Ground motion seismology

This book explains the physics behind seismic ground motions and seismic waves to graduate and upper undergraduate students as well as to professionals. Both seismic ground motions and seismic waves are terms for "shaking" due to earthquakes, but it is common that shaking in the near-field of an earthquake source is called seismic ground motion and in the far-field is called seismic waves. Seismic ground motion is often described by the tensor formula based on the representation theorem, but in this book explicit formulation is emphasized beginning with Augustus Edward Hough Love (1863 - 1940). The book also explains in depth the equations and methods used for analysis and computation of shaking close to an earthquake source. In addition, it provides in detail information and knowledge related to teleseismic body waves, which are frequently used in the analysis of the source of an earthquake.

1 Earthquakes and Ground Motion 1.1 Definition of Ground Motion 1.2 Ground Motion and Seismic Waves 1.2.1 Elastic Strain 1.2.2 Balance of Stress 1.2.3 Constitutive Law and Equation of Motion 1.2.4 Wave Equation and Seismic Wave 1.2.5 Wavefronts and Rays 1.2.6 Anelasticity 1.3 Principles of Ground Motion 1.3.1 Principle of Superposition 1.3.2 Reciprocity Theorem 1.3.3 Representation Theorem Problems References 2 The Effect of Earthquake Source 2.1 Representation of Earthquake Source 2.1.1 Discovery of Earthquake Source 2.1.2 Representation of Source Fault 2.1.3 Ground Motion by Point Force 2.1.4 Ground Motion by Point Source 2.1.5 Potential Representation 2.2 Cylindrical Wave Expansion 2.2.1 Vertical Strike Slip Fault 2.2.2 Inclined Strike Slip Fault 2.2.3 Vertical Dip Slip Fault 2.2.4 Inclined Dip Slip Fault 2.2.5 Extension to Arbitrary Fault Slip 2.3 Analysis of the Earthquake Source 2.3.1 Hypocenter Determination 2.3.2 Radiation Pattern and Fault Plane Solution 2.3.3 Moment Tensor 2.3.4 CMT Inversion 2.3.5 Ground Motion from a Finite Fault 2.3.6 Source Processes and Source Inversion 2.3.7 Stress Drop and Slip Rate Function 2.3.8 Directivity Effect Problems References 3 The Effect of Propagation 3.1 Propagation in 1-D Media 3.1.1 1-D Velocity Structure 3.1.2 SH wave 3.1.3 P wave and SV wave 3.1.4 Haskell matrix 3.1.5 Reflection/Transmission Matrix I 3.1.6 Reflection/Transmission Matrix II 3.1.7 Wavenumber Integration (Approximate) 3.1.8 Wavenumber Integration (Numerical) 3.1.9 Surface Wave (Love Wave) 3.1.10 Surface Wave (Rayleigh Wave) 3.1.11 Teleseismic Body Wave 3.1.12 Crustal Deformation 3.2 Propagation in 3-D Velocity Structures 3.2.1 3-D Velocity Structure 3.2.2 Ray Theory 3.2.3 Ray Tracing 3.2.4 Finite Difference Method 3.2.5 Finite Element Method 3.2.6 Aki-Larner Method 3.3 Analysis of Propagation 3.3.1 Long-Period Ground Motion 3.3.2 Microtremors 3.3.3 Seismic Interferometry 3.3.4 Seismic Tomography Problems References 4 Observation and Processing 4.1 Seismographs 4.1.1 Instrumentation of Seismographs 4.1.2 Strong Motion Seismographs 4.1.3 Electromagnetic Seismographs 4.1.4 Servo Mechanisms 4.2 Spectral Processing 4.2.1 A/D Conversion 4.2.2 Fourier Transform 4.2.3 Discrete Fourier Transform 4.2.4 FFT 4.3 Filtering 4.3.1 Filters and Windows 4.3.2 Low-Pass Filters 4.3.3 High-Pass and Band-Pass Filters 4.4 Least-Squares Method 4.4.1 Computation in Least-Squares Method 4.4.2 Constraints in Least-Squares Method Problems References Appendix A.1 Magnitude A.1.1 Definition of Magnitude A.1.2 Recent Magnitudes A.2 Seismic Intensity A.2.1 Characteristics of Seismic Intensity A.2.2 Sensory Seismic Intensity A.2.3 Instrumental Seismic Intensity References Index