The growth of global ground-motion databases has allowed generation of non-ergodic ground-motion prediction equations (GMPEs) based on specific on-site recordings. Several studies have investigated the differences between the hazard estimates from ergodic versus non-ergodic GMPEs. Here instead we focus on the impact of non-ergodic PSHA estimates on the seismic risk of nonlinear single-degree-of-freedom systems representing ductile structures and compare it with the traditional risk estimates obtained using ergodic GMPEs. The structure-and-site-specific risk estimates depend not only on the difference in the hazard estimates but also on the different hazard-consistent ground-motion record selection that informs the response calculation. The more accurate structure-and-site-specific non-ergodic risk estimates show that traditional ones may be biased in a way impossible to predict a priori. Hence, the use of the non-ergodic approach is recommended, whenever possible. However, further advancements of non-ergodic GMPEs are necessary before being routinely utilized in real-life risk assessment applications.
AkkarSSandıkkayaMBommerJ (2014a) Empirical ground-motion models for point-and extended-source crustal earthquake scenarios in Europe and the Middle East. Bulletin of Earthquake Engineering12: 359–387.
2.
AkkarSSandıkkayaMŞenyurtMSisiAAAyBTraversaPDouglasJCottonFLuziLHernandezBGodeyS (2014b) Reference database for seismic ground-motion in Europe (RESORCE). Bulletin of Earthquake Engineering12: 311–339.
3.
Al AtikLAbrahamsonNBommerJJScherbaumFCottonFKuehnN (2010) The variability of ground-motion prediction models and its components. Seismological Research Letters81: 794–801.
AndersonJGBruneJN (1999) Probabilistic seismic hazard analysis without the ergodic assumption. Seismological Research Letters70: 19–28.
6.
AristizábalCBardP-YBeauvalCGómezJ (2018) Integration of site effects into probabilistic seismic hazard assessment (PSHA): A comparison between two fully probabilistic methods on the euroseistest site. Geosciences8: 285.
7.
BazzurroPCornellCA (2004) Nonlinear soil-site effects in probabilistic seismic-hazard analysis. Bulletin of the Seismological Society of America94: 2110–2123.
8.
BindiDMassaMLuziLAmeriGPacorFPugliaRAuglieraP (2014) Pan-European ground-motion prediction equations for the average horizontal component of PGA, PGV, and 5 %-damped PSA at spectral periods up to 3.0 s using the RESORCE dataset. Bulletin of Earthquake Engineering12: 391–430.
9.
BommerJJAbrahamsonNA (2006) Why do modern probabilistic seismic-hazard analyses often lead to increased hazard estimates?Bulletin of the Seismological Society of America96: 1967–1977.
10.
ChiouBDarraghRGregorNSilvaW (2008) NGA project strong-motion database. Earthquake Spectra24: 23–44.
11.
CodeP (2005) Eurocode 8: Design of Structures for Earthquake Resistance-Part 1: General Rules, Seismic Actions and Rules for Buildings. Brussels: European Committee for Standardization.
12.
CornellCA (1968) Engineering seismic risk analysis. Bulletin of the Seismological Society of America58: 1583–1606.
13.
JalayerFCornellCA (2009) Alternative nonlinear demand estimation methods for probability-based seismic assessments. Earthquake Engineering & Structural Dynamics38: 951–972.
14.
JayaramNLinTBakerJW (2011) A computationally efficient ground-motion selection algorithm for matching a target response spectrum mean and variance. Earthquake Spectra27: 797–815.
15.
KamaiRAbrahamsonNASilvaWJ (2014) Nonlinear horizontal site amplification for constraining the NGA-West2 GMPEs. Earthquake Spectra30: 1223–1240.
16.
KohrangiMVamvatsikosDBazzurroP (2017) Site dependence and record selection schemes for building fragility and regional loss assessment. Earthquake Engineering & Structural Dynamics46: 1625–1643.
17.
KothaSRBazzurroPPaganiM (2018a) Effects of epistemic uncertainty in seismic hazard estimates on building portfolio losses. Earthquake Spectra34: 217–236.
