Ground motion simulation validation is an important and necessary task toward establishing the efficacy of physics-based ground motion simulations for seismic hazard analysis and earthquake engineering applications. This article presents a comprehensive validation of the commonly used Graves and Pitarka hybrid broadband ground motion simulation methodology with a recently developed three-dimensional (3D) Canterbury Velocity Model. This is done through simulation of 148 small magnitude earthquake events in the Canterbury, New Zealand, region in order to supplement prior validation efforts directed at several larger magnitude events. Recent empirical ground motion models are also considered to benchmark the simulation predictive capability, which is examined by partitioning the prediction residuals into the various components of ground motion variability. Biases identified in source, path, and site components suggest that improvements to the predictive capabilities of the simulation methodology can be made by using a longer high-frequency path duration model, reducing empirical Vs30-based low-frequency site amplification, and utilizing site-specific velocity models in the high-frequency simulations.
AbrahamsonNSilvaW (2008) Summary of the Abrahamson & Silva NGA ground-motion relations. Earthquake Spectra24: 67–97.
2.
AfshariKStewartJP (2016a) Physically parameterized prediction equations for significant duration in active crustal regions. Earthquake Spectra32: 2057–2081.
3.
AfshariKStewartJP (2016b) Validation of duration parameters from SCEC broadband platform simulated ground motions. Seismological Research Letters87: 1355–1362.
4.
Al AtikLAbrahamsonNBommerJJ, et al. (2010) The variability of ground-motion prediction models and its components. Seismological Research Letters81: 794–801.
5.
AnchetaTDDarraghRBStewartJP, et al. (2014) NGA-West2 database. Earthquake Spectra30: 989–1005.
6.
AtkinsonGMAssatouriansK (2015) Implementation and validation of EXSIM (a stochastic finite-fault ground-motion simulation algorithm) on the SCEC broadband platform. Seismological Research Letters86: 48–60.
7.
BannisterSGledhillK (2012) Evolution of the 2010–2012 Canterbury earthquake sequence. New Zealand Journal of Geology and Geophysics55: 295–304.
8.
BatesDMächlerMBolkerB, et al. (2015) Fitting linear mixed-effects models using lme4. Journal of Statistical Software67: 1–48.
9.
BooreDM (2003) Simulation of ground motion using the stochastic method. Pure and Applied Geophysics160: 635–676.
10.
BooreDMThompsonEM (2014) Path durations for use in the stochastic-method simulation of ground motions. Bulletin of the Seismological Society of America104: 2541–2552.
11.
BooreDMThompsonEM (2015) Revisions to some parameters used in stochastic-method simulations of ground motion. Bulletin of the Seismological Society of America105: 1029–1041.
12.
BradleyBA (2013) A New Zealand-specific pseudospectral acceleration ground-motion prediction equation for active shallow crustal earthquakes based on foreign models. Bulletin of the Seismological Society of America103: 1801–1822.
13.
BradleyBA (2015) Systematic ground motion observations in the Canterbury earthquakes and region-specific non-ergodic empirical ground motion modeling. Earthquake Spectra31: 1735–1761.
14.
BradleyBACubrinovskiM (2011) Near-source strong ground motions observed in the 22 February 2011 Christchurch earthquake. Seismological Research Letters82: 853–865.
15.
BradleyBABaeSEPolakV, et al. (2017a) Ground motion simulations of great earthquakes on the Alpine Fault: Effect of hypocentre location and comparison with empirical modelling. New Zealand Journal of Geology and Geophysics60: 188–198.
16.
BradleyBAPettingaDBakerJW, et al. (2017b) Guidance on the utilization of earthquake-induced ground motion simulations in engineering practice. Earthquake Spectra33: 809–835.
17.
BradleyBARazafindrakotoHNPolakV (2017c) Ground-motion observations from the 14 November 2016 Mw 7.8 Kaikoura, New Zealand, earthquake and insights from broadband simulations. Seismological Research Letters88: 740–756.
18.
BrownLJWeeberJH (1992) Geology of the Christchurch Urban Area – 1:25000 (Geological Map). Lower Hutt, New Zealand: Institute of Geological and Nuclear Sciences, p. 103.
19.
CampbellKWBozorgniaY (2012) A comparison of ground motion prediction equations for Arias intensity and cumulative absolute velocity developed using a consistent database and functional form. Earthquake Spectra28: 931–941.
