Your search keyword '"thermographic data analysis"' showing total 12 results

1. Data-Augmented Manifold Learning Thermography for Defect Detection and Evaluation of Polymer Composites.

Author

Liu, Kaixin, Wang, Fumin, He, Yuxiang, Liu, Yi, Yang, Jianguo, and Yao, Yuan

Subjects

*CARBON fiber-reinforced plastics, *PARTIAL least squares regression, *GENERATIVE adversarial networks, *THERMOGRAPHY

Abstract

Infrared thermography techniques with thermographic data analysis have been widely applied to non-destructive tests and evaluations of subsurface defects in practical composite materials. However, the performance of these methods is still restricted by limited informative images and difficulties in feature extraction caused by inhomogeneous backgrounds and noise. In this work, a novel generative manifold learning thermography (GMLT) is proposed for defect detection and the evaluation of composites. Specifically, the spectral normalized generative adversarial networks serve as an image augmentation strategy to learn the thermal image distribution, thereby generating virtual images to enrich the dataset. Subsequently, the manifold learning method is employed for the unsupervised dimensionality reduction in all images. Finally, the partial least squares regression is presented to extract the explicit mapping of manifold learning for defect visualization. Moreover, probability density maps and quantitative metrics are proposed to evaluate and explain the obtained defect detection performance. Experimental results on carbon fiber-reinforced polymers demonstrate the superiorities of GMLT, compared with other methods. [ABSTRACT FROM AUTHOR]

Published

2023

2. Thermographic Data Analysis for Defect Detection by Imposing Spatial Connectivity and Sparsity Constraints in Principal Component Thermography.

Author

Wen, Ching-Mei, Sfarra, Stefano, Gargiulo, Gianfranco, and Yao, Yuan

Abstract

Data analysis methods have been extensively used in active thermography for defect identification. Among them, principal component thermography (PCT) is popular for dimensionality reduction and feature extraction. PCT summarizes the thermal images with a small number of empirical orthogonal functions that better reflect the information of defects. However, PCT does not induce sparsity, which limits the interpretation of PCT results. Recently, sparse PCT (SPCT) has been proposed to provide more interpretable analysis results. However, SPCT does not consider the spatial connectivity between pixels, omitting the fact that a defective region is usually spatially connected. In this article, a novel thermographic data analysis method is proposed to overcome the shortcomings of the existing methods. The proposed method imposes both spatial connectivity and sparsity constraints in PCT. Finally, one case study on an ancient marquetry sample and another on a carbon fiber-reinforced polymer composite illustrate the feasibility of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2021

3. Generative Principal Component Thermography for Enhanced Defect Detection and Analysis.

Author

Liu, Kaixin, Li, Yingjie, Yang, Jianguo, Liu, Yi, and Yao, Yuan

Subjects

*THERMOGRAPHY, *DEEP learning, *NONDESTRUCTIVE testing, *CARBON fibers, *MACHINE learning, *DATA analysis, *GALLIUM nitride

Abstract

Machine learning methods play an important role in the nondestructive testing field for quality assessment of polymer composites. As a popular deep learning branch, a generative adversarial network is introduced to the thermography field as an image augmentation approach to improve its defect detection performance. Specifically, a generative principal component thermography (GPCT) method for defect detection in polymer composites is proposed. By employing the data augmentation strategy, more informative images are generated to enlarge the diversity of the original set of images. The defect detection results can be visualized using a number of interpretable features. Consequently, the defect detection performance of thermographic data analysis can be enhanced to some extent. The experimental results on a carbon fiber reinforced polymer specimen demonstrate the feasibility and advantages of the GPCT method. [ABSTRACT FROM AUTHOR]

