Full-3D Seismic Waveform Inversion
Theory, Software, and Practice
(Sprache: Englisch)
This book introduces a methodology for solving the seismic inverse problem using purely numerical solutions built on purely numerical solutions of 3D wave equations and is free of the approximations or simplifications that are common in classical seismic...
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Klappentext zu „Full-3D Seismic Waveform Inversion “
This book introduces a methodology for solving the seismic inverse problem using purely numerical solutions built on purely numerical solutions of 3D wave equations and is free of the approximations or simplifications that are common in classical seismic inversion methodologies and therefore applicable to arbitrary 3D geological media and seismic source models. Such waveform data contain a wealth of information about the details of the geological media and the seismic source, and the methodology introduced here allows us to exploit that information to the full extent. Source codes provided allow readers to experiment with the calculations demonstrated and also explore their own applications.
Inhaltsverzeichnis zu „Full-3D Seismic Waveform Inversion “
- Preface- Introduction
- Advantages of the seismic ray method
- Drawbacks of the seismic ray method
- Numerical solutions of the seismic wave equation
- A brief history of HPC technology
- Anelastic Wave Propagation (AWP)
- Formulation
- Elastic Media
- Viscoelastic Media
- The complex modulus and its approximation
- Physical interpretation of the approximate modulus
- Isotropic viscoelastic media
- Frequency-independent Q
- Discretization
- Free-Surface Boundary
- PML Boundary
- Internal Welded Material Interfaces
- Source Representation
- Software
- Mesh Generation
- Structural Model
- Parameter File
- Sources and Receivers
- File Format
- File Processing
- Recording Grid Points
- Wavefield Simulation
- Synthetic Seismograms
- Half-Space Example Summary
- Application
- SCEC Community Velocity Models (CVMs)
- Earthquake Source Models
- Validation of SCEC CVMs
- Green's Functions
- Mathematical Preliminary
- Vector Spaces
- Inner Product
- Linear Transformations
- Hilbert Spaces
- Functions As Vectors
- Dirac Delta Function
- Fourier Transforms
- Operator Algebra
- Fréchet Derivative
- The Adjoint of a Differential Operator
- Ordinary Differential Operators
- Partial Differential Operators
- Scalar Wave Equations
- Gradient, Divergence and Curl
- Viscoelastic Equation of Motion
- Adjoint Initial and Boundary Conditions
- ODE
- Scalar Wave Equations
- Anisotropic Viscoelastic Wave Equation
- Properties of Green's Functions
- Adjoint Green's Functions
- Reciprocity
- Scalar Wave-Equation Operator
- Anisotropic Viscoelastic Wave-Equation Operator
- Inhomogeneous Initial/Boundary Conditions
- General 2nd-Order ODE
- Representation Theorem
- Adjoint Representation Theorem
- Receiver Green Tensor (RGT)
- Time-Reversed Adjoint Green's Tensor
- Receiver-Side Strain Green's Tensor (RSGT)
- RSGTs in the Half-Space Example
- Born Series
- The Scalar Wave Equation
- Born Kernel
- Born Approximation
- The
... mehr
Anisotropic Viscoelastic Wave Equation
- Data Sensitivity Kernels
- Definition
- Data Functionals
- Data Functionals for u and u
- Filtered RGT
- The Chain Rule
- Time-Domain Waveform Differences
- Frequency-Domain Waveform Differences
- Broadband Cross-Correlation Measurements
- Frequency-Dependent Phase and Amplitude Misfits
- Rytov Approximation
- "Banana-Doughnut" Structure of Rytov Phase Kernels
- Model Parameterization
- Bulk Modulus
- Bulk and Shear Moduli
- Lamé Parameters
- P- and S-wave Velocities
- Love's Elastic Parameters (Hexagonal Symmetry)
- Asymptotic Parameters (Triclinic Symmetry)
- Anelastic Attenuation Quality Factors
- Finite Moment Tensor (FMT)
- Software
- WPK File
- Kernel Calculation
- Kernel Output and Visualization
- More Examples
- S-Wave From a Double-Couple Source
- Rayleigh Wave From a Vertical Body-Force
- Head Waves
- Optimization Algorithms
- The Scattering-Integral (SI) Method
- The Gauss-Newton Algorithm
- F3DT-SI
- Scalable Parallel LSQR (SPLSQR)
