Broadband ground motion simulation procedures typically utilize physics-based modeling at low frequencies, coupled with semi-stochastic procedures at high frequencies. The high-frequency procedure considered here combines deterministic Fourier amplitude spectra (dependent on source, path, and site models) with random phase. Previous work showed that high-frequency intensity measures from this simulation methodology attenuate faster with distance and have lower intra-event dispersion than in empirical equations. We address these issues by increasing crustal damping (Q) to reduce distance attenuation bias and by introducing random site-to-site variations to Fourier amplitudes using a lognormal standard deviation ranging from 0.45 for Mw < 7 to zero for Mw 8. Ground motions simulated with the updated parameterization exhibit significantly reduced distance attenuation bias and revised dispersion terms are more compatible with those from empirical models but remain lower at large distances (e.g., > 100 km).
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References
1.
AagaardB. T., BrocherT. M., DolencD., DregerD., GravesR. W., HarmsenS., HartzellS, LarsenS., McCandlessK., NilssonS., PeterssonN. A., RodgersA., SjögreenB., and ZobackM. L., 2008. Ground-motion modeling of the 1906 San Francisco earthquake, Part II: Ground-motion estimates for the 1906 earthquake and scenario events, Bull. Seism. Soc. Am.98, 1012–1046.
2.
AbrahamsonN. A., and SilvaW. J., 2008. Summary of the Abrahamson and Silva NGA ground motion relations, Earthquake Spectra24, 67–97.
3.
AbrahamsonN. A., AtkinsonG. M., BooreD. M., BozorgniaY., CampbellK. W., ChiouB. S-J., IdrissI. M., SilvaW. J., and YoungsR. R., 2008. Comparisons of the NGA ground-motion relations, Earthquake Spectra24, 45–66.
4.
AmeriG., GallovičF., PacorF., and EmoloA., 2009. Uncertainties in strong ground motion prediction with finite-fault synthetic seismograms: An application to the 1984 M5.7 Gubbio, central Italy, earthquake, Bull. Seism. Soc. Am.99, 647–663.
5.
AnchetaT. D., StewartJ. P., and AbramhamsonN. A., 2011. “Engineering characterization of earthquake ground motion coherency and amplitude variability,” Proc. 4th International Symposium on Effects of Surface Geology on Seismic Motion, IASPEI / IAEE, August 23–26, 2011, University of California Santa Barbara.
6.
AndersonJ. G., and HoughS. E., 1984. A model for the shape of the Fourier amplitude spectrum of acceleration at high frequencies, Bull. Seism. Soc. Am.74, 1969–1993.
7.
AtkinsonG. M., AssatouriansK., BooreD. M., CampbellK. W., and MotazedianD., 2009. A guide to differences between stochastic point-source and stochastic finite-fault simulations, Bull. Seism. Soc. Am. 99, 3192–3201, doi: 10.1785/0120090058.
8.
BeresnevI. A., and AtkinsonG. M., 1997. Modeling finite-fault radiation from the ωn spectrum, Bull. Seism. Soc. Am. 87, 67–84.
9.
BielakJ., GravesR. W., OlsenK. B., TabordaR., Ramirez-GuzmanL., DayS. M., ElyG. P., RotenD., JordanT. H., MaechlingP. J., UrbanicJ., CuiY. F., and JuveG., 2010. The ShakeOut earthquake scenario: Verification of three simulation sets, Geophy. J. International180, 375–404.
10.
BooreD. M., 1983. Stochastic simulation of high-frequency ground motions based on seismological models of the radiated spectra, Bull. Seism. Soc. Am.73, 1865–1894.
11.
BooreD. M., and JoynerW. B., 1997. Site amplifications for generic rock sites,”Bull. Seism. Soc. Am.87, 327–341.
12.
BooreD. M., and AtkinsonG. M., 2008. Ground motion prediction equations for the average horizontal component of PGA, PGV, and 5%-damped PSA at spectral periods between 0.01 and 10.0 s, Earthquake Spectra24, 99–138.
13.
BooreD. M., 2009. Comparing stochastic point-source and finite-source ground-motion simulations: SMSIM and EXSIM, Bull. Seism. Soc. Am. 99, 3202–3216.
14.
CampbellK. W., 2009. Estimates of shear-wave Q and κ0 for unconsolidated and semiconsolidated sediments in eastern North America, Bull. Seism. Soc. Am.99, 2365–2392.
15.
CampbellK. W., and BozorgniaY., 2008. NGA ground motion model for the geometric mean horizontal component of PGA, PGV, PGD and 5% damped linear elastic response spectra for periods ranging from 0.01 to 10 s, Earthquake Spectra24, 139–172.