Published

2020

4. Multiview Learning for Subsurface Defect Detection in Composite Products: A Challenge on Thermographic Data Analysis.

Author

Wu, Haibin, Zheng, Kaiyi, Sfarra, Stefano, Liu, Yi, and Yao, Yuan

Abstract

Nondestructive testing (NDT) is an economical way of detecting subsurface defects in composite products. Infrared thermography serves as a popular NDT method due to its high efficiency and low cost. However, defect identification by directly visualizing thermal images is difficult owing to the nonuniform background and noise. Recently, data analysis methods have been introduced to thermal image processing, including principal component analysis, which is known for its good performance in dimensionality reduction, feature extraction, and noise reduction. However, most of these methods can only extract linear features. In this article, a multiview learning-based autoencoder, which can process not only nonlinear features but also sequential attributes, is utilized in thermographic data analysis. After extracting the low-dimensional features by multiview learning, a background elimination step is conducted to highlight the locations and shapes of the defects. The experimental results demonstrate the feasibility of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2020

5. Spatial-Neighborhood Manifold Learning for Nondestructive Testing of Defects in Polymer Composites.

Author

Liu, Yi, Liu, Kaixin, Yang, Jianguo, and Yao, Yuan

Abstract

The subspace learning (dimensionality reduction) algorithms have played an important role in the analysis of thermographic data: a key step in infrared thermography-based nondestructive testing of subsurface defects in composite materials. However, one of its branches, manifold learning, with excellent ability to preserve local data structure, is rarely applied. In this article, a spatial-neighborhood manifold learning (SNML) framework is proposed for thermographic data analysis. Different from traditional manifold learning methods, SNML uses the spatial-neighborhood information instead of the traditional k-nearest neighbors, or $\varepsilon$ -neighborhood, to construct the adjacency graph. This overcomes the difficulty of parameter selection and extracts local features in images in a more reasonable way. Additionally, the data preprocessing step and the means of thermographic data normalization in the proposed framework are discussed. For performance comparison, three traditional manifold learning methods are also implemented. The experiments on carbon fiber-reinforced polymer specimens demonstrate the validity and feasibility of SNML. [ABSTRACT FROM AUTHOR]

Published

2020

6. Non-destructive defect evaluation of polymer composites via thermographic data analysis: A manifold learning method.

Author

Liu, Yi, Liu, Kaixin, Gao, Zengliang, Yao, Yuan, Sfarra, Stefano, Zhang, Hai, and Maldague, Xavier P.V.

Subjects

*DIMENSION reduction (Statistics), *CARBON fiber-reinforced plastics, *DATA analysis, *NONDESTRUCTIVE testing, *THERMOGRAPHY, *IMAGE processing

Abstract

Highlights • A nonlinear manifold learning based thermographic data analysis method is proposed. • It is the first time that ISOMAP is introduced to the field of IRT. • The method performance is quantitatively evaluated using the SNR index. • The proposed method is promising for subsurface defect detection. • The proposed method can also be used in nondestructive testing of other materials. Abstract Recently, various thermographic data analysis methods have been utilized in the field of non-destructive evaluation (NDE) to process thermal images and enhance the visibility of defects. However, most of them extract only linear features, leading to cumbersome results. In this work, manifold learning is introduced into the thermographic data analysis field. As a nonlinear dimensionality reduction technique, manifold learning can identify an intrinsically low-dimensional manifold in a high-dimensional data space. Specifically, an isometric feature mapping (ISOMAP) based manifold learning thermography (MLT) method is proposed to analyze the thermographic data, which can effectively distinguish the uneven background, noise, and defect characteristics contained in thermal images and make the defect detection easier. The feasibility of MLT is illustrated using a carbon fiber-reinforced polymer (CFRP) specimen. The results show that, comparing to the conventional linear methods, the present method can better determine the defect information, including the positions, sizes, and shapes. [ABSTRACT FROM AUTHOR]

Published

2019

7. Thermographic Data Analysis for Defect Detection by Imposing Spatial Connectivity and Sparsity Constraints in Principal Component Thermography

