A time-averaged 30-m-depth shear wave velocity (VS30) map is developed for New Zealand as a weighted combination of a geology-based and a terrain-based model. A Bayesian updating process allows local VS30 measurements to control model estimates where data exist and uses model estimates developed for other parts of the world where local data are sparse or nonexistent. Geostatistical interpolation is performed on the geology-based and terrain-based models using local VS30 measurements to constrain the model in the vicinity of data. Conventional regression kriging is compared with a flexible multivariate normal (MVN) approach that allows for arbitrary assumptions regarding measurement uncertainty at each data location. A modification to the covariance structure in the MVN application allows for more realistic estimates by reducing undesirable extrapolation across geologic boundaries. The results of kriging and MVN approaches are compared. The geology-based and terrain-based MVN models are combined to produce a final model suitable for engineering applications. The 100-m resolution map outputs are publicly available.
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References
1.
AhdiS. K.StewartJ. P.AnchetaT. D.KwakD. Y. and MitraD.2017a. Development of VS profile database and proxy-based models for VS30 prediction in the Pacific Northwest region of North America, Bulletin of the Seismological Society of America107, 1781–1801.
2.
AhdiS. K.StewartJ. P.KwakD. Y.AnchetaT. D. and MitraD.2017b. Proxy-based VS30 prediction in Alaska accounting for limited regional data, Paper No. 482, in Proceedings, Third International Conference on Performance-Based Design in Earthquake Geotechnical Engineering, 16–19 July, 2017, Vancouver, Canada.
3.
AllenT. I. and WaldD. J.2007. Topographic Slope as a Proxy for Seismic Site-Conditions (VS30) and Amplification Around the Globe, Open-File Report 2007-1357, U.S. Geological Survey, Reston, VA.
4.
BarringerJ. R. F.PairmanD. and McNeillS. J.2002. Development of a High-Resolution Digital Elevation Model for New Zealand, Landcare Research Contract Report LC0102/170, Landcare Research, Lincoln, New Zealand.
5.
BorcherdtR. D.1994. Estimates of site-dependent response spectra for design (methodology and justification), Earthquake Spectra10, 617–653.
6.
CousinsW. J.PerrinN. D.McVerryG. H.HeffordR. T. and PorrittT. E.1996. Ground Conditions at Strong-Motion Recording Sites in New Zealand, Report 96/33, Institute of Geological & Nuclear Sciences, Lower Hutt, New Zealand.
7.
CoxB. R.WoodC. M.DeschenesR. and PearsonM.2011. University of Arkansas Preliminary Data Report for: Surface Wave Testing in Christchurch, New Zealand Affected by the New Zealand Earthquakes, Work Performed in Conjunction with the NSF RAPID Proposal: Liquefaction and Its Effects on Buildings and Lifelines in the February 22, 2011 Christchurch, New Zealand Earthquake, University of Arkansas, Fayetteville.
8.
CoxB. R.WoodC. M. and TeagueD. P.2014. Synthesis of the UTexas1 surface wave dataset blind-analysis study: Inter-analyst dispersion and shear wave velocity uncertainty, in Geo-Congress 2014 Technical Papers: Geo-Characterization and Modeling for Sustainability (GSP 234), American Society of Civil Engineers, Reston, VA, 850–859.
9.
D'AgostiniG.2003. Bayesian Reasoning in Data Analysis: A Critical Introduction, World Scientific, Singapore, 352 pp.
10.
DeschenesM. R.WoodC. M.WotherspoonL. M.BradleyB. A. and ThomsonE.2018. Development of deep shear wave velocity profiles in the Canterbury Plains, New Zealand, Earthquake Spectra34, 1065–1089.
11.
DestegulU.DellowG. and HeronD.2009. A ground shaking amplification map for New Zealand, Bulletin of the New Zealand Society for Earthquake Engineering42, 122.
12.