20.
CampbellKWBozorgniaY (2014) NGA-West2 ground motion model for the average horizontal components of PGA, PGV, and 5% damped linear acceleration response spectra. Earthquake Spectra30: 1087–1115.
21.
ChiouBYoungsRAbrahamsonN, et al. (2010) Ground-motion attenuation model for small-to-moderate shallow crustal earthquakes in California and its implications on regionalization of ground-motion prediction models. Earthquake Spectra26: 907–926.
22.
CrempienJGArchuletaRJ (2015) UCSB method for simulation of broadband ground motion from kinematic earthquake sources. Seismological Research Letters86: 61–67.
23.
de la TorreCBradleyBALeeRL (2020) Modeling nonlinear site effects in physics-based ground motion simulations of the 2010–2011 Canterbury earthquake sequence. Earthquake Spectra36(2) 856–879.
24.
DregerDSJordanTH (2015) Introduction to the focus section on validation of the SCEC broadband platform V14.3 simulation methods. Seismological Research Letters86: 15–16.
25.
DregerDSBerozaGCDaySM, et al. (2015) Validation of the SCEC broadband platform V14.3 simulation methods using pseudospectral acceleration data. Seismological Research Letters86: 39–47.
26.
Eberhart-PhillipsDReynersMBannisterS, et al. (2010) Establishing a versatile 3-D seismic velocity model for New Zealand. Seismological Research Letters81: 992–1000.
27.
GouletCAAbrahamsonNASomervillePG, et al. (2015) The SCEC broadband platform validation exercise: Methodology for code validation in the context of seismic-hazard analyses. Seismological Research Letters86: 17–26.
28.
GravesRPitarkaA (2015) Refinements to the Graves and Pitarka (2010) broadband ground-motion simulation method. Seismological Research Letters86: 75–80.
29.
GravesRPitarkaA (2016) Kinematic ground-motion simulations on rough faults including effects of 3D stochastic velocity perturbations. Bulletin of the Seismological Society of America106: 2136–2153.
30.
GravesRJordanTHCallaghanS, et al. (2011) CyberShake: A physics-based seismic hazard model for southern California. Pure and Applied Geophysics168: 367–381.
31.
GravesRWPitarkaA (2010) Broadband ground-motion simulation using a hybrid approach. Bulletin of the Seismological Society of America100: 2095–2123.
32.
HartzellSFrankelALiuP, et al. (2011) Model and parametric uncertainty in source-based kinematic models of earthquake ground motion. Bulletin of the Seismological Society of America101: 2431–2452.
33.
ImperatoriWGallovičF (2017) Validation of 3D velocity models using earthquakes with shallow slip: Case study of the 2014 Mw 6.0 south Napa, California, event. Bulletin of the Seismological Society of America107: 1019–1026.
34.
JeongSBradleyBA (2017) Amplification of strong ground motions at Heathcote Valley during the 2010–2011 Canterbury earthquakes: The role of 2D nonlinear site response. Bulletin of the Seismological Society of America107: 2117–2130Inpress.
35.
KaiserAHoldenCMasseyC (2014) Site amplification, polarity and topographic effects in the Port Hills during the Canterbury earthquake sequence. GNS Science Consultancy Report 2014/121, July. Lower Hutt, New Zealand: GNS Science.
36.
KomatitschDLiuQTrompJ, et al. (2004) Simulations of ground motion in the Los Angeles basin based upon the spectral-element method. Bulletin of the Seismological Society of America94: 187–206.
37.
LeeRLBradleyBAMcGannCR (2017a) 3D models of quaternary-aged sedimentary successions within the Canterbury, New Zealand region. New Zealand Journal of Geology and Geophysics60: 320–340.
38.
LeeRLBradleyBAGhisettiFG, et al. (2017b) Development of a 3D velocity model of the Canterbury, New Zealand region for broadband ground motion simulations. Bulletin of the Seismological Society of America107: 2131–2150.
39.
MaiPMImperatoriWOlsenKB (2010) Hybrid broadband ground-motion simulations: Combining long-period deterministic synthetics with high-frequency multiple S-to-S backscattering. Bulletin of the Seismological Society of America100: 2124–2142.
40.
