Response to discussion of “Seismic damage analysis due to near-fault multipulse ground motion”

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

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  • Wuhan University
  • Xi'an University of Architecture and Technology
  • Hong Kong Polytechnic University
  • The University of Liverpool
  • Tongji University
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Details

OriginalspracheEnglisch
Seiten (von - bis)861-866
Seitenumfang6
FachzeitschriftEarthquake Engineering and Structural Dynamics
Jahrgang53
Ausgabenummer2
PublikationsstatusVeröffentlicht - 9 Jan. 2024

Abstract

The authors thank the discusser for the attention and interests on our previous work, entitled “Seismic damage analysis due to near-fault multipulse ground motion” (referred to as the original paper/work in the following text). To demonstrate the increased seismic demands required by multipulse ground motions compared to non- and single-pulse ground motions, three cases were illustrated in the original work, including frame structures, a soil slope and a concrete dam. The discusser, Dr M.Amin Hariri-Ardebili, raised concerns on the seismic response of the dam, together with the optimal intensity measure of ground motions. Specifically, four subissues are involved, including effectiveness of the numerical model of dam, the damage index for dam, the selection strategy for input ground motions, and the ground motion intensity measures. Detailed responses to these issues are provided. In short, the main conclusion in the original paper that the multipulse ground motions potentially cause more severe damage compared to non- and single-pulse ground motions is reliable.

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Response to discussion of “Seismic damage analysis due to near-fault multipulse ground motion”. / Chen, Guan; Yang, Jiashu; Wang, Ruohan et al.
in: Earthquake Engineering and Structural Dynamics, Jahrgang 53, Nr. 2, 09.01.2024, S. 861-866.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Chen, Guan ; Yang, Jiashu ; Wang, Ruohan et al. / Response to discussion of “Seismic damage analysis due to near-fault multipulse ground motion”. in: Earthquake Engineering and Structural Dynamics. 2024 ; Jahrgang 53, Nr. 2. S. 861-866.
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title = "Response to discussion of “Seismic damage analysis due to near-fault multipulse ground motion”",
abstract = "The authors thank the discusser for the attention and interests on our previous work, entitled “Seismic damage analysis due to near-fault multipulse ground motion” (referred to as the original paper/work in the following text). To demonstrate the increased seismic demands required by multipulse ground motions compared to non- and single-pulse ground motions, three cases were illustrated in the original work, including frame structures, a soil slope and a concrete dam. The discusser, Dr M.Amin Hariri-Ardebili, raised concerns on the seismic response of the dam, together with the optimal intensity measure of ground motions. Specifically, four subissues are involved, including effectiveness of the numerical model of dam, the damage index for dam, the selection strategy for input ground motions, and the ground motion intensity measures. Detailed responses to these issues are provided. In short, the main conclusion in the original paper that the multipulse ground motions potentially cause more severe damage compared to non- and single-pulse ground motions is reliable.",
keywords = "multipulse ground motion, near-fault earthquake, pulse-like ground motion, response spectrum, seismic damage analysis, seismic risk",
author = "Guan Chen and Jiashu Yang and Ruohan Wang and Kaiqi Li and Yong Liu and Michael Beer",
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T1 - Response to discussion of “Seismic damage analysis due to near-fault multipulse ground motion”

AU - Chen, Guan

AU - Yang, Jiashu

AU - Wang, Ruohan

AU - Li, Kaiqi

AU - Liu, Yong

AU - Beer, Michael

N1 - Funding Information: The authors have nothing to report.

PY - 2024/1/9

Y1 - 2024/1/9

N2 - The authors thank the discusser for the attention and interests on our previous work, entitled “Seismic damage analysis due to near-fault multipulse ground motion” (referred to as the original paper/work in the following text). To demonstrate the increased seismic demands required by multipulse ground motions compared to non- and single-pulse ground motions, three cases were illustrated in the original work, including frame structures, a soil slope and a concrete dam. The discusser, Dr M.Amin Hariri-Ardebili, raised concerns on the seismic response of the dam, together with the optimal intensity measure of ground motions. Specifically, four subissues are involved, including effectiveness of the numerical model of dam, the damage index for dam, the selection strategy for input ground motions, and the ground motion intensity measures. Detailed responses to these issues are provided. In short, the main conclusion in the original paper that the multipulse ground motions potentially cause more severe damage compared to non- and single-pulse ground motions is reliable.

AB - The authors thank the discusser for the attention and interests on our previous work, entitled “Seismic damage analysis due to near-fault multipulse ground motion” (referred to as the original paper/work in the following text). To demonstrate the increased seismic demands required by multipulse ground motions compared to non- and single-pulse ground motions, three cases were illustrated in the original work, including frame structures, a soil slope and a concrete dam. The discusser, Dr M.Amin Hariri-Ardebili, raised concerns on the seismic response of the dam, together with the optimal intensity measure of ground motions. Specifically, four subissues are involved, including effectiveness of the numerical model of dam, the damage index for dam, the selection strategy for input ground motions, and the ground motion intensity measures. Detailed responses to these issues are provided. In short, the main conclusion in the original paper that the multipulse ground motions potentially cause more severe damage compared to non- and single-pulse ground motions is reliable.

KW - multipulse ground motion

KW - near-fault earthquake

KW - pulse-like ground motion

KW - response spectrum

KW - seismic damage analysis

KW - seismic risk

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VL - 53

SP - 861

EP - 866

JO - Earthquake Engineering and Structural Dynamics

JF - Earthquake Engineering and Structural Dynamics

SN - 0098-8847

IS - 2

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