The effects of torsion and motion coupling in site response estimation

The effects of torsion and motion coupling in site response estimation

Soil amplification characteristics are investigated using data from the Chibaken‐Toho‐Oki earthquake and its aftershocks recorded at Chiba dense array in Japan. The frequency‐dependent amplification function of soil is calculated using uphole‐to‐downhole spectral ratio analysis, considering the hori...

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Bibliographic Details
Published in:Earthquake engineering & structural dynamics Vol. 32; no. 5; pp. 691 - 709
Main Authors: Ghayamghamian, Mohammad R., Motosaka, Masato
Format: Journal Article
Language:English
Published: Chichester, UK John Wiley & Sons, Ltd 25-04-2003
Wiley
Subjects:
damping ratio
Earth sciences
Earth, ocean, space
Earthquakes, seismology
Exact sciences and technology
Internal geophysics
S-wave coupling
site response
splitting effect
torsion response of the site
vertical array data
Far East
Honshu
Japan
spectral analysis
S-waves
digital simulation
accelerograms
earthquakes
coupling
torsion response of the site
soil dynamics
aftershocks
soils
horizontal component
strain
models
site response
shear
ground motion
splitting effect
damping ratio
propagation
one-dimensional models
Asia
torsion
vertical array data
transfer functions
wave damping
S-wave coupling
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Summary:Soil amplification characteristics are investigated using data from the Chibaken‐Toho‐Oki earthquake and its aftershocks recorded at Chiba dense array in Japan. The frequency‐dependent amplification function of soil is calculated using uphole‐to‐downhole spectral ratio analysis, considering the horizontal components of shear wave. The identified spectral ratios consistently demonstrate the splitting of peaks in their resonance frequencies and low amplification values in comparison with a 1D model. The torsional behaviour and horizontal ground motion coupling are clarified as the reasons for these phenomena at the site. To prove the hypothesis, the torsional motion is directly evaluated using the data of the horizontal dense array in different depths at the site. The comparison between Fourier spectra of torsional motion and identified transfer functions reveals the peaks at the same frequencies. The wave equation including torsion and horizontal motion coupling is introduced and solved for the layered media by applying wave propagation theory. Using the developed model, the effects of torsional motion with horizontal motion coupling on soil transfer function are numerically examined. Splitting and low amplification at resonance frequencies are confirmed by the results of numerical analysis. Furthermore, the ground motion in two horizontal directions at the site is simulated using site geotechnical specification and optimizing the model parameters. The simulated and recorded motions demonstrate good agreement that is used to validate the hypothesis. In addition, the spectral density of torsional ground motions are compared with the calculated one and found to be well predicted by the model. Finally, the results are used to explain the overestimation of damping in back‐calculation of dynamic soil properties using vertical array data in small strain level. Copyright © 2003 John Wiley & Sons, Ltd.
Bibliography:istex:6F589152FF1D7107993C5F4504A3E4F41D323B98
ark:/67375/WNG-GMJ141NT-V
ArticleID:EQE244
ISSN:0098-8847
1096-9845
DOI:10.1002/eqe.244