Bridge condition monitoring using fixed moving principal component analysis

Nie, Zhenhua; Guo, Enguo; Li, Jun; Hao, Hong; Ma, Hongwei; Jiang, Hui

doi:10.1002/stc.2535

Cited by 32 publications

(35 citation statements)

References 43 publications

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“…Even though several health monitoring procedures have been defined through several experiences during decades for in‐service structures (mainly bridges), 1–3 a conceptual model is needed for durability health monitoring of structural concrete elements during fabrication and based on the methodology proposed in NMX‐530‐ONNCCE 4 and other investigations 5 . This procedure is used in this investigation to discuss the achievement of durability through the design and health monitoring during construction.…”

Section: Introductionmentioning

confidence: 99%

Durability control through design and health monitoring during construction

Torres-Acosta

Castro-Borges²

2020

Struct Control Health Monit

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Section: Introductionmentioning

confidence: 99%

Durability control through design and health monitoring during construction

Torres-Acosta

Castro-Borges²

2020

Struct Control Health Monit

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“…In general, PC analysis (PCA) has been used for damage detection and localization in two ways. In the first way, PCA has a main role in damage detection and localization, whereas it was used in the second way as an initial step for other algorithms 28–33 . The former way was utilized in the following researches.…”

Section: Introductionmentioning

confidence: 99%

Structural damage detection using principal component analysis of frequency response function data

Esfandiari

Nabiyan

Rofooei

2020

Struct Control Health Monit

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Summary In this paper, a new sensitivity‐based model updating method is presented based on the changes of principal components (PCs) of frequency response function (FRF). Structural damage estimation, identification of damage location and severity, is conducted by an innovative sensitivity relation. The sensitivity relation is derived by incorporating PC analysis (PCA) data obtained from the incomplete measured structural responses in a mathematical formulation and is then solved by the least square method. In order to demonstrate the performance of the proposed method, it is applied to a truss and a frame model. The results prove the ability of the method as a robust damage detection algorithm in the presence of measurement and mass modeling errors. The comparative studies prove that the results obtained by the proposed sensitivity relation are more accurate than the results based on using FRF data directly.

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“…PCA is widely used for conducting the data compression and extracting information from the high dimensional data. It is used in the field of SHM for performing the dimensionality reduction of the input dataset and for removing the uncertainties, for example, measurement noise and environmental effects 25 while retaining most of the information of the original data 26 . For the datasets measured for a long duration, the number of sampling points becomes significantly large, which increases the computational time for obtaining the covariance matrix and principal components.…”

Section: Introductionmentioning

confidence: 99%

“…These principal components are obtained by performing eigen‐decomposition of covariance matrix obtained from the centred matrix of the input datasets. The eigenvectors can be arranged in the descending order of the eigenvalues, and the number of components can be selected based on certain criteria on the singular values or energy of covariance 25,26 . Posenta et al 27 proposed using a moving window of a constant size, and the computation of covariance matrix was carried out inside the window.…”

Section: Introductionmentioning

confidence: 99%

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Development and application of random forest technique for element level structural damage quantification

Chencho

Hao

et al. 2020

Struct Control Health Monit

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Summary This paper presents element level structural damage quantification using an ensemble‐based machine learning technique, namely, random forest technique, with acceleration responses from structures. The ensemble‐based approach provides a better prediction than an individual model. Random forest is a machine learning algorithm which has several decision trees to perform a task. The proposed approach develops a random forest as a regressor to predict multiple output variables, which is the vector of elemental level damage quantification results of the structure. Damage severity is identified as the reduction in the elemental stiffness parameters. The acceleration responses for single‐element and multiple element damage cases are generated and further processed to feed as input to the random forest. The acceleration responses from the sensor nodes are concatenated, and principal component analysis (PCA) is applied to reduce the uncorrelated input dimension. The proposed approach can provide good damage identification results efficiently with much less computational demand and time, compared to the neural network training methods and deep learning models. Moreover, fewer sensors are needed to measure acceleration responses to localise damage and quantify the damage level. To demonstrate the proposed method, a simply supported beam is used as an example in numerical studies. Different levels of noise in the acceleration responses and uncertainty in the finite element modelling are considered. Experimental studies on a steel frame structure with 70 elements are also conducted to investigate the performance of the proposed approach for structural damage quantification. Good identification results are obtained with an efficient training process.

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Bridge condition monitoring using fixed moving principal component analysis

Cited by 32 publications

References 43 publications

Durability control through design and health monitoring during construction

Durability control through design and health monitoring during construction

Structural damage detection using principal component analysis of frequency response function data

Development and application of random forest technique for element level structural damage quantification

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