TY - GEN

T1 - Frequency comparison of the pulse-like and non-pulse ground motions

AU - Chen, G.

AU - Liu, Y.

AU - Beer, M.

PY - 2022

Y1 - 2022

N2 - As one of the essential parameters, the ground motion frequency is of significance for earthquake engineering and seismology. Pulselike ground motions attract increasing attention since it potentially causes severer damage to structures than ordinary ground motion. However, compared with the lots of researches on the time domain, few studies consider the frequency-domain characteristics of pulselike ground motion. Hence, this study attempts to analyze the frequency-domain feature of pulse-like ground motion. Furthermore, owing to the limitation of the Fourier transform on the time-frequency conversion of the non-stationary signals, the frequency-domain characteristics of ground motions are analyzed using the wavelet packet transform. The frequency-domain differences between pulse-like and non-pulse ground motions are compared using recorded and simulated ground motions. The results show that the energy (5%-75%) of pulse-like ground motions concentrates on a shorter frequency band than non-pulse ground motion. Moreover, the cumulative energy of pulse-like ground motion is about twice times of non-pulse ground motion in 0 - 1 Hz, even when the pulse-like and non-pulse ground motion is compatible with the same target spectrum. The non-pulse ground motion, by contrast, has more energies at greater than 10 Hz. Hence, the pulse-like ground motion with high energy in the 0 - 1 Hz potentially causes severer damage to structures, for which the fundamental frequency is less than 1 Hz. The effects of the frequency-domain feature on structural safety will be carried out in further study using non-linear time history analysis.

AB - As one of the essential parameters, the ground motion frequency is of significance for earthquake engineering and seismology. Pulselike ground motions attract increasing attention since it potentially causes severer damage to structures than ordinary ground motion. However, compared with the lots of researches on the time domain, few studies consider the frequency-domain characteristics of pulselike ground motion. Hence, this study attempts to analyze the frequency-domain feature of pulse-like ground motion. Furthermore, owing to the limitation of the Fourier transform on the time-frequency conversion of the non-stationary signals, the frequency-domain characteristics of ground motions are analyzed using the wavelet packet transform. The frequency-domain differences between pulse-like and non-pulse ground motions are compared using recorded and simulated ground motions. The results show that the energy (5%-75%) of pulse-like ground motions concentrates on a shorter frequency band than non-pulse ground motion. Moreover, the cumulative energy of pulse-like ground motion is about twice times of non-pulse ground motion in 0 - 1 Hz, even when the pulse-like and non-pulse ground motion is compatible with the same target spectrum. The non-pulse ground motion, by contrast, has more energies at greater than 10 Hz. Hence, the pulse-like ground motion with high energy in the 0 - 1 Hz potentially causes severer damage to structures, for which the fundamental frequency is less than 1 Hz. The effects of the frequency-domain feature on structural safety will be carried out in further study using non-linear time history analysis.

KW - frequency

KW - near-fault earthquake

KW - pulse-like ground motion

KW - spectrum compatibility

KW - wavelet transform

UR - http://www.scopus.com/inward/record.url?scp=85202038413&partnerID=8YFLogxK

U2 - 10.3850/978-981-18-5184-1_MS-09-134-cd

DO - 10.3850/978-981-18-5184-1_MS-09-134-cd

M3 - Conference contribution

AN - SCOPUS:85202038413

SN - 9789811851841

T3 - Proceedings of the 8th International Symposium on Reliability Engineering and Risk Management, ISRERM 2022

SP - 277

EP - 281

BT - Proceedings of the 8th International Symposium on Reliability Engineering and Risk Management, ISRERM 2022

A2 - Beer, Michael

A2 - Zio, Enrico

A2 - Phoon, Kok-Kwang

A2 - Ayyub, Bilal M.

T2 - 8th International Symposium on Reliability Engineering and Risk Management, ISRERM 2022

Y2 - 4 September 2022 through 7 September 2022

ER -