Bayesian Spectral Decomposition for Efficient Modal Identification Using Ambient Vibration

IF 4.6 2区 工程技术 Q1 CONSTRUCTION & BUILDING TECHNOLOGY
Zhouquan Feng, Jiren Zhang, Lambros Katafygiotis, Xugang Hua, Zhengqing Chen
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Abstract

Modal parameter identification via ambient vibration is popular but faces challenges from uncertainties due to unknown inputs and low signal-to-noise ratio. Bayesian methods are gaining increasing attention for operational modal identification due to their ability to quantify uncertainties. However, improvements in computational efficiency are needed, particularly when addressing numerous modes and degrees of freedom. To address this challenge, this study proposes an innovative approach, termed the “Bayesian spectral decomposition” method (BSD), employing the decompose-and-conquer strategy. This novel method, operating within the frequency domain, identifies each mode individually by exploiting their inherent separated modal characteristics. For each mode, the response spectrum matrix undergoes an eigenvalue decomposition, yielding crucial eigenvalues (incorporating frequency and damping information) and eigenvectors (containing mode shape information). Subsequently, statistical properties of the eigenvalues and eigenvectors are utilized to establish likelihood functions for Bayesian parameter identification. By combining prior information, the posterior probability distribution functions of modal parameters are derived. The optimal solution is then obtained by resolving the maximum posterior probability distribution function problem. To further quantify the uncertainty of modal parameters, Gaussian distributions are employed to approximate the posterior probability distribution functions. The adoption of the decomposition approach circumvents the joint identification of all modal parameters, substantially reducing the parameter dimensions for optimization. Consequently, this strategy leads to decreased computational complexity and significantly improved computational stability. The effectiveness of the BSD is confirmed through simulated data generated from an 8-story shear building as well as measured data collected from both an experimental shear frame and the Canton Tower. The results demonstrate that the proposed method achieves high accuracy in identifying modal parameters, greatly improves computational efficiency, and effectively quantifies the uncertainties in modal parameters.

Abstract Image

利用环境振动进行贝叶斯频谱分解以实现高效模态识别
通过环境振动进行模态参数识别很受欢迎,但面临着未知输入和低信噪比带来的不确定性挑战。贝叶斯方法能够量化不确定性,因此在运行模态识别方面越来越受到关注。然而,需要提高计算效率,尤其是在处理众多模态和自由度时。为应对这一挑战,本研究提出了一种创新方法,称为 "贝叶斯频谱分解 "方法(BSD),采用分解-征服策略。这种新颖的方法在频域内运行,通过利用其固有的分离模态特征来单独识别每个模态。对于每种模态,响应谱矩阵都要经过特征值分解,产生关键的特征值(包含频率和阻尼信息)和特征向量(包含模态形状信息)。随后,利用特征值和特征向量的统计特性,建立贝叶斯参数识别的似然函数。通过结合先验信息,得出模态参数的后验概率分布函数。然后通过解决最大后验概率分布函数问题获得最优解。为了进一步量化模态参数的不确定性,采用了高斯分布来近似后验概率分布函数。分解方法的采用避免了所有模态参数的联合识别,大大减少了优化参数的维数。因此,这一策略降低了计算复杂度,并显著提高了计算稳定性。BSD 的有效性通过 8 层剪力墙建筑的模拟数据以及实验剪力框架和广州塔的测量数据得到了证实。结果表明,所提出的方法在模态参数识别方面实现了高精度,大大提高了计算效率,并有效量化了模态参数的不确定性。
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来源期刊
Structural Control & Health Monitoring
Structural Control & Health Monitoring 工程技术-工程:土木
CiteScore
9.50
自引率
13.00%
发文量
234
审稿时长
8 months
期刊介绍: The Journal Structural Control and Health Monitoring encompasses all theoretical and technological aspects of structural control, structural health monitoring theory and smart materials and structures. The journal focuses on aerospace, civil, infrastructure and mechanical engineering applications. Original contributions based on analytical, computational and experimental methods are solicited in three main areas: monitoring, control, and smart materials and structures, covering subjects such as system identification, health monitoring, health diagnostics, multi-functional materials, signal processing, sensor technology, passive, active and semi active control schemes and implementations, shape memory alloys, piezoelectrics and mechatronics. Also of interest are actuator design, dynamic systems, dynamic stability, artificial intelligence tools, data acquisition, wireless communications, measurements, MEMS/NEMS sensors for local damage detection, optical fibre sensors for health monitoring, remote control of monitoring systems, sensor-logger combinations for mobile applications, corrosion sensors, scour indicators and experimental techniques.
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