Gradient-Based Optimization Method for Experimental Modal Parameter Estimation with Finite Element Model

IF 2.1 3区工程技术 Q2 ENGINEERING, AEROSPACE

AIAA Journal Pub Date : 2024-06-08 DOI:10.2514/1.j063967

Zhaoyi Xu, Gangtie Zheng

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Abstract

This paper presents a novel gradient-based optimization algorithm for improving the accuracy of experimentally estimated modal parameters with the assistance of finite element models. Initially, we recast the discrete vibration response equation into a matrix form and formulate the parameter estimation problem in modal analysis as an optimization problem. Then the problem is solved with a gradient-based iterative algorithm, which explicitly exhibits the closed form of gradients used in optimization. Initial values for this iteration are parameters derived from finite element models, since every important engineering structure should be analyzed with a finite element model before it is constructed. Subsequently, the performance of this algorithm is validated by both pure numerical experiments, which simulate the physical world, and experiments using real measurement data gathered by sensors in the real physical world. The algorithm’s performance is further enhanced by incorporating gradient clipping and an adaptive iteration threshold. As a comparison, a discussion on classical least-squares time-domain method for the problem is provided. For practical applications, the Shi–Tomasi corner detection and Lucas–Kanade optical flow methods are deployed to detect corner points from videos taken during the vibration of a structure and track the motion of these points in the videos.

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利用有限元模型进行实验模态参数估计的梯度优化方法

本文提出了一种新颖的基于梯度的优化算法，用于在有限元模型的帮助下提高实验估算模态参数的精度。首先，我们将离散振动响应方程转换为矩阵形式，并将模态分析中的参数估计问题表述为优化问题。然后使用基于梯度的迭代算法来解决这个问题，该算法明确显示了优化中使用的梯度闭合形式。该迭代算法的初始值是由有限元模型导出的参数，因为每一个重要的工程结构在建造之前都应使用有限元模型进行分析。随后，该算法的性能通过模拟物理世界的纯数值实验和使用真实物理世界中传感器收集的真实测量数据进行的实验进行了验证。通过加入梯度剪切和自适应迭代阈值，该算法的性能得到了进一步提升。作为比较，还讨论了该问题的经典最小二乘时域方法。在实际应用中，Shi-Tomasi 角检测和 Lucas-Kanade 光流方法被用来检测结构振动时视频中的角点，并跟踪视频中这些点的运动。

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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来源期刊

AIAA Journal 工程技术-工程：宇航

CiteScore

5.60

自引率

12.00%

发文量

458

审稿时长

4.6 months

期刊介绍： This Journal is devoted to the advancement of the science and technology of astronautics and aeronautics through the dissemination of original archival research papers disclosing new theoretical developments and/or experimental results. The topics include aeroacoustics, aerodynamics, combustion, fundamentals of propulsion, fluid mechanics and reacting flows, fundamental aspects of the aerospace environment, hydrodynamics, lasers and associated phenomena, plasmas, research instrumentation and facilities, structural mechanics and materials, optimization, and thermomechanics and thermochemistry. Papers also are sought which review in an intensive manner the results of recent research developments on any of the topics listed above.