Decomposing seismic accelerograms with optimized window and its application for generating artificial fully non-Gaussian and nonstationary ground motion time histories

Decomposing seismic accelerograms with optimized window and its application for generating artificial fully non-Gaussian and nonstationary ground motion time histories

In the present study, we propose a framework to simulate artificial seismic ground motion time histories for a given target record based on the time-frequency decomposition with an optimized window. The considered time-frequency decomposition technique is the S-transform (ST), where the optimized wi...

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Bibliographic Details
Published in:Soil dynamics and earthquake engineering (1984) Vol. 154; p. 107124
Main Authors: Cui, X.Z., Hong, H.P.
Format: Journal Article
Language:English
Published: Barking Elsevier Ltd 01-03-2022
Elsevier BV
Subjects:
Algorithms
Decomposition
Earthquake accelerograms
Electric power distribution
Ground motion
Iterative methods
Nonstationary non-Gaussian process
Optimized window
Power spectral density
S-transform
Seismic ground motions
Simulation
Spectra
Spectral density function
Surrogate
Time-frequency analysis
Time-frequency power spectral density function
Transformations (mathematics)
Optimized window
Nonstationary non-Gaussian process
Simulation
Time-frequency power spectral density function
Surrogate
Seismic ground motions
S-transform
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Description
Summary:In the present study, we propose a framework to simulate artificial seismic ground motion time histories for a given target record based on the time-frequency decomposition with an optimized window. The considered time-frequency decomposition technique is the S-transform (ST), where the optimized window is determined based on an energy concentration measure (ECM). For the evaluation of ECM for S-transform, we propose to use the time-frequency power spectral density function rather than the ST coefficients. Depending on the adopted assumption, the use of the iterative power and amplitude correction algorithm (IPAC) or the spectral represent method is suggested. The use of IPAC could also preserve the non-Gaussian characteristics of the target record. The proposed framework to simulate the artificial seismic ground motion time histories can capture the irregular pockets of power concentration in the time-frequency domain, and no assumptions on the functional forms of the spectra are required. The use of the proposed framework in simulating the time histories is illustrated by numerical examples, showing that the zero-upcrossing rate, the power distribution in time and in frequency, and the spectral acceleration of the simulated time histories match well their corresponding targets. •We proposed a new equation to determine the optimized window in S-transform (ST) to process ground motion records.•We suggested a new framework to simulate ground motions for a given target record using the optimized ST.•The simulation framework is efficient and is applicable for fully nonstationary Gaussian/non-Gaussian ground motions.•We showed the characteristics of the sampled ground motions match well those of the target or seed record.
ISSN:0267-7261
1879-341X
DOI:10.1016/j.soildyn.2021.107124