Efficient Modal Identification and Optimal Sensor Placement via Dynamic DIC Measurement and Feature-Based Data Compression

IF 1.9 Q3 ENGINEERING, MECHANICAL
Vibration Pub Date : 2023-10-06 DOI:10.3390/vibration6040050
Weizhuo Wang
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Abstract

Full-field non-contact vibration measurements provide a rich dataset for analysing structural dynamics. However, implementing the identification algorithm directly using high-spatial resolution data can be computationally expensive in modal identification. To address this challenge, performing identification in a shape-preserving but lower-dimensional feature space is more feasible. The full-field mode shapes can then be reconstructed from the identified feature mode shapes. This paper discusses two approaches, namely data-dependent and data-independent, for constructing the feature spaces. The applications of these approaches to modal identification on a curved plate are studied, and their performance is compared. In a case study involving a curved plate, it was found that a spatial data compression ratio as low as 1% could be achieved without compromising the integrity of the shape features essential for a full-field modal. Furthermore, the paper explores the optimal point-wise sensor placement using the feature space. It presents an alternative, data-driven method for optimal sensor placement that eliminates the need for a normal model, which is typically required in conventional approaches. Combining a small number of point-wise sensors with the constructed feature space can accurately reconstruct the full-field response. This approach demonstrates a two-step structural health monitoring (SHM) preparation process: offline full-field identification of the structure and the recommended point-wise sensor placement for online long-term monitoring.
基于动态DIC测量和特征数据压缩的有效模态识别和最优传感器配置
全场非接触振动测量为结构动力学分析提供了丰富的数据集。然而,在模态识别中,直接使用高空间分辨率数据实现识别算法计算代价高昂。为了解决这一挑战,在保持形状但较低维的特征空间中进行识别更为可行。然后可以从识别的特征模态振型重建全场模态振型。本文讨论了两种构造特征空间的方法,即数据依赖和数据独立。研究了这些方法在曲面板模态识别中的应用,并对它们的性能进行了比较。在一个涉及曲面板的案例研究中,研究人员发现,在不影响全场模态所必需的形状特征完整性的情况下,可以实现低至1%的空间数据压缩比。此外,本文还利用特征空间探索了逐点传感器的最佳位置。它提出了一种替代的、数据驱动的最佳传感器放置方法,消除了传统方法中通常需要的常规模型的需要。将少量的逐点传感器与所构建的特征空间相结合,可以准确地重建全场响应。该方法演示了两步结构健康监测(SHM)准备过程:离线全场结构识别和推荐的用于在线长期监测的点方向传感器放置。
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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CiteScore
3.20
自引率
0.00%
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0
审稿时长
10 weeks
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