| 一种用于层状结构模型的先进计算方法 |
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| 引用本文: | 潘爾年,周江存,林志平,张智卿.一种用于层状结构模型的先进计算方法[J].计算力学学报,2024,41(1):167-177. |
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| 作者姓名: | 潘爾年 周江存 林志平 张智卿 |
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| 作者单位: | 阳明交通大学 土木工程系 防灾与水环境研究中心, 新竹 300;中国科学院精密测量科学与技术创新研究院, 武汉 430077;温州理工学院 建筑与能源工程学院, 温州 325035 |
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| 基金项目: | 台湾科学与技术委员会资助项目(NSTC111-2811-E-A49-534);湖北珞珈实验室开放基金(220100033);台湾科学与技术委员会资助项目(MOST110-2625-M-A49-004);国家自然科学基金(52178367)资助项目. |
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| 摘 要: | 提出一种针对层状结构模型的先进计算方法。研究的层状结构通常为水平层状板或者层状半空间,结构由横观各向同性(TI)材料组成,材料对称轴指向分层方向。本文方法可以考虑材料的多场耦合特性,即热弹性、多孔弹性和磁电弹性耦合。基于最近提出的傅立叶-贝塞尔级数(FBS)向量函数系和双变量/位置(DVP)方法,建立了本文的先进计算方法。DVP能够无条件稳定地将层矩阵从一层传播到下一层。FBS向量函数系具有以下特点,(1)反映了具有明确类型的广义变形/波,(2)将展开系数预先计算为Love数,然后将其用于涉及问题的模拟。层状地球中的断层(或位错)作用、土-结构相互作用以及近地表地球剖面中的瞬态波等三个典型算例,证明了提出方法的准确性和有效性。
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| 关 键 词: | 分层介质 横向各向同性 傅立叶-贝赛尔级数系统 双变量位置法 多场耦合 勒夫数 |
| 收稿时间: | 2023/9/9 0:00:00 |
| 修稿时间: | 2023/10/30 0:00:00 |
An advanced computational approach for layered structure modeling |
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| PAN Er-nian,ZHOU Jiang-cun,LIN Chih-ping,ZHANG Zhi-qing.An advanced computational approach for layered structure modeling[J].Chinese Journal of Computational Mechanics,2024,41(1):167-177. |
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| Authors: | PAN Er-nian ZHOU Jiang-cun LIN Chih-ping ZHANG Zhi-qing |
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| Institution: | Civil Engineering and Disaster Prevention & Water Environment Research Center, Yang Ming Chiao Tung University, Hsinchu 300, China;State Key Laboratory of Geodesy and Earth''s Dynamics, Innovation Academy for Precision Measurement Science and Technology, Chinese Academy of Sciences, Wuhan 430077, China; College of Architecture and Energy Engineering, Wenzhou University of Technology, Zhejiang 325035, China |
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| Abstract: | In this paper, we present an advanced computational approach for modeling layered structures.The structures can be horizontally layered plates or layered half-spaces.The materials can be multi-field coupled, i.e., thermoelastic, poroelastic, and magnetoelectroelastic coupled, but require that they are transversely isotropic (TI) with material symmetry axis along the layering direction.This advanced approach is based on the recently constructed Fourier-Bessel series (FBS) system of vector functions and the dual-variable and position (DVP) method.While the DVP is for propagating the layer matrix from one layer to the next with unconditional stability, the FBS vector system is to 1) represent the general deformations/waves with distinguished deformation/wave types, and 2) pre-calculate the expansion coefficients as Love numbers and then use them later for massive simulation of the involved problem.Three typical examples are presented to demonstrate the accuracy and efficiency, as compared with the existing approaches.These are:faulting (or dislocation) in a layered earth, soil-structure interaction, and transient wave propagation in a near-surface earth profile. |
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| Keywords: | layered media transverse isotropy Fourier-Bessel series system dual-variable and position method multi-field coupling Love number |
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