18.
KothaSRBindiDCottonF (2016) Partially non-ergodic region specific GMPE for Europe and Middle-East. Bulletin of Earthquake Engineering14: 1245–1263.
19.
KothaSRBindiDCottonF (2017a) From ergodic to region- and site-specific probabilistic seismic hazard assessment: Method development and application at European and Middle Eastern sites. Earthquake Spectra33: 1433–1453.
20.
KothaSRBindiDCottonF (2017b) Site-corrected magnitude- and region-dependent correlations of horizontal peak spectral amplitudes. Earthquake Spectra33: 1415–1432.
21.
KothaSRCottonFBindiD (2018b) A new approach to site classification: Mixed-effects ground motion prediction equation with spectral clustering of site amplification functions. Soil Dynamics and Earthquake Engineering110: 318–329.
22.
LinTHarmsenSCBakerJWLucoN (2013) Conditional spectrum computation incorporating multiple causal earthquakes and ground-motion prediction models. Bulletin of the Seismological Society of America103: 1103–1116.
PaganiMMonelliDWeatherillGDanciuLCrowleyHSilvaVHenshawPButlerLNastasiMPanzeriLSimionatoMViganoD (2014) OpenQuake Engine: An open hazard (and risk) software for the global earthquake model. Seismological Research Letters85: 692–702.
25.
PilzMCottonF (2019) Does the one-dimensional assumption hold for site response analysis? A study of seismic site responses and implication for ground motion assessment using KiK-Net strong-motion data. Earthquake Spectra35: 883–905.
26.
RathjeEPehlivanMGilbertRRodriguez-MarekA (2015) Incorporating site response into seismic hazard assessments for critical facilities: A probabilistic approach. In: AnsalASakrM (eds) Perspectives on Earthquake Geotechnical Engineering. New York: Springer, pp. 93–111.
27.
Rodriguez-MarekACottonFAbrahamsonNAAkkarSAl AtikLEdwardsBMontalvaGADawoodHM (2013) A model for single-station standard deviation using data from various tectonic regions. Bulletin of the Seismological Society of America103: 3149–3163.
28.
SandıkkayaMAAkkarSBardPY (2013) A nonlinear site-amplification model for the next pan-European ground-motion prediction equations. Bulletin of the Seismological Society of America103: 19–32.
29.
ScheingraberCKäserMA (2019) The impact of portfolio location uncertainty on probabilistic seismic risk analysis. Risk Analysis39: 695–712.
30.
SeyhanEStewartJP (2014) Semi-empirical nonlinear site amplification from NGA-West2 data and simulations. Earthquake Spectra30: 1241–1256.
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.
33.
StewartJPAfshariKGouletCA (2017) Non-ergodic site response in seismic hazard analysis. Earthquake Spectra33: 1385–1414.
34.
Structural Engineering Institute (2006) Minimum Design Loads for Buildings and Other Structures, Vol. 5 and 7. Reston, VA: American Society of Civil Engineers.
35.
VillaniMAbrahamsonNA (2015) Repeatable site and path effects on the ground-motion sigma based on empirical data from southern California and simulated waveforms from the CyberShake platform. Bulletin of the Seismological Society of America105: 2681–2695.
36.
WeatherillGKothaSRCottonF (2020) Re-thinking site amplification in regional seismic risk assessment. Earthquake Spectra36(S1) 274–297.
37.
WeatherillGSilvaVCrowleyHBazzurroP (2015) Exploring the impact of spatial correlations and uncertainties for portfolio analysis in probabilistic seismic loss estimation. Bulletin of Earthquake Engineering13: 957–981.
38.
WoessnerJLaurentiuDGiardiniDCrowleyHCottonFGrünthalGValensiseGArvidssonRBasiliRDemirciogluMBHiemerSMelettiCMussonRWRovidaANSesetyanKStucchiM (2015) The 2013 European Seismic Hazard Model: Key components and results. Bulletin of Earthquake Engineering13: 3553–3596.
Supplementary Material
Please find the following supplemental material available below.
For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.
For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.