Author

Yuan Yao, Stefano Sfarra, Ching-Mei Wen, and Gianfranco Gargiulo

Subjects

defect detection, Computer science, Active thermography, defect detection, principal component thermography (PCT), sparsity, spatial connectivity, thermographic data analysis, Feature extraction, 02 engineering and technology, thermographic data analysis, 0202 electrical engineering, electronic engineering, information engineering, Electrical and Electronic Engineering, Active thermography, Pixel, business.industry, Dimensionality reduction, sparsity, 020208 electrical & electronic engineering, Pattern recognition, Sample (graphics), Computer Science Applications, Identification (information), Control and Systems Engineering, Principal component analysis, Thermography, Data analysis, spatial connectivity, principal component thermography (PCT), Artificial intelligence, business, Information Systems

Abstract

Data analysis methods have been extensively used in active thermography for defect identification. Among them, principal component thermography (PCT) is popular for dimensionality reduction and feature extraction. PCT summarizes the thermal images with a small number of empirical orthogonal functions that better reflect the information of defects. However, PCT does not induce sparsity, which limits the interpretation of PCT results. Recently, sparse PCT (SPCT) has been proposed to provide more interpretable analysis results. However, SPCT does not consider the spatial connectivity between pixels, omitting the fact that a defective region is usually spatially connected. In this article, a novel thermographic data analysis method is proposed to overcome the shortcomings of the existing methods. The proposed method imposes both spatial connectivity and sparsity constraints in PCT. Finally, one case study on an ancient marquetry sample and another on a carbon fiber-reinforced polymer composite illustrate the feasibility of the proposed method.

Published

2021

8. Enhanced Defect Detection in Carbon Fiber Reinforced Polymer Composites via Generative Kernel Principal Component Thermography

Author

Yi Liu, Zhengyang Ma, Kaixin Liu, Jianguo Yang, and Yuan Yao

Subjects

Polymers and Plastics, Computer science, Normalization (image processing), 02 engineering and technology, Kernel principal component analysis, Article, lcsh:QD241-441, lcsh:Organic chemistry, thermographic data analysis, 0202 electrical engineering, electronic engineering, information engineering, polymer composite, Composite material, Carbon fiber reinforced polymer, business.industry, Deep learning, 020208 electrical & electronic engineering, generative adversarial network, deep learning, General Chemistry, kernel principal component analysis, 021001 nanoscience & nanotechnology, infrared non-destructive assessment, Kernel (statistics), Principal component analysis, Thermography, Data analysis, Artificial intelligence, 0210 nano-technology, business

Abstract

Increasing machine learning methods are being applied to infrared non-destructive assessment for internal defects assessment of composite materials. However, most of them extract only linear features, which is not in accord with the nonlinear characteristics of infrared data. Moreover, limited infrared images tend to restrict the data analysis capabilities of machine learning methods. In this work, a novel generative kernel principal component thermography (GKPCT) method is proposed for defect detection of carbon fiber reinforced polymer (CFRP) composites. Specifically, the spectral normalization generative adversarial network is proposed to augment the thermograms for model construction. Sequentially, the KPCT method is used by feature mapping of all thermogram data using kernel principal component analysis, which allows for differentiation of defects and background in the dimensionality-reduced data. Additionally, a defect-background separation metric is designed to help the performance evaluation of data analysis methods. Experimental results on CFRP demonstrate the feasibility and advantages of the proposed GKPCT method.

Published

2021

9. Multiview Learning for Subsurface Defect Detection in Composite Products: A Challenge on Thermographic Data Analysis

Author

Yi Liu, Haibin Wu, Stefano Sfarra, Kaiyi Zheng, and Yuan Yao

Subjects

multiview learning, Computer science, Noise reduction, Decoding, Feature extraction, Testing, Data analysis, Principal component analysis, 02 engineering and technology, Nondestructive testing, thermographic data analysis, 0202 electrical engineering, electronic engineering, information engineering, Electrical and Electronic Engineering, business.industry, Noise (signal processing), Dimensionality reduction, feature extraction, 020208 electrical & electronic engineering, Temperature, deep learning, nondestructive testing (NDT), Pattern recognition, Heating systems, Autoencoder, Computer Science Applications, Control and Systems Engineering, Thermography, Artificial intelligence, business, Information Systems

