针对非线性动力学和准脆性材料的 LATIN-PGD 方法在未来地震工程中的应用

arXiv - CS - Computational Engineering, Finance, and Science Pub Date : 2024-08-09 DOI:arxiv-2408.05108

Sebastian Rodriguez, Pierre-Etienne Charbonnel, Pierre Ladevèze, David Néron

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摘要

本文首次提出了LArge Time INcrement (LATIN)方法与称为ProperGeneralized Decomposition (PGD)的模型缩减技术，用于求解准脆性各向同性损伤构成参数时的非线性低频动力学问题。本文使用时间-非连续伽勒金方法（TDGM）计算 LATIN-PGD 方法的时空分离无变量求解的时间贡献。以三维弯曲梁为例，测试了该方法的效率，并给出了将 LATIN-PGD 与经典的时间递增纽马克/准牛顿非线性求解器进行比较的结果和基准。这项工作是考虑不确定性和开展地震风险评估所要求的更复杂参数研究的第一步。

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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The LATIN-PGD methodology to nonlinear dynamics and quasi-brittle materials for future earthquake engineering applications

This paper presents a first implementation of the LArge Time INcrement (LATIN) method along with the model reduction technique called Proper Generalized Decomposition (PGD) for solving nonlinear low-frequency dynamics problems when dealing with a quasi-brittle isotropic damage constitutive relations. The present paper uses the Time-Discontinuous Galerkin Method (TDGM) for computing the temporal contributions of the space-time separate-variables solution of the LATIN-PGD approach, which offers several advantages when considering a high number of DOFs in time. The efficiency of the method is tested for the case of a 3D bending beam, where results and benchmarks comparing LATIN-PGD to classical time-incremental Newmark/Quasi-Newton nonlinear solver are presented. This work represents a first step towards taking into account uncertainties and carrying out more complex parametric studies imposed by seismic risk assessment.

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arXiv - CS - Computational Engineering, Finance, and Science

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