16.
ChiouB. S-J., and YoungsR. R., 2008. Chiou and Youngs PEER-NGA empirical ground motion model for the average horizontal component of peak acceleration and pseudo-spectral acceleration for spectral periods of 0.01 to 10 seconds, Earthquake Spectra24, 173–215.
17.
ChiouB. S-J., DarraghR., DregorD., and SilvaW. J., 2008. NGA project strong-motion database,”Earthquake Spectra24, 23–44.
18.
ConteJ. P., and PengB. F., 1997. Fully nonstationary analytical earthquake ground-motion model. J. Eng. Mech.123, 15–24.
19.
DayS. M., GravesR. W., BielakJ., DregerD. S., LarsenS., OlsenK. B., PitarkaA., and Ramirez-GuzmanL., 2008. Model for basin effects on long-period response spectra in Southern California, Earthquake Spectra24, 257–277.
20.
FatehiA., and HerrmannR. B., 2008. High-frequency ground-motion scaling in the Pacific northwest and in northern and central California, Bull. Seism. Soc. Am. 98, 709–721.
21.
FrankelA., 1993. Three-dimensional simulations of ground motions in the San Bernardino Valley, California, for hypothetical earthquakes on the San Andreas Fault, Bull. Seism. Soc. Am. 83, 1020–1041.
22.
FrankelA., 1995. Simulating strong motions of large earthquakes using recordings of small earthquakes: The Loma Prieta mainshock as a test case, Bull. Seism. Soc. Am. 85, 1144–1160.
23.
FrankelA., 2009. A constant stress-drop model for producing broadband synthetic seismograms: Comparison with the Next Generation Attenuation relations, Bull. Seism. Soc. Am. 99, 664–680.
24.
GravesR. W., AagaardB. T., HudnutK. W., StarL. M., StewartJ. P., and JordanT. H., 2008. Broadband simulations for Mw 7.8 southern San Andreas earthquakes: Ground motion sensitivity to rupture speed, Geophys. Res. Lett. 35, L22302, doi:10.1029/2008GL035750.
25.
GravesR.W., and PitarkaA., 2010. Broadband ground-motion simulation using a hybrid approach, Bull. Seism. Soc. Am. 100, 2095–2123.
26.
GravesR. W., AagaardB. T., and HudnutK. W., 2011. The ShakeOut earthquake source and ground motion simulations, Earthquake Spectra27, 273–291.
27.
GuatteriM., MaiP. M., and BerozaG. C., 2004. A pseudo-dynamic approximation to dynamic rupture models for strong ground motion prediction, Bull. Seism. Soc. Am. 94, 2051–2063.
28.
HarmsenS., and FrankelA., 2001. Geographic deaggregation of seismic hazard in the United States, Bull. Seism. Soc. Am. 91, 13–26.
29.
HartzellS., HarmsenS., FrankelA., and LarsenS., 1999. Calculation of broadband time histories of ground motion: Comparison of methods and validation using strong-ground motion from the 1994 Northridge Earthquake, Bull. Seism. Soc. Am. 89, 1484–1504.
30.
HartzellS., GuatteriM., MaiP. M., LiuP-C., and FiskM., 2005. Calculation of broadband time histories of ground motion, Part II: Kinematic and dynamic modeling using theoretical Green's functions and comparison with the 1994 Northridge earthquake, Bull. Seismol. Soc. Am. 95, 614–645.
31.
LiuH., and HelmbergerD. V., 1985. The 23:19 aftershock of the October 1979 Imperial Valley earthquake: More evidence for an asperity, Bull. Seism. Soc. Am. 75, 689–708.
32.
LiuP., ArchuletaR. J., and HartzellS. H., 2006. Prediction of broadband ground-motion time histories: hybrid low/high- frequency method with correlated random source parameters, Bull. Seism. Soc. Am. 96, 2118–2130.
33.
MaiP. M., ImperatoriW., and OlsenK. B., 2010. Hybrid broadband ground-motion simulations: combining long-period deterministic synthetics with high-frequency multiple S-to-S backscattering, Bull. Seism. Soc. Am.100, 2124–2142.
34.
MenaB., MaiP. M., OlsenK. B., PurvanceM. D., and BruneJ. N., 2010. Hybrid broadband ground-motion simulation using scattering green's functions: application to large-magnitude events, Bull. Seism. Soc. Am. 100, 2143–2162.
35.
