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The 17 January 1994 Northridge, California, Earthquake: A Retrospective Analysis
Modern Products for a Vintage Event: An Update on the 1933 Long Beach, California, Earthquake
Hybrid broadband ground-motion simulation validation of small magnitude active shallow crustal earthquakes in New Zealand
Validating predicted site response in sedimentary basins from 3D ground motion simulations
Ground motions in urban Los Angeles from the 2019 Ridgecrest earthquake sequence
NGA-East Ground-Motion Characterization model part I: Summary of products and model development
NGA-East ground-motion characterization model Part II: Implementation and hazard implications
Regional Calibration of Hybrid Ground‐Motion Simulations in Moderate Seismicity Areas: Application to the Upper Rhine Graben
Hybrid broadband ground motion simulation validation of small magnitude earthquakes in Canterbury, New Zealand
Near‐Field Ground Motions from the July 2019 Ridgecrest, California, Earthquake Sequence
Reply to “Comment on ‘Broadband Ground‐Motion Simulation of the 2011 M w 6.2 Christchurch, New Zealand, Earthquake’ by H. N. T. Razafindrakoto, B. A. Bradley, and R. W. Graves” by Guidotti et al.
Broadband Ground‐Motion Simulation of the 2011 M w 6.2 Christchurch, New Zealand, Earthquake
Subsurface Geometry of the San Andreas Fault in Southern California: Results from the Salton Seismic Imaging Project (SSIP) and Strong Ground Motion Expectations
Ground‐Motion Simulations of 1811–1812 New Madrid Earthquakes, Central United States
NGA-West2 Site Database
NGA-West2 Database
NGA-West2 Research Project
Calibration of a Semi-Stochastic Procedure for Simulating High-Frequency Ground Motions
Implications of the M w 9.0 Tohoku-Oki Earthquake for Ground Motion Scaling with Source, Path, and Site Parameters
Simulating seismic wave propagation in 3D elastic media using staggered-grid finite differences
Abstract This article provides an overview of the application of the staggered-grid finite-difference technique to model wave propagation problems in 3D elastic media. In addition to presenting generalized, discrete representations of the differential equations of motion using the staggered-grid approach, we also provide detailed formulations that describe the incorporation of moment-tensor sources, the implementation of a stable and accurate representation of a planar free-surface boundary for 3D models, and the derivation and implementation of an approximate technique to model spatially variable anelastic attenuation within time-domain finite-difference computations. The comparison of results obtained using the staggered-grid technique with those obtained using a frequency-wavenumber algorithm shows excellent agreement between the two methods for a variety of models. In addition, this article also introduces a memory optimization procedure that allows large-scale 3D finite-difference problems to be computed on a conventional, single-processor desktop workstation. With this technique, model storage is accommodated using both external (hard-disk) and internal (core) memory. To reduce system overhead, a cascaded time update procedure is utilized to maximize the number of computations performed between I/O operations. This formulation greatly expands the applicability of the 3D finite-difference technique by providing an efficient and practical algorithm for implementation on commonly available workstation platforms.