Multi-level deformation behavior monitoring of flexural structures via vision-based continuous boundary tracking: proof-of-concept study

•This study proposes the concept of measuring multi-level deformation behavior of flexural structures via the extraction of continuous structural boundaries from a computer vision technique.•This study explores the feasibility of using a salient object detection method to measure the curvature profi...

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Published in:Measurement : journal of the International Measurement Confederation 2022-05, Vol.194, p.111031, Article 111031
Main Authors: Shan, Jiazeng, Liu, Yuwen, Cui, Xiaoxuan, Wu, Hao, Loong, Cheng Ning, Wei, Zhihua
Format: Article
Language:English
Subjects:
Artificial neural networks
Bending curvature
Circular plates
Computer vision
Curvature
Deep neural network
Deformation
Feasibility
Impact loads
Measurement
Neural networks
Reinforced concrete
Rigid-body dynamics
Salient object detection
Structural health monitoring
Vibration
Vibration measurement
Vision-based measurement
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cited_by cdi_FETCH-LOGICAL-c349t-204d7f02c40842328f1f3f57c8564b5ca49ec5a799030f7fba785c249b7a4c753
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container_title Measurement : journal of the International Measurement Confederation
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creator Shan, Jiazeng
Liu, Yuwen
Cui, Xiaoxuan
Wu, Hao
Loong, Cheng Ning
Wei, Zhihua
description •This study proposes the concept of measuring multi-level deformation behavior of flexural structures via the extraction of continuous structural boundaries from a computer vision technique.•This study explores the feasibility of using a salient object detection method to measure the curvature profile of a structure from the image frames of a video captured from a digital camera.•This study presents a pre-trained deep neural network that can accurately segment a salient object in an image for curvature measurement.•A novel approach for determining the curvature of a structure based on the geometrical information at its boundary is proposed.•The proposed technique is validated via two experiments and shown to be accurate for measuring the displacement and curvature profile of a structure. The concept of measuring the multi-level deformation behavior of flexural structures via the extraction of continuous structural boundaries using a computer vision technique is proposed. The feasibility of using a salient-object-detection method to estimate the deformation and curvature profile of target structures from the image frames of a video recording structural vibrations is investigated. A framework is proposed for performing this salient-object-detection-based vibration measurement technique via the aid of a pre-trained deep neural network. A method for determining the curvature estimated from the boundary extracted from the deep neural network is then introduced. The accuracy of the proposed technique is validated via two experiments. The first experiment measures the curvature of a semi-circular plate under rigid body motions. The second experiment tracks the deformation of reinforced concrete beams under impact loads. Both experiments verify that the proposed method is feasible for accurately measuring the vibration profile of the target structure.
doi_str_mv 10.1016/j.measurement.2022.111031
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The concept of measuring the multi-level deformation behavior of flexural structures via the extraction of continuous structural boundaries using a computer vision technique is proposed. The feasibility of using a salient-object-detection method to estimate the deformation and curvature profile of target structures from the image frames of a video recording structural vibrations is investigated. A framework is proposed for performing this salient-object-detection-based vibration measurement technique via the aid of a pre-trained deep neural network. A method for determining the curvature estimated from the boundary extracted from the deep neural network is then introduced. The accuracy of the proposed technique is validated via two experiments. The first experiment measures the curvature of a semi-circular plate under rigid body motions. The second experiment tracks the deformation of reinforced concrete beams under impact loads. 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The concept of measuring the multi-level deformation behavior of flexural structures via the extraction of continuous structural boundaries using a computer vision technique is proposed. The feasibility of using a salient-object-detection method to estimate the deformation and curvature profile of target structures from the image frames of a video recording structural vibrations is investigated. A framework is proposed for performing this salient-object-detection-based vibration measurement technique via the aid of a pre-trained deep neural network. A method for determining the curvature estimated from the boundary extracted from the deep neural network is then introduced. The accuracy of the proposed technique is validated via two experiments. The first experiment measures the curvature of a semi-circular plate under rigid body motions. The second experiment tracks the deformation of reinforced concrete beams under impact loads. 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The concept of measuring the multi-level deformation behavior of flexural structures via the extraction of continuous structural boundaries using a computer vision technique is proposed. The feasibility of using a salient-object-detection method to estimate the deformation and curvature profile of target structures from the image frames of a video recording structural vibrations is investigated. A framework is proposed for performing this salient-object-detection-based vibration measurement technique via the aid of a pre-trained deep neural network. A method for determining the curvature estimated from the boundary extracted from the deep neural network is then introduced. The accuracy of the proposed technique is validated via two experiments. The first experiment measures the curvature of a semi-circular plate under rigid body motions. The second experiment tracks the deformation of reinforced concrete beams under impact loads. 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subjects Artificial neural networks
Bending curvature
Circular plates
Computer vision
Curvature
Deep neural network
Deformation
Feasibility
Impact loads
Measurement
Neural networks
Reinforced concrete
Rigid-body dynamics
Salient object detection
Structural health monitoring
Vibration
Vibration measurement
Vision-based measurement
title Multi-level deformation behavior monitoring of flexural structures via vision-based continuous boundary tracking: proof-of-concept study
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