Constant-ductility energy factors of SDOF systems subjected to mainshock-aftershock sequences

Constant-ductility energy factors of SDOF systems subjected to mainshock-aftershock sequences

This article focuses on the energy factor of single-degree-of-freedom (SDOF) systems subjected to mainshock-aftershock (MSAS) sequences, of which 163 and 143 are collected from crustal and subduction regions, respectively. The recorded MSAS sequences are divided into four groups based on the relativ...

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Bibliographic Details
Published in:Earthquake spectra Vol. 37; no. 2; pp. 1078 - 1107
Main Authors: Ji Duofa, Ji Duofa, Wen Weiping, Wen Weiping, Zhai Changhai, Zhai Changhai
Format: Journal Article
Language:English
Published: London, England Earthquake Engineering Research Institute 01-05-2021
SAGE Publications
Subjects:
acceleration
aftershocks
aseismic design
attenuation
ductility
earthquakes
elastic properties
energy balance
Engineering geology
ground motion
hysteresis
IMK model
main shocks
peak ground acceleration
seismic energy
seismic intensity
Seismology
soil mechanics
statistical analysis
stiffness
structures
swarms
vibration
energy factor
IMK model
single-degree-of-freedom systems
seismic design
Earthquake sequences
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Summary:This article focuses on the energy factor of single-degree-of-freedom (SDOF) systems subjected to mainshock-aftershock (MSAS) sequences, of which 163 and 143 are collected from crustal and subduction regions, respectively. The recorded MSAS sequences are divided into four groups based on the relative intensity that is defined as the ratio of the peak ground acceleration (PGA) of an aftershock to the PGA of the corresponding mainshock. Constant-ductility inelastic spectra are calculated to assess the energy factor, γ, defined as the ratio of the covered area of the skeleton load-deformation curve of the inelastic structural system to that of the corresponding elastic system with identical elastic properties, by considering various levels of structural inelasticity. Moreover, the effect of the hysteresis law, damping ratio, post-yield stiffness ratio, soil condition, and relative intensity on the energy factor is thoroughly analyzed. A predictive model is also developed as a function of the ductility factor, vibration period, damping ratio, and post-yield stiffness ratio. Such a model is expected to facilitate the energy-based seismic design of structures.
ISSN:8755-2930
1944-8201
DOI:10.1177/8755293020952461