretative approach