- Model Covariance
- Annihilator Matrix
- The Adjoint-Wavefield (AW) Method
- The Gradient
- F3DT-AW
- Hessian-Vector Product
- Software
- Adjoint Source Field
- Adjoint Wavefield
- Event Kernel
- CVM-S4.26
- Background
- Convergence Rate
- Data Functionals
- Model Evaluation
- Model Description
- CVM-S4.26 and CVM-S4 Comparison
- CVM-S4.26 and CVM-H11.9 Comparison
- Starting Model Differences
- Data Differences
- Algorithmic Differences
- Earthquake Source Parameter Differences
- Summary
- Southern Walker Lane Belt
- Long Valley Caldera
- Indian Wells Valley - Coso Geothermal Area
- Owens Lake
- Panamint Range
- Southern Sierra Nevada
- SNB Mafic Cumulates
- Tehachapi Anomaly
- Southern San Joaquin Basin
- Basin Geometry
- Great Valley Ophiolite
- Southern Coast Ranges
- Salinian Block
- Nacimiento Block
- Transverse Ranges
- Ventura Basin _ Santa Barbara Channel
- San Bernardino Basin
- Inner Continental Borderland
- Los Angeles Basin
- Offshore Region
- Mojave Desert Region
- Antelope Valley
- POR Schist
- Peninsular Ranges - Salton Trough Region
- Index
- Data Sensitivity Kernels
- Definition
- Data Functionals
- Data Functionals for u and u
- Filtered RGT
- The Chain Rule
- Time-Domain Waveform Differences
- Frequency-Domain Waveform Differences
- Broadband Cross-Correlation Measurements
- Frequency-Dependent Phase and Amplitude Misfits
- Rytov Approximation
- "Banana-Doughnut" Structure of Rytov Phase Kernels
- Model Parameterization
- Bulk Modulus
- Bulk and Shear Moduli
- Lamé Parameters
- P- and S-wave Velocities
- Love's Elastic Parameters (Hexagonal Symmetry)
- Asymptotic Parameters (Triclinic Symmetry)
- Anelastic Attenuation Quality Factors
- Finite Moment Tensor (FMT)
- Software
- WPK File
- Kernel Calculation
- Kernel Output and Visualization
- More Examples
- S-Wave From a Double-Couple Source
- Rayleigh Wave From a Vertical Body-Force
- Head Waves
- Optimization Algorithms
- The Scattering-Integral (SI) Method
- The Gauss-Newton Algorithm
- F3DT-SI
- Scalable Parallel LSQR (SPLSQR)
- Model Covariance
- Annihilator Matrix
- The Adjoint-Wavefield (AW) Method
- The Gradient
- F3DT-AW
- Hessian-Vector Product
- Software
- Adjoint Source Field
- Adjoint Wavefield
- Event Kernel
- CVM-S4.26
- Background
- Convergence Rate
- Data Functionals
- Model Evaluation
- Model Description
- CVM-S4.26 and CVM-S4 Comparison
- CVM-S4.26 and CVM-H11.9 Comparison
- Starting Model Differences
- Data Differences
- Algorithmic Differences
- Earthquake Source Parameter Differences
- Summary
- Southern Walker Lane Belt
- Long Valley Caldera
- Indian Wells Valley - Coso Geothermal Area
- Owens Lake
- Panamint Range
- Southern Sierra Nevada
- SNB Mafic Cumulates
- Tehachapi Anomaly
- Southern San Joaquin Basin
- Basin Geometry
- Great Valley Ophiolite
- Southern Coast Ranges
- Salinian Block
- Nacimiento Block
- Transverse Ranges
- Ventura Basin _ Santa Barbara Channel
- San Bernardino Basin
- Inner Continental Borderland
- Los Angeles Basin
- Offshore Region
- Mojave Desert Region
- Antelope Valley
- POR Schist
- Peninsular Ranges - Salton Trough Region
- Index
... weniger
Autoren-Porträt von Po Chen, En-Jui Lee
Po Chen is an Associate Professor in the Department of Geology and Geophysics and the School of Energy Resources, University of Wyoming. He has published 24 peer-reviewed journal papers, 5 peer-reviewed conference papers, one book and three book chapters. Most of his publications are focused on different aspects of the newly emerging Full-3D Waveform Inversion (F3DWI) technique and its applications in earthquake hazard analysis/mitigation, resource exploration, crustal and upper-mantle dynamics. He teaches seismological inverse problems and has developed a set of parallel software tools for solving F3DWI problems.
Bibliographische Angaben
- Autoren: Po Chen , En-Jui Lee
- 2015, 1st ed. 2015, XXXIV, 513 Seiten, 125 farbige Abbildungen, Maße: 16 x 24,1 cm, Gebunden, Englisch
- Verlag: Springer, Berlin
- ISBN-10: 3319166034
- ISBN-13: 9783319166032
- Erscheinungsdatum: 22.09.2015
Sprache:
Englisch
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