An Improved Objective Function for Modal-Based Damage Identification Using Substructural Virtual Distortion Method

Hou, Jilin; Wang, Sijie; Zhang, Qingxia; Jankowski, Łukasz

doi:10.3390/app9050971

Cited by 6 publications

(3 citation statements)

References 39 publications

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“…First, the first three natural frequencies and mode shapes ( Figure 29) are identified from the responses. The damages are optimized using the objective function considered in [47] and shown in Equation (20), where φ is the number of the structural mode shapes and ω is the number of the natural frequencies, while and are the respective weighting coefficients:…”

Section: Direct Identification Of Damage Using Structural Modal Parammentioning

confidence: 99%

Bridge Damage Identification Using Vehicle Bump Based on Additional Virtual Masses

Zhang

Hou

Jankowski

2020

Sensors

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Structural damage identification plays an important role in providing effective evidence for the health monitoring of bridges in service. Due to the limitations of measurement points and lack of valid structural response data, the accurate identification of structural damage, especially for large-scale structures, remains difficult. Based on additional virtual mass, this paper presents a damage identification method for bridges using a vehicle bump as the excitation. First, general equations of virtual modifications, including virtual mass, stiffness, and damping, are derived. A theoretical method for damage identification, which is based on additional virtual mass, is formulated. The vehicle bump is analyzed, and the bump-induced excitation is estimated via a detailed analysis in four periods: separation, free-fall, contact, and coupled vibrations. The precise estimation of bump-induced excitation is then applied to a bridge. This allows the additional virtual mass method to be used, which requires knowledge of the excitations and acceleration responses in order to construct the frequency responses of a virtual structure with an additional virtual mass. Via this method, a virtual mass with substantially more weight than a typical vehicle is added to the bridge, which provides a sufficient amount of modal information for accurate damage identification while avoiding the bridge overloading problem. A numerical example of a two-span continuous beam is used to verify the proposed method, where the damage can be identified even with 15% Gaussian random noise pollution using a 1-degree of freedom (DOF) car model and 4-DOF model.

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Section: Direct Identification Of Damage Using Structural Modal Parammentioning

confidence: 99%

Bridge Damage Identification Using Vehicle Bump Based on Additional Virtual Masses

Zhang

Hou

Jankowski

2020

Sensors

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“…With the rapid development of modern science and technology, there has been an increasing number of large and complex engineering structures [1,2]. When these structures become damaged, the consequences are catastrophic, leading to a significant loss of human lives and property [3,4]. Therefore, it is necessary to adopt effective health-monitoring methods for such structures [5], and damage identification is a crucial aspect of structural health monitoring (SHM) [6,7].…”

Section: Introductionmentioning

confidence: 99%

Damage Identification Method Using Additional Virtual Mass Based on Damage Sparsity

Zhang

Hou

et al. 2021

Applied Sciences

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Damage identification methods based on structural modal parameters are influenced by the structure form, number of measuring sensors and noise, resulting in insufficient modal data and low damage identification accuracy. The additional virtual mass method introduced in this study is based on the virtual deformation method for deriving the frequency-domain response equation of the virtual structure and identify its mode to expand the modal information of the original structure. Based on the initial condition assumption that the structural damage was sparse, the damage identification method based on sparsity with l1 and l2 norm of the damage-factor variation and the orthogonal matching pursuit (OMP) method based on the l0 norm were introduced. According to the characteristics of the additional virtual mass method, an improved OMP method (IOMP) was developed to improve the localization of optimal solution determined using the OMP method and the damage substructure selection process, analyze the damage in the entire structure globally, and improve damage identification accuracy. The accuracy and robustness of each damage identification method for multi-damage scenario were analyzed and verified through simulation and experiment.

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“…[36][37][38][39][40][41]. A large number of investigators focus on damage detection [42][43][44][45][46], in which sensing technologies are used to characterize (e.g., location, size, depth, etc.) damage at a shorter time frame than typical monitoring techniques.…”

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confidence: 99%

Structural Damage Detection and Health Monitoring

Song

Kong

2019

Applied Sciences

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An Improved Objective Function for Modal-Based Damage Identification Using Substructural Virtual Distortion Method

Cited by 6 publications

References 39 publications

Bridge Damage Identification Using Vehicle Bump Based on Additional Virtual Masses

Bridge Damage Identification Using Vehicle Bump Based on Additional Virtual Masses

Damage Identification Method Using Additional Virtual Mass Based on Damage Sparsity

Structural Damage Detection and Health Monitoring

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