基于迭代重加权 L1/2 正则化和三种优化函数的结构损伤识别方法对比分析

IF 3 3区 工程技术 Q2 ENGINEERING, CIVIL
Wanli Yan, Yong Liu, Xinfeng Yin, Yang Liu, Yingfei Dong
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引用次数: 0

摘要

以往基于振动的损伤检测研究大多侧重于开发更灵敏的优化函数,以提高损伤识别的有效性。然而,只有少数研究对不同优化函数的检测性能进行了比较分析。在本研究中,频率和模态振型的变化被用作不同优化函数的输入,用于损伤识别。分别使用频率残差、频率和模态振型组合残差以及模态柔性残差建立了三个优化函数。考虑到损伤元素分布的稀疏性,在优化函数中加入了迭代加权 l1/2(IRl1/2)正则化作为规范惩罚。应用数值模型和实验实例评估了不同优化函数的性能。结果表明,当模态数据的数量满足识别损伤的基本要求时,模态数据数量的增加并不能显著提高检测精度。使用前四阶和十四阶噪声模态数据,结合频率和模态振型残差建立的优化函数的检测误差分别为 6.65% 和 5.18%。此外,与其他两个函数相比,利用模态弹性残差构建的优化函数需要更少的模态数据来识别损坏。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Comparative Analysis of Structural Damage Identification Methods Based on Iterative Reweighted L1/2 Regularization and Three Optimization Functions

Previous vibration-based damage detection studies mostly focus on developing a more sensitive optimization function to promote the effectiveness of damage identification. However, a few studies have conducted comparative analyses on the detection performance of different optimization functions. In the study, changes in the frequency and mode shape are applied as the inputs to different optimization functions for damage identification. Three optimization functions are established using the frequency residuals, the combinations of frequency and mode shape residuals, and the modal flexibility residuals, respectively. Considering the sparsity of damage element distribution, an iterative reweighted l1/2(IRl1/2) regularization is added as a norm penalty to the optimization function. A numerical model and an experimental example are applied to assess the performance of distinct optimization functions. The results show that the increase in modal data number cannot significantly improve the detection accuracy when the number meets the basic requirements for identifying damage. The detection error of the optimization function established by combining the frequency and mode shape residuals is 6.65% and 5.18% using the first four and fourteen-order noisy modal data, respectively. Furthermore, the optimization function constructed using the modal flexibility residuals requires more less modal data to identify damage than the other two functions.

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来源期刊
CiteScore
5.30
自引率
38.90%
发文量
291
审稿时长
4 months
期刊介绍: The aim of this journal is to provide a unique forum for the publication and rapid dissemination of original research on stability and dynamics of structures. Papers that deal with conventional land-based structures, aerospace structures, marine structures, as well as biostructures and micro- and nano-structures are considered. Papers devoted to all aspects of structural stability and dynamics (both transient and vibration response), ranging from mathematical formulations, novel methods of solutions, to experimental investigations and practical applications in civil, mechanical, aerospace, marine, bio- and nano-engineering will be published. The important subjects of structural stability and structural dynamics are placed together in this journal because they share somewhat fundamental elements. In recognition of the considerable research interests and recent proliferation of papers in these subjects, it is hoped that the journal may help bring together papers focused on related subjects, including the state-of-the-art surveys, so as to provide a more effective medium for disseminating the latest developments to researchers and engineers. This journal features a section for technical notes that allows researchers to publish their initial findings or new ideas more speedily. Discussions of papers and concepts will also be published so that researchers can have a vibrant and timely communication with others.
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