Synthetic Earthquake Ground Motions for the Design of Long Structures

Lifeline Earthquake Engineering Pub Date : 2013-12-27 DOI:10.1061/9780784413234.076

M. Todorovska, M. Trifunac, V. W. Lee

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引用次数: 1

Abstract

The SYNACC method for synthesizing earthquake ground motion time histories is reviewed, with emphasis on the recent extension to generating motions on an array of points in space. This method is a combination of empirical and physical model-based approach, and involves unfolding in time a site-specific Fourier amplitude spectrum of ground acceleration, obtained for a scenario earthquake by an empirical scaling model, or for an ensemble of earthquakes by probabilistic seismic hazard analysis. The unfolding consists of representing the ground motion as a superposition of traveling surface Love and Rayleigh waves and of body P and S waves, which propagate with phase and group velocities consistent with the dispersion characteristic of the site geology, approximated by parallel layers. The synthesized motions are site-specific and consistent statistically with observations within the recording range of typical accelerographs (0.02-25 Hz). The output consists of synthetic accelerations, velocities and displacements, and also of point strains, rotations and curvatures, at a point or at an array of points. Such time histories are useful for the design of spatially extended structures, like pipelines, bridges and tunnels.

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长结构设计的综合地震动

综述了用于合成地震地面运动时程的SYNACC方法，重点介绍了最近扩展到在空间点阵列上生成运动的方法。该方法结合了经验和基于物理模型的方法，并涉及及时展开特定地点的地面加速度傅立叶振幅谱，通过经验标度模型获得情景地震，或通过概率地震危害分析获得地震集合。展开包括将地面运动表示为行进的表面洛夫波和瑞利波以及体P波和S波的叠加，这些波以与场地地质的频散特征一致的相速度和群速度传播，用平行层近似。合成的运动具有站点特异性，在统计上与典型加速度计(0.02-25 Hz)记录范围内的观测结果一致。输出包括合成加速度，速度和位移，以及点应变，旋转和曲率，在一个点或在一个点阵列。这样的时间历史对空间扩展结构的设计很有用，比如管道、桥梁和隧道。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Lifeline Earthquake Engineering

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