MaufroyEChaljubEHollenderF, et al. (2015) Earthquake ground motion in the Mygdonian basin, Greece: The E2VP verification and validation of 3D numerical simulation up to 4 Hz. Bulletin of the Seismological Society of America105: 1398–1418.
41.
OlsenKTakedatsuR (2015) The SDSU broadband ground-motion generation module BBtoolbox version 1.5. Seismological Research Letters86: 81–88.
42.
OthAKaiserAE (2014) Stress release and source scaling of the 2010–2011 Canterbury, New Zealand earthquake sequence from spectral inversion of ground motion data. Pure and Applied Geophysics171: 2767–2782.
43.
PorterKJonesLCoxD, et al. (2011) The ShakeOut scenario: A hypothetical Mw7. 8 earthquake on the southern San Andreas fault. Earthquake Spectra27: 239–261.
44.
RazafindrakotoHBradleyBGravesR (2016) Broadband ground motion simulation of the 2010–2011 Canterbury earthquake sequence. In: Proceedings of the New Zealand society for earthquake engineering conference. Christchurch, New Zealand, 26–28 April.
45.
RazafindrakotoHNBradleyBAGravesRW (2018) Broadband ground-motion simulation of the 2011 Mw 6.2 Christchurch earthquake, New Zealand. Bulletin of the Seismological Society of America108: 2130–2147.
46.
RistauJ (2008.) Implementation of routine regional moment tensor analysis in New Zealand. Seismological Research Letters79: 400–415.
47.
Rodriguez-MarekAMontalvaGACottonF, et al. (2011) Analysis of single-station standard deviation using the KiK-net data. Bulletin of the Seismological Society of America101: 1242–1258.
48.
SibsonRGhisettiFRistauJ (2011) Stress control of an evolving strike-slip fault system during the 2010–2011 Canterbury, New Zealand, earthquake sequence. Seismological Research Letters82: 824–832.
49.
StaffordPJ (2014) Crossed and nested mixed-effects approaches for enhanced model development and removal of the ergodic assumption in empirical ground-motion models. Bulletin of the Seismological Society of America104: 702–719.
50.
TabordaRBielakJ (2013) Ground-motion simulation and validation of the 2008 Chino Hills, California, earthquake. Bulletin of the Seismological Society of America103: 131–156.
51.
TabordaRAzizzadeh-RoodpishSKhoshnevisN, et al. (2016) Evaluation of the southern California seismic velocity models through simulation of recorded events. Geophysical Journal International205: 1342–1364.
52.
ThomsonEMBradleyBALeeRL (2020) Methodology and computational implementation of a New Zealand velocity model (NZVM2.0) for broadband ground motion simulation. New Zealand Journal of Geology and Geophysics63: 110–127.
53.
TrugmanDTShearerPM (2018) Strong correlation between stress drop and peak ground acceleration for recent M 1–4 Earthquakes in the San Francisco Bay Area. Bulletin of the Seismological Society of America108: 929–945.
54.
Van HoutteCKtenidouO-JLarkinT, et al. (2012) Reference stations for Christchurch. Bulletin of the New Zealand Society for Earthquake Engineering45: 184–195.
55.
Van HoutteCKtenidouO-JLarkinT, et al. (2014) Hard-site k0 (kappa) calculations for Christchurch, New Zealand, and comparison with local ground-motion prediction models. Bulletin of the Seismological Society of America104: 1899–1913.
56.
WoodCMCoxBRWotherspoonLM, et al. (2011) Dynamic site characterization of Christchurch strong motion stations. Bulletin of the New Zealand Society for Earthquake Engineering44: 195–204.
57.
WotherspoonLBradleyBThomsonE, et al. (2016) Dynamic site characterisation of Canterbury strong motion stations using active and passive surface wave testing. EQC Report 14/663, 30June. Auckland, New Zealand: University of Auckland.
58.
WotherspoonLOrenseRBradleyB, et al. (2014) Geotechnical characterisation of Christchurch strong motion stations. EQC Report 12/629, 31October. Auckland, New Zealand: University of Auckland.
59.
WotherspoonLOrenseRBradleyB, et al. (2015) Soil profile characterisation of Christchurch Central Business District strong motion stations. Bulletin of the New Zealand Society for Earthquake Engineering44: 195–204.
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