International Benchmark on Numerical Simulations for 1D, Nonlinear Site Response (PRENOLIN): Verification Phase Based on Canonical Cases

Régnier, Julie; Bonilla, Luis Fabián; Bard, Pierre Yves; Bertrand, Éric; Hollender, Fabrice; Kawase, Hiroshi; Sicilia, D.; Arduino, Pedro; Amorosi, A.; Asimaki, Domniki; Boldini, Daniela; Chen, Long; Chiaradonna, Anna; Demartin, Florent; Ebrille, Marco; Elgamal, Ahmed; Falcone, Gaetano; Foerster, Evelyne; Foti, Sebastiano; Garini, Evangelia; Gazetas, George; Gelis, Céline; Ghofrani, Alborz; Γιαννακού, Αμαλία; Gingery, James R.; Glinsky, Nathalie; Harmon, Joseph; Hashash, Youssef M. A.; Iai, Susumu; Jeremić, Boris; Kramer, S.L.; Kontoe, Stavroula; Kristek, Jozef; Lanzo, Giuseppe; Lernia, A. di; López-Caballero, Fernando; Marot, Marianne; McAllister, Graeme; Mercerat, Diego; Moczo, Peter; Montoya-Noguera, Silvana; Musgrove, Michael; Nieto-Ferro, Alex; Pagliaroli, Alessandro; Pisanò, Federico; Richterova, Aneta; Suwal, Sajana; d’Avila, Maria Paola Santisi; Shi, Juntai; Silvestri, Francesco; Taiebat, Mahdi; Tropeano, Giuseppe; Verrucci, Luca; Watanabe, Kohei

doi:10.1785/0120150284

Cited by 93 publications

(43 citation statements)

References 50 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…One set of time histories on soil is generated that is based on the SHAKE91 equivalent-linear (EL) code [42][43][44], while the second set was derived using the NOAH [45] fully non-linear code (NL). Both of the codes were used with the objective of incorporating somehow the code-to-code variability, which has been shown in all recent benchmarking exercises to be very important [46,47]. The final step in the SM method consists in deriving the site-specific hazard curve by simply calculating the annual rate of exceedance from the set of surface synthetic time series.…”

Section: Methodsmentioning

confidence: 99%

Integration of Site Effects into Probabilistic Seismic Hazard Assessment (PSHA): A Comparison between Two Fully Probabilistic Methods on the Euroseistest Site

et al. 2018

View full text Add to dashboard Cite

The integration of site effects into Probabilistic Seismic Hazard Assessment (PSHA) is still an open issue within the seismic hazard community. Several approaches have been proposed varying from deterministic to fully probabilistic, through hybrid (probabilistic-deterministic) approaches. The present study compares the hazard curves that have been obtained for a thick, soft non-linear site with two different fully probabilistic, site-specific seismic hazard methods: (1) The analytical approximation of the full convolution method (AM) proposed by Bazzurro and Cornell 2004a,b and (2) what we call the Full Probabilistic Stochastic Method (SM). The AM computes the site-specific hazard curve on soil, HC(Sas(f)), by convolving for each oscillator frequency the bedrock hazard curve, HC(Sar(f)), with a simplified representation of the probability distribution of the amplification function, AF(f), at the considered site The SM hazard curve is built from stochastic time histories on soil or rock corresponding to a representative, long enough synthetic catalog of seismic events. This comparison is performed for the example case of the Euroseistest site near Thessaloniki (Greece). For this purpose, we generate a long synthetic earthquake catalog, we calculate synthetic time histories on rock with the stochastic point source approach, and then scale them using an adhoc frequency-dependent correction factor to fit the specific rock target hazard. We then propagate the rock stochastic time histories, from depth to surface using two different one-dimensional (1D) numerical site response analyses, while using an equivalent-linear (EL) and a non-linear (NL) code to account for code-to-code variability. Lastly, we compute the probability distribution of the non-linear site amplification function, AF(f), for both site response analyses, and derive the site-specific hazard curve with both AM and SM methods, to account for method-to-method variability. The code-to-code variability (EL and NL) is found to be significant, providing a much larger contribution to the uncertainty in hazard estimates, than the method-to-method variability: AM and SM results are found comparable whenever simultaneously applicable. However, the AM method is also shown to exhibit severe limitations in the case of strong non-linearity, leading to ground motion “saturation”, so that finally the SM method is to be preferred, despite its much higher computational price. Finally, we encourage the use of ground-motion simulations to integrate site effects into PSHA, since models with different levels of complexity can be included (e.g., point source, extended source, 1D, two-dimensional (2D), and three-dimensional (3D) site response analysis, kappa effect, hard rock …), and the corresponding variability of the site response can be quantified.

