Dimensional response analysis of bilinear systems subjected to non-pulse-like earthquake ground motions
Dimensional response analysis of bilinear systems subjected to non-pulse-like earthquake ground motions
The maximum inelastic response of bilinear single-degree-of-freedom (SDOF) systems when subjected to ground motions without distinguishable pulses is revisited with dimensional analysis by identifying timescales and length scales in the time histories of recorded ground motions. The characteristic length scale is used to normalize the peak inelastic displacement of the bilinear system. The paper adopts the mean period of the Fourier transform of the ground motion as an appropriate timescale and examines two different length scales that result from the peak ground acceleration and the peak ground velocity. When the normalized peak inelastic displacement is presented as a function of the normalized strength and normalized yield displacement, the response becomes self-similar, and a clear pattern emerges. Accordingly, the paper proposes two alternative predictive master curves for the response that solely involve the strength and yield displacement of the bilinear SDOF system in association with either the peak ground acceleration or the peak ground velocity, together with the mean period of the Fourier transform of the ground motion. The regression coefficients that control the shape of the predictive master curves are based on 484 ground motions recorded at rock and stiff soil sites and are applicable to bilinear SDOF systems with a postyield stiffness ratio equal to 2% and an inherent viscous damping ratio equal to 5%.
600-606
Karavasilis, T.L.
15850eb0-6af4-4b6e-bab4-d5bde281b769
Seo, C-Y.
1fb058b5-ec02-4bf7-bb71-4d0bf03fe84c
Makris, N.
2b453e8e-926a-47bc-b7d3-1130fc93e332
May 2011
Karavasilis, T.L.
15850eb0-6af4-4b6e-bab4-d5bde281b769
Seo, C-Y.
1fb058b5-ec02-4bf7-bb71-4d0bf03fe84c
Makris, N.
2b453e8e-926a-47bc-b7d3-1130fc93e332
Karavasilis, T.L., Seo, C-Y. and Makris, N.
(2011)
Dimensional response analysis of bilinear systems subjected to non-pulse-like earthquake ground motions.
Journal of Structural Engineering, 137 (5), .
(doi:10.1061/(ASCE)ST.1943-541X.0000305).
Abstract
The maximum inelastic response of bilinear single-degree-of-freedom (SDOF) systems when subjected to ground motions without distinguishable pulses is revisited with dimensional analysis by identifying timescales and length scales in the time histories of recorded ground motions. The characteristic length scale is used to normalize the peak inelastic displacement of the bilinear system. The paper adopts the mean period of the Fourier transform of the ground motion as an appropriate timescale and examines two different length scales that result from the peak ground acceleration and the peak ground velocity. When the normalized peak inelastic displacement is presented as a function of the normalized strength and normalized yield displacement, the response becomes self-similar, and a clear pattern emerges. Accordingly, the paper proposes two alternative predictive master curves for the response that solely involve the strength and yield displacement of the bilinear SDOF system in association with either the peak ground acceleration or the peak ground velocity, together with the mean period of the Fourier transform of the ground motion. The regression coefficients that control the shape of the predictive master curves are based on 484 ground motions recorded at rock and stiff soil sites and are applicable to bilinear SDOF systems with a postyield stiffness ratio equal to 2% and an inherent viscous damping ratio equal to 5%.
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Accepted/In Press date: 20 August 2010
e-pub ahead of print date: 25 August 2010
Published date: May 2011
Organisations:
Infrastructure Group
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Local EPrints ID: 401620
URI: http://eprints.soton.ac.uk/id/eprint/401620
ISSN: 0733-9445
PURE UUID: 8e4b36da-2447-46cc-b277-8282d7ff84b3
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Date deposited: 20 Oct 2016 15:36
Last modified: 15 Mar 2024 02:51
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Author:
T.L. Karavasilis
Author:
C-Y. Seo
Author:
N. Makris
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