Time-Frequency Energy Distribution of Ground Motion and Its Effect on the Dynamic Response of Nonlinear Structures
The ground motion characteristics are essential for understanding the structural seismic response. In this paper, the time-frequency analytical method is used to analyze the time-frequency energy distribution of ground motion, and its effect on the dynamic response of nonlinear structure is studied...
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doaj-d70717f761eb44118e2d49208916a6f62020-11-24T23:56:42ZengMDPI AGSustainability2071-10502019-01-0111370210.3390/su11030702su11030702Time-Frequency Energy Distribution of Ground Motion and Its Effect on the Dynamic Response of Nonlinear StructuresDongwang Tao0Jiali Lin1Zheng Lu2Institute of Engineering Mechanics, China Earthquake Administration, Harbin 150080, ChinaResearch Institute of Structural Engineering and Disaster Reduction, Tongji University, Shanghai 200092, ChinaResearch Institute of Structural Engineering and Disaster Reduction, Tongji University, Shanghai 200092, ChinaThe ground motion characteristics are essential for understanding the structural seismic response. In this paper, the time-frequency analytical method is used to analyze the time-frequency energy distribution of ground motion, and its effect on the dynamic response of nonlinear structure is studied and discussed. The time-frequency energy distribution of ground motion is obtained by the matching pursuit decomposition algorithm, which not only effectively reflects the energy distribution of different frequency components in time, but also reflects the main frequency components existing near the peak ground acceleration occurrence time. A series of artificial ground motions with the same peak ground acceleration, Fourier amplitude spectrum, and duration are generated and chosen as the earthquake input of the structural response. By analyzing the response of the elasto-perfectly-plastic structure excited by artificial seismic waves, it can be found that the time-frequency energy distribution has a great influence on the structural ductility. Especially if there are even multiple frequency components in the same ground motion phrase, the plastic deformation of the elasto-perfectly-plastic structure will continuously accumulate in a certain direction, resulting in a large nonlinear displacement. This paper reveals that the time-frequency energy distribution of a strong ground motion has a vital influence on the structural response.https://www.mdpi.com/2071-1050/11/3/702ground motionmatching pursuit decompositiontime-frequency energy distributionratcheting effectnonlinear response |
collection |
DOAJ |
language |
English |
format |
Article |
sources |
DOAJ |
author |
Dongwang Tao Jiali Lin Zheng Lu |
spellingShingle |
Dongwang Tao Jiali Lin Zheng Lu Time-Frequency Energy Distribution of Ground Motion and Its Effect on the Dynamic Response of Nonlinear Structures Sustainability ground motion matching pursuit decomposition time-frequency energy distribution ratcheting effect nonlinear response |
author_facet |
Dongwang Tao Jiali Lin Zheng Lu |
author_sort |
Dongwang Tao |
title |
Time-Frequency Energy Distribution of Ground Motion and Its Effect on the Dynamic Response of Nonlinear Structures |
title_short |
Time-Frequency Energy Distribution of Ground Motion and Its Effect on the Dynamic Response of Nonlinear Structures |
title_full |
Time-Frequency Energy Distribution of Ground Motion and Its Effect on the Dynamic Response of Nonlinear Structures |
title_fullStr |
Time-Frequency Energy Distribution of Ground Motion and Its Effect on the Dynamic Response of Nonlinear Structures |
title_full_unstemmed |
Time-Frequency Energy Distribution of Ground Motion and Its Effect on the Dynamic Response of Nonlinear Structures |
title_sort |
time-frequency energy distribution of ground motion and its effect on the dynamic response of nonlinear structures |
publisher |
MDPI AG |
series |
Sustainability |
issn |
2071-1050 |
publishDate |
2019-01-01 |
description |
The ground motion characteristics are essential for understanding the structural seismic response. In this paper, the time-frequency analytical method is used to analyze the time-frequency energy distribution of ground motion, and its effect on the dynamic response of nonlinear structure is studied and discussed. The time-frequency energy distribution of ground motion is obtained by the matching pursuit decomposition algorithm, which not only effectively reflects the energy distribution of different frequency components in time, but also reflects the main frequency components existing near the peak ground acceleration occurrence time. A series of artificial ground motions with the same peak ground acceleration, Fourier amplitude spectrum, and duration are generated and chosen as the earthquake input of the structural response. By analyzing the response of the elasto-perfectly-plastic structure excited by artificial seismic waves, it can be found that the time-frequency energy distribution has a great influence on the structural ductility. Especially if there are even multiple frequency components in the same ground motion phrase, the plastic deformation of the elasto-perfectly-plastic structure will continuously accumulate in a certain direction, resulting in a large nonlinear displacement. This paper reveals that the time-frequency energy distribution of a strong ground motion has a vital influence on the structural response. |
topic |
ground motion matching pursuit decomposition time-frequency energy distribution ratcheting effect nonlinear response |
url |
https://www.mdpi.com/2071-1050/11/3/702 |
work_keys_str_mv |
AT dongwangtao timefrequencyenergydistributionofgroundmotionanditseffectonthedynamicresponseofnonlinearstructures AT jialilin timefrequencyenergydistributionofgroundmotionanditseffectonthedynamicresponseofnonlinearstructures AT zhenglu timefrequencyenergydistributionofgroundmotionanditseffectonthedynamicresponseofnonlinearstructures |
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1725457046151626752 |