Influence of building-site resonance and building properties on site-city interaction: A numerical investigation

Influence of building-site resonance and building properties on site-city interaction: A numerical investigation

Recently, the concept of ground motions within dense urban areas being significantly affected by upper building clusters has been widely accepted. However, multiple interactions between upper buildings and underlain soil layer have increased the complexity of the problem. In this study, we focused o...

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Bibliographic Details
Published in:Soil dynamics and earthquake engineering (1984) Vol. 158; p. 107307
Main Authors: Chen, Shupei, Liu, Qifang, Zhai, Changhai, Wen, Weiping
Format: Journal Article
Language:English
Published: Barking Elsevier Ltd 01-07-2022
Elsevier BV
Subjects:
Building-foundation stiffness ratio
Clusters
Finite element method
Frequencies
Ground motion
Mathematical analysis
Mathematical models
Resonance
Site-building resonance
Site-city interaction
Soil layers
Soil non-linearity
Soil properties
Soils
Urban areas
Urban environment
Site-city interaction
Soil non-linearity
Building-foundation stiffness ratio
Urban environment
Site-building resonance
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Summary:Recently, the concept of ground motions within dense urban areas being significantly affected by upper building clusters has been widely accepted. However, multiple interactions between upper buildings and underlain soil layer have increased the complexity of the problem. In this study, we focused on the analysis of ground motion changes with respect to free-field motion caused by upper building clusters, and the seismic interaction between building clusters and underlain soil, named site-city interaction (SCI). Emphasis was placed on the influence of building-site resonance and building properties on SCI effects. Hence, a two-dimensional (2D) numerical finite element model coupled with a non-linear elastic-plastic soil model and a linear multiple degree-of-freedom building model was developed in the OpenSees framework. Numerical results showed that the SCI effects were strongly influenced by the building-site resonance effects and building properties. For special cases, the ground motion was reduced by more than 60% with respect to the free-field motion. Furthermore, the SCI effects decreased as the degree of soil non-linearity increased, whereas the ground motion caused by SCI effects reduced by more than 20% of the free-field motion. However, owing to the non-linear effects, several unexpected amplifications were observed at certain frequency bands. Overall, the results of this study present an insight into the relationship between building properties, building-site resonance effects and SCI effects, and provide a reference for further SCI analysis of real-life applications. •The influence of site-city interaction on the ground motion was investigated by a numerical method.•Site-city interaction is influenced by the site-building resonance effect, structure-foundation stiffness ratio rk.•Buildings with rk smaller than 0.1 can hardly change the ground motion.•Site-city interaction reduced the peak ground acceleration and Arias intensity in most cases.•Period-dependent site aggravate factors were reduced or aggravated for different periods due to the upper building clusters.
ISSN:0267-7261
1879-341X
DOI:10.1016/j.soildyn.2022.107307