基于鱼骨模型的地震作用下弹性结构物性参数反演

IF 2.2 Q2 CONSTRUCTION & BUILDING TECHNOLOGY Frontiers in Built Environment Pub Date : 2023-07-20 DOI:10.3389/fbuil.2023.1201048
K. Kajiwara, A. Kishida, J. Fujiwara, R. Enokida
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引用次数: 0

摘要

本文建立了一种基于鱼骨模型的反演方法,从地震作用下弹性建筑结构的响应中估计其物性参数。鱼骨模型除了具有集总质量模型中的元素外,还具有旋转弹簧和阻尼器,可以有效地演示在柱和梁的连接处发生的结构旋转。该模型通常用于结构地震反应的计算计算,并被归类为从已知系统和激励下获得响应的正演问题。虽然它对正问题的有效性已经得到很好的证明,但它很少被应用于逆问题,在逆问题中,结构性质是根据已知的响应和激励来估计的。首先,本研究反演了多/单质量系统鱼骨模型。然后,将反演结果应用于基于E-Defense振动台实验建立的3质量系统弹性鱼骨模型,对其结构响应进行数值模拟。数值模拟结果表明,该方法对三质量系统鱼骨模型参数的准确估计是有效的,特别是在结构响应不受噪声污染的情况下。最后,将该方法应用于含有噪声的响应,考察噪声对估计精度的影响。结果表明,阻尼单元的估计精度对噪声敏感,而刚度单元的估计精度比阻尼单元的估计精度不敏感。所提出的反演特别适用于估计集总质量系统的旋转刚度,这是集总质量系统的反演所不能得到的。
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Fishbone model-based inversion to estimate physical parameters of elastic structures under earthquake excitations
This study established an inversion based on a fishbone model to estimate physical parameters from the responses of elastic building structures subjected to an earthquake. A fishbone model, which has rotational springs and dashpots in addition to the elements in a lumped mass model, is effective for demonstrating structural rotations that happen at the connections of columns and beams. This model is commonly applied to computational calculations of seismic responses of structures and is classified into a forward problem obtaining responses from known systems and excitations. Although its effectiveness for the forward problem has been well demonstrated, it has rarely been applied to the inverse problem, where structural properties are estimated from known responses and excitations. First, this study inverted multi/single-mass-system fishbone models. Then, the inversion was applied to an elastic fishbone model of a 3-mass system, which was built based on an E-Defense shaking table experiment, and its structural responses were numerically simulated. This numerical simulation demonstrated its effectiveness for accurately estimating parameters in the fishbone model of the 3-mass system, especially when its structural responses are not contaminated by noises. Lastly, it was applied to responses containing some noise to examine its influence on the estimation accuracy. The estimation accuracy of damping elements was found to be sensitive to noise, whereas that of stiffness was more insensitive than the damping elements. The proposed inversion is particularly suitable for estimating rotational stiffness, which is not obtainable from the inversion of lumped mass systems.
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来源期刊
Frontiers in Built Environment
Frontiers in Built Environment Social Sciences-Urban Studies
CiteScore
4.80
自引率
6.70%
发文量
266
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