On group-theoretic computation of natural frequencies for spring–mass dynamic systems with rectilinear motion

Communications in Numerical Methods in Engineering Pub Date : 2007-04-20 DOI:10.1002/CNM.1003

A. Zingoni

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引用次数: 33

Abstract

In this article, group theory is employed to simplify the computation of natural circular frequencies for spring–mass dynamic systems with rectilinear motion. The systems are by themselves not physically symmetric (or they exhibit only very weak symmetry properties), but they can be transformed into graphs that preserve all the connectivities between masses and springs, while featuring the maximum possible symmetry. For physical dynamic systems exhibiting symmetry, a well-known group-theoretic approach involves the computation of the full stiffness matrix of the system first, followed by transformation of this matrix in order to cast it into block-diagonal form. The present approach involves the direct assembly of much smaller stiffness matrices within the decomposed subspaces of the problem, and is therefore computationally more efficient. Of particular focus in this study are transformed configurations belonging to ‘triangular’ symmetry groups, whose symmetries are difficult to exploit using conventional methods. It is shown how the repeating eigenvalues associated with the degenerate subspaces of such symmetry groups can easily be obtained. Copyright © 2007 John Wiley & Sons, Ltd.

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直线运动弹簧-质量动力系统固有频率的群理论计算

本文利用群理论简化了直线运动的弹簧-质量动力系统的固有圆频率的计算。这些系统本身不是物理对称的(或者它们只表现出非常弱的对称性)，但它们可以转换成保留质量和弹簧之间所有连通性的图，同时具有最大可能的对称性。对于具有对称性的物理动力系统，众所周知的群论方法包括首先计算系统的全刚度矩阵，然后对该矩阵进行变换，以将其转换为块对角线形式。目前的方法涉及在问题的分解子空间内直接组装更小的刚度矩阵，因此计算效率更高。本研究特别关注的是属于“三角形”对称群的变换构型，其对称性很难用传统方法来利用。证明了如何容易地得到与这类对称群的简并子空间相关的重复特征值。版权所有©2007 John Wiley & Sons, Ltd

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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Communications in Numerical Methods in Engineering

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