show abstract

Section: Methodsmentioning

confidence: 99%

Integration of Site Effects into Probabilistic Seismic Hazard Assessment (PSHA): A Comparison between Two Fully Probabilistic Methods on the Euroseistest Site

et al. 2018

View full text Add to dashboard Cite

show abstract

“…The damping ratio chosen for both sets of analyses is 3%, which results in a smooth transfer function where the effect of noise is minimized. The choice of this damping ratio (Regnier et al 2016), where a series of tests were conducted to determine the most appropriate damping value for viscous-elastic analysis. It is easy to fix the damping ratio in STRATA but more challenging in Abaqus because it treats damping in a different way (Volpini et al 2018).…”

Section: Defining the Toolsmentioning

confidence: 99%

“…Secondly, to make the soil profile considered more realistic than a single soil layer overlying a stiff bedrock layer, the analysis was repeated using an idealized shear wave velocity profile from the Prenolin project (Regnier et al 2016), described by this equation: . 9 Summary of the Pearson's sample correlation coefficient, r, for all analyses.…”

Section: Investigating Numerically the Boundary Between 1d/2d Sra Formentioning

confidence: 99%

An accessible approach for the site response analysis of quasi-horizontal layered deposits

Volpini

Douglas

2018

Bull Earthquake Eng

View full text Add to dashboard Cite

This study focusses on site response analysis for sites that are neither strictly one-dimensional (with flat parallel soil layers) nor clearly two-dimensional (steep valleys, canyons and basins). Both these types of geometries are well studied in the literature. There is a lack of studies, however, for all those geometries that are in between these two worlds, such as sites with gently dipping layers. Theoretically, such sites should be studied with a two-dimensional dynamic approach because of the formation of surface waves due to the non-horizontal layering. In certain situations, however, the one-dimensional dynamic assumption leads to minor errors and it may save a lot of effort in terms of defining a two-dimensional model, computing the response and interpreting the results. As a result of these practical advantages, an accessible approach is presented here to determine when one-dimensional analysis can be used for geometries consisting of quasi-horizontal layers. The methodology is based on the construction of a chart, delimiting the applicability of the one-dimensional approach, using simple but valid variables, such as the slope of the critical subsurface interface and the impedance contrast at this interface. Indeed, we propose our guidance on the limits of the one-dimensional analysis in the form of this power law separating the one-dimensional and two-dimensional dynamic regimes: I z = 6.95 γ −0.69 , where I z is the impedance contrast and γ is the angle in degrees of the sloping critical subsurface interface. Site response analysis for geometries with values of I z below this critical value can be computed using a standard one-dimensional approach without large error whereas geometries with values of I z above this threshold require two-dimensional calculations.

show abstract

“…Recent earthquakes, such as the Athens (Greece, 1999) [9], the Kocaeli (Turkey, 1999) [10], the Haiti (2010) [11], and the Gorkha (Nepal, 2015) [12][13][14] earthquakes, showed the importance of taking into account soil amplifications. In the literature, several approaches have been applied to perform ground motion analyses including site effects: hybrid analyses that consist of a combination of probabilistic and deterministic methods (e.g., [15,16]), convolution approaches that provide modifications of the rocking hazard (e.g., [17,18]), and 1D seismic site response analyses (e.g., [19,20]).…”

Section: Introductionmentioning

confidence: 99%

Soil–Structure Interaction Assessment of the 23 November 1980 Irpinia-Basilicata Earthquake

Mina

Forcellini

2020

Geosciences

View full text Add to dashboard Cite

This paper aimed to present a systematic study of the effects caused by the strong earthquake that struck southern Italy on 23 November 1980 (Ms = 6.9) and affected the Campania and Basilicata regions. Two aspects are discussed here: The broadening of the knowledge of the response site effects by considering several soil free-field conditions and the assessment of the role of the soil–structure interaction (SSI) on a representative benchmark structure. This research study, based on the state-of-the-art knowledge, may be applied to assess future seismic events and to propose new original code provisions. The numerical simulations were herein performed with the advanced platform OpenSees, which can consider non-linear models for both the structure and the soil. The results show the importance of considering the SSI in the seismic assessment of soil amplifications and its consequences on the structural performance.

show abstract

International Benchmark on Numerical Simulations for 1D, Nonlinear Site Response (PRENOLIN): Verification Phase Based on Canonical Cases

Cited by 93 publications

References 50 publications

Integration of Site Effects into Probabilistic Seismic Hazard Assessment (PSHA): A Comparison between Two Fully Probabilistic Methods on the Euroseistest Site

Integration of Site Effects into Probabilistic Seismic Hazard Assessment (PSHA): A Comparison between Two Fully Probabilistic Methods on the Euroseistest Site

An accessible approach for the site response analysis of quasi-horizontal layered deposits

Soil–Structure Interaction Assessment of the 23 November 1980 Irpinia-Basilicata Earthquake

Contact Info

Product

Resources

About