DiggleP. J. and RibeiroP. J.Jr., 2007. Model-Based Geostatistics, Springer, New York, NY, 232 pp.
13.
FarrT. G.RosenP. A.CaroE.CrippenR.DurenR.HensleyS.KobrickM.PallerM.RodriguezE.RothL.SealD.ShafferS.ShimadaJ.UmlandJ.WernerM.OskinM.BurbankD. and AlsdorfD.2007. The Shuttle Radar Topography Mission, Reviews of Geophysics45, RG2004.
14.
FosterK.2018. Vs30 model for New Zealand based on geology, terrain and observational data inputs, available at https://github.com/fostergeotech/Vs30_NZ (last accessed July 2019).
15.
GelmanA.CarlinJ. B.SternH. S.DunsonD. B.VehtariA. and RubinD. B.2014. Bayesian Data Analysis, 3rd edition, CRC Press, Boca Raton, FL, 639 pp.
HornB. K. P.1981. Hill shading and the reflectance map, Proceedings of the IEEE69, 14–47.
18.
IwahashiJ. and PikeR. J.2007. Automated classifications of topography from DEMs by an unsupervised nested-means algorithm and a three-part geometric signature, Geomorphology86, 409–440.
19.
JayaramN. and BakerJ. W.2009. Correlation model for spatially distributed ground-motion intensities, Earthquake Engineering and Structural Dynamics38, 1687–1708.
20.
KaiserA.Van HoutteC.PerrinN.WotherspoonL. and McVerryG.2017. Site characterisation of GeoNet stations for the New Zealand strong motion database, Bulletin of the New Zealand Society for Earthquake Engineering50, 39–49.
21.
KwokO. L. A.StewartJ. P.KwakD. Y. and SunP. -L.2018. Taiwan-specific model for VS30 prediction considering between-proxy correlations, Earthquake Spectra34, 1973–1993.
LeeC. -T. and TsaiB. -R.2008. Mapping Vs30 in Taiwan, Terrestrial, Atmospheric and Oceanic Sciences19, 671–682.
24.
McElreathR.2015. Statistical Rethinking: A Bayesian Course with Examples in R and Stan, CRC Press, Boca Raton, FL, 469 pp.
25.
McGannC. R.BradleyB. A. and CubrinovskiM.2017. Development of regional VS30 Model and typical Vs profiles for Christchurch, New Zealand from CPT data and region-specific CPT-Vs correlation, Soil Dynamics and Earthquake Engineering95, 48–60.
26.
McGannC. R.BradleyB. A.TaylorM. L.WotherspoonL. M. and CubrinovskiM.2015. Development of an empirical correlation for predicting shear wave velocity of Christchurch soils from cone penetration test data. Soil Dynamics and Earthquake Engineering75, 66–75.
27.
MossR. E. S.2008. Quantifying measurement uncertainty of thirty-meter shear-wave velocity, Bulletin of the Seismological Society of America98, 1399–1411.
28.
ParkerG. A.HarmonJ. A.StewartJ. P.HashashY. M. A.KottkeA. R.RathjeE. M.SilvaW. J. and CampbellK. W.2017. Proxy-based VS30 estimation in Central and Eastern North America, Bulletin of the Seismological Society of America107, 117–131.
29.
PebesmaE. J.2014. Gstat User's Manual (Version 2.5.1), Free Software Foundation, Boston, MA, available at http://gstat.org/gstat.pdf (last accessed August 2019).
30.
PerrinN. DHeronD.KaiserA. and Van HoutteC.2015. VS30 and NZS 1170.5 site class maps of New Zealand, in Proceedings, 2015 NZSEE Conference, New Zealand Society for Earthquake Engineering, Wellington, New Zealand, 10–12.
31.
Standards New Zealand, 1992. Code of Practice for General Structural Design and Design Loadings for Buildings, NZS 4203:1992, Wellington, New Zealand.
32.
Standards New Zealand, 2004. Structural Design Actions: Part 5: Earthquake Actions – New Zealand, NZS 1170.5:2004, Wellington, New Zealand.