OlsenK. B., and MayhewJ. E., 2010. Goodness-of-fit criteria for broadband synthetic seismograms, with application to the 2008 Mw 5.4 Chino Hills, California, earthquake, Seism. Res. Ltrs.81, 715–723.
36.
OlsenK. B., DayS. M., MinsterJ. B., CuiY., ChourasiaA., OkayaD., MaechlingP., and JordanT., 2008. TeraShake2: “Simulation of Mw 7.7 earthquakes on the southern San Andreas with spontaneous rupture description, Bull. Seism. Soc. Am. 98, 1162–1185.
37.
OlsenK. B., DayS. M., DalguerL. A., MayhewJ., CuiY., ZhuJ., Cruz-AtienzaV. M., RotenD., MaechlingP., JordanT. H., OkayaD., and ChourasiaA., 2009. ShakeOut-D: Ground motion estimates using an ensemble of large earthquakes on the southern San Andreas Fault with spontaneous rupture propagation, Geophys. Res. Lett. 36, L04303, doi:10.1029/2008GL036832.
38.
PorterK. A., JonesL., CoxD., GoltzJ., HudnutK. W., MiletiD., PerryS., PontiD., ReichleM., ScawthornC. R., SeligsonH. A., ShoafK. I., and WeinA., 2011. The ShakeOut scenario: a hypothetical Mw7.8 earthquake on the southern San Andreas Fault, Earthquake Spectra27, 239–261.
39.
PulidoN., and DalguerL. A., 2009. Estimation of the high-frequency radiation of the 2000 Tottori, Japan) earthquake based on a dynamic model of fault rupture: Application to the strong ground motion simulation, Bull. Seism. Soc. Am. 99, 2305–2322.
40.
RaoofM., HerrmannR. B., and MalagniniL., 1999. Attenuation and excitation of three-component ground motion in Southern California, Bull. Seism. Soc. Am. 89, 888–902.
41.
RezaeianS., and Der KiureghianA., 2008. A stochastic ground motion model with separable temporal and spectral nonstationarities, Eqk Engin & Struct. Dyn. 37, 1565–1584.
42.
RippergerJ., MaiP. M., and AmpueroJ. P., 2008. Variability of near-field ground-motion from dynamic earthquake rupture simulation, Bull. Seism. Soc. Am. 98, 1207–1228.
43.
SatoT., GravesR. W., and SomervilleP. G., 1999. Three-dimensional finite-difference simulations of long-period strong motions in the Tokyo metropolitan area during the 1990 Odawara earthquake, MJ 5.1) and the great 1923 Kanto earthquake (MS 8.2) in Japan, Bull. Seism. Soc. Am. 89, 579–607.
44.
SatoH., and FehlerM. C., 1998. Seismic Wave Propagation and Scattering in the Heterogeneous Earth, Springer-Verlag, Inc., New York.
45.
SchmedesJ., ArchuletaR. J., and LavalleD., 2010. Correlation of earthquake source parameters inferred from dynamic rupture simulations, J. Geophys. Res. 115, doi:10.1029/2009JB006689.
46.
SilvaW. J., and DarraghR. B., 1995. Engineering characterization of earthquake strong ground motion recorded at rock sites, Report TR-102261, Electric Power Research Institute, Palo Alto, CA.
47.
SilvaW. J., LiS., DarraghR., and GregorN., 1999. Surface Geology–Based Strong Motion Amplification Factors for the San Francisco Bay and Los Angeles Areas, Report to Pacific Earthquake Engineering Research Center, Berkeley, CA.
48.
StarL. M., StewartJ. P., and GravesR. W., 2011. Comparison of ground motions from hybrid simulations to NGA prediction equations, Earthquake Spectra27, 333–350.
49.
StewartJ. P., SeyhanE., and GravesR. W., 2011. Calibration of semi-stochastic procedure for simulating high-frequency ground motions, PEER Report 2011/09, Pacific Earthquake Engineering Research Center, University of California, Berkeley.
50.
StidhamC., AntolikM., DregerDS, LarsenS, and RamanowiczB, 1999. Three-dimensional structure influences on the strong motion wavefield of the 1989 Loma Prieta earthquake, Bull. Seism. Soc. Am. 89, 1184–1202.
51.
XuJ., BielakJ., GhattasO., and WangJ., 2003. Three-dimensional nonlinear seismic ground motion modeling in basins, Physics of the Earth and Planetary Interiors137, 81–95.
52.
ZengY., AndersonJ. G., and YuG., 1994. A composite source model for computing realistic synthetics strong ground motions, Geophys. Res. Lett. 21, 725–728.
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