A computational workflow for rupture‐to‐structural‐response simulation and its application to Istanbul

Name: A computational workflow for rupture‐to‐structural‐response simulation and its application to Istanbul
Author: Zhang, W. Y., Restrepo, D., Crempien, J. G. F., Erkmen, Bülent, Taborda, R., Kurtuluş, Aslı, Taciroglu, E.

İsim	A computational workflow for rupture‐to‐structural‐response simulation and its application to Istanbul
Yazar	Zhang, W. Y., Restrepo, D., Crempien, J. G. F., Erkmen, Bülent, Taborda, R., Kurtuluş, Aslı, Taciroglu, E.
Basım Tarihi:	2020-10
Basım Yeri	- Wiley
Konu	ABAQUS, Domain reduction method, Foundation input motion, Hercules, High‐performance computing, Perfectly matched layers, Regional‐scale ground motion simulation, Soil‐structure interaction, Substructuring method
Tür	Süreli Yayın
Dil	İngilizce
Dijital	Evet
Yazma	Hayır
Kütüphane:	Özyeğin Üniversitesi
Demirbaş Numarası	0098-8847
Kayıt Numarası	18a4894d-1434-40ac-96bf-33c1efc796d7
Lokasyon	Civil Engineering
Tarih	2020-10
Notlar	TÜBİTAK ; Texas Advanced Computing Center (TACC)
Örnek Metin	Scenario-based earthquake simulations at regional scales hold the promise in advancing the state-of-the-art in seismic risk assessment studies. In this study, a computational workflow is presented that combines (i) a broadband Green's function-based fault-rupture and ground motion simulation-herein carried out using the "UCSB (University of California at Santa Barbara) method", (ii) a three-dimensional physics-based regional-scale wave propagation simulation that is resolved at fmax=11.2 Hz, and (iii) a local soil-foundation-structure finite element analysis model. These models are interfaced with each other using the domain reduction method. The innermost local model-implemented in ABAQUS-is additionally enveloped with perfectly matched layer boundaries that absorb outbound waves scattered by the structures contained within it. The intermediate wave propagation simulation is carried out using Hercules, which is an explicit time-stepping finite element code that is developed and licensed by the CMU-QUAKE group. The devised workflow is applied to a 80x40x40 km3 region on the European side of Istanbul, which was modeled using detailed soil stratigraphy data and realistic fault rupture properties, which are available from prior microzonation surveys and earthquake scenario studies. The innermost local model comprises a chevron-braced steel frame building supported by a shallow foundation slab, which, in turn, rests atop a three-dimensional soil domain. To demonstrate the utility of the workflow, results obtained using various simplified soil-structure interaction analysis techniques are compared with those from the detailed direct model. While the aforementioned demonstration has a limited scope, the devised workflow can be used in a multitude of ways, for example, to examine the effects of shallow-layer soil nonlinearities and surface topography, to devise site- and structure-specific seismic fragilities, and for calibrating regional loss models, to name a few.
DOI	10.1002/eqe.3377
Cilt	50

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A computational workflow for rupture‐to‐structural‐response simulation and its application to Istanbul

Yazar Zhang, W. Y., Restrepo, D., Crempien, J. G. F., Erkmen, Bülent, Taborda, R., Kurtuluş, Aslı, Taciroglu, E.

Basım Tarihi 2020-10

Basım Yeri - Wiley

Konu ABAQUS, Domain reduction method, Foundation input motion, Hercules, High‐performance computing, Perfectly matched layers, Regional‐scale ground motion simulation, Soil‐structure interaction, Substructuring method

Tür Süreli Yayın

Dil İngilizce

Dijital Evet

Yazma Hayır

Kütüphane Özyeğin Üniversitesi

Demirbaş Numarası 0098-8847

Kayıt Numarası 18a4894d-1434-40ac-96bf-33c1efc796d7

Lokasyon Civil Engineering

Tarih 2020-10

Notlar TÜBİTAK ; Texas Advanced Computing Center (TACC)

Örnek Metin Scenario-based earthquake simulations at regional scales hold the promise in advancing the state-of-the-art in seismic risk assessment studies. In this study, a computational workflow is presented that combines (i) a broadband Green's function-based fault-rupture and ground motion simulation-herein carried out using the "UCSB (University of California at Santa Barbara) method", (ii) a three-dimensional physics-based regional-scale wave propagation simulation that is resolved at fmax=11.2 Hz, and (iii) a local soil-foundation-structure finite element analysis model. These models are interfaced with each other using the domain reduction method. The innermost local model-implemented in ABAQUS-is additionally enveloped with perfectly matched layer boundaries that absorb outbound waves scattered by the structures contained within it. The intermediate wave propagation simulation is carried out using Hercules, which is an explicit time-stepping finite element code that is developed and licensed by the CMU-QUAKE group. The devised workflow is applied to a 80x40x40 km3 region on the European side of Istanbul, which was modeled using detailed soil stratigraphy data and realistic fault rupture properties, which are available from prior microzonation surveys and earthquake scenario studies. The innermost local model comprises a chevron-braced steel frame building supported by a shallow foundation slab, which, in turn, rests atop a three-dimensional soil domain. To demonstrate the utility of the workflow, results obtained using various simplified soil-structure interaction analysis techniques are compared with those from the detailed direct model. While the aforementioned demonstration has a limited scope, the devised workflow can be used in a multitude of ways, for example, to examine the effects of shallow-layer soil nonlinearities and surface topography, to devise site- and structure-specific seismic fragilities, and for calibrating regional loss models, to name a few.

DOI 10.1002/eqe.3377

Cilt 50