33.
TeagueD.CoxB.BradleyB. and WotherspoonL.2018. Development of deep shear wave velocity profiles with estimates of uncertainty in the complex interbedded geology of Christchurch, New Zealand, Earthquake Spectra34, 639–672.
34.
ThompsonE. M. and WaldD. J.2012. Developing Vs30 site-condition maps by combining observations with geologic and topographic constraints, in Proceedings, 15th World Conference on Earthquake Engineering, 24–28 September, 2012, Lisbon, Portugal.
35.
ThompsonE. M.WaldD. J. and WordenC. B.2014. A Vs30 map for California with geologic and topographic constraints, Bulletin of the Seismological Society of America104, 2313–2321.
36.
Van HoutteC.KtenidouO. -J.LarkinT. and HoldenC.2014. Hard-site κ0 (kappa) calculations for Christchurch, New Zealand, and comparison with local ground-motion prediction models, Bulletin of the Seismological Society of America104, 1899–1913.
37.
VilanovaS. P.NarcisoJ.CarvalhoJ. P.LopesI.Quinta-FerreiraM.PintoC. C.MouraR.BorgesJ. and NemserE. S.2018. Developing a geologically based VS30 site-condition model for Portugal: Methodology and assessment of the performance of proxies, Bulletin of the Seismological Society of America108, 322–337.
38.
WaldD. J.McWhirterL.ThompsonE. and HeringA. S.2011. A new strategy for developing VS30 maps, in Proceedings, 4th IASPEI/IAEE International Symposium: Effects of Surface Geology on Seismic Motion, 23–26 August, 2011, Santa Barbara, CA.
39.
WillsC. J. and ClahanK. B.2006. Developing a map of geologically defined site-condition categories for California, Bulletin of the Seismological Society of America96, 1483–1501.
40.
WillsC. and GutierrezC.2009. Investigation of geographic rules for improving site-conditions mapping, in Digital Mapping Techniques ‘08—Workshop Proceedings, U.S. Geological Survey Open-File Report 2009-1298, U.S. Geological Survey, Reston, VA, 205–216.
41.
WoodC. M.CoxB. R.GreenR. A.WotherspoonL. M.BradleyB. A. and CubrinovskiM.2017. Vs-based evaluation of select liquefaction case histories from the 2010-2011 Canterbury earthquake sequence, Journal of Geotechnical and Geoenvironmental Engineering143, 04017066.
42.
WoodC. M.CoxB. R.WotherspoonL. M. and GreenR. A.2011. Dynamic site characterization of Christchurch strong motion stations, Bulletin of the New Zealand Society for Earthquake Engineering44, 195–204.
43.
WordenC. B.ThompsonE. M.BakerJ. W.BradleyB. A.LucoN. and WaldD. J.2018. Spatial and spectral interpolation of ground-motion intensity measure observations, Bulletin of the Seismological Society of America108, 866–875.
44.
WotherspoonL.BradleyB.ThompsonE.WoodC.DeschenesM. and CoxB.2016. Dynamic Site Characterisation of Canterbury Strong Motion Stations Using Active and Passive Surface Wave Testing: Version 1.0 – June 2016, Earthquake Commission Report Project No. 14/663, University of Auckland, New Zealand.
45.
WotherspoonL.OrenseR.BradleyB.CoxB.WoodC. and GreenR.2013. Geotechnical Characterization of Christchurch Strong Motion Stations: Version 1.0 – September 2013, Earthquake Commission Report Project No. 12/629, University of Auckland, New Zealand.
46.
YongA.2016. Comparison of measured and proxy-based VS30 values in California, Earthquake Spectra32, 171–192.
47.
YongA.HoughS. E.IwahashiJ. and BravermanA.2012. A terrain-based site-conditions map of California with implications for the contiguous United States, Bulletin of the Seismological Society of America102, 114–128.
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