Abstract

Nondestructive testing (NDT) is an economical way of detecting subsurface defects in composite products. Infrared thermography serves as a popular NDT method due to its high efficiency and low cost. However, defect identification by directly visualizing thermal images is difficult owing to the nonuniform background and noise. Recently, data analysis methods have been introduced to thermal image processing, including principal component analysis, which is known for its good performance in dimensionality reduction, feature extraction, and noise reduction. However, most of these methods can only extract linear features. In this article, a multiview learning-based autoencoder, which can process not only nonlinear features but also sequential attributes, is utilized in thermographic data analysis. After extracting the low-dimensional features by multiview learning, a background elimination step is conducted to highlight the locations and shapes of the defects. The experimental results demonstrate the feasibility of the proposed method.

Published

2020

10. Non-destructive defect evaluation of polymer composites via thermographic data analysis: A manifold learning method

Author

Yi Liu, Yuan Yao, Hai Zhang, Zengliang Gao, Stefano Sfarra, Kaixin Liu, and Xavier Maldague

Subjects

Computer science, 02 engineering and technology, 01 natural sciences, Active infrared thermography, Field (computer science), law.invention, 010309 optics, law, Atomic and Molecular Physics, 0103 physical sciences, Electronic, Thermographic data analysis, Optical and Magnetic Materials, Carbon fiber-reinforced polymer, Manifold learning, Non-destructive evaluation, Electronic, Optical and Magnetic Materials, Atomic and Molecular Physics, and Optics, Condensed Matter Physics, business.industry, Noise (signal processing), Process (computing), Nonlinear dimensionality reduction, Pattern recognition, 021001 nanoscience & nanotechnology, Thermography, Data analysis, Artificial intelligence, and Optics, 0210 nano-technology, Isomap, business, Manifold (fluid mechanics)

Abstract

Recently, various thermographic data analysis methods have been utilized in the field of non-destructive evaluation (NDE) to process thermal images and enhance the visibility of defects. However, most of them extract only linear features, leading to cumbersome results. In this work, manifold learning is introduced into the thermographic data analysis field. As a nonlinear dimensionality reduction technique, manifold learning can identify an intrinsically low-dimensional manifold in a high-dimensional data space. Specifically, an isometric feature mapping (ISOMAP) based manifold learning thermography (MLT) method is proposed to analyze the thermographic data, which can effectively distinguish the uneven background, noise, and defect characteristics contained in thermal images and make the defect detection easier. The feasibility of MLT is illustrated using a carbon fiber-reinforced polymer (CFRP) specimen. The results show that, comparing to the conventional linear methods, the present method can better determine the defect information, including the positions, sizes, and shapes.

Published

2019

11. Independent component thermography for non-destructive testing of defects in polymer composites

Author

Hsiu-Li Wen, Stefano Sfarra, Chunhui Zhao, Kaixin Liu, Yi Liu, Jin-Yi Wu, and Yuan Yao

Subjects

Materials science, business.industry, polymer composites, Applied Mathematics, Non-destructive testing, Independent component analysis, active infrared thermography, independent component analysis, Nondestructive testing, Component (UML), Thermography, thermographic data analysis, Polymer composites, Composite material, business, Instrumentation, Engineering (miscellaneous), active infrared thermography, independent component analysis, Non-destructive testing, polymer composites, thermographic data analysis

Published

2019

12. Enhanced Defect Detection in Carbon Fiber Reinforced Polymer Composites via Generative Kernel Principal Component Thermography.

Author

Liu, Kaixin, Ma, Zhengyang, Liu, Yi, Yang, Jianguo, Yao, Yuan, and González-Benito, Javier

Subjects

*FIBROUS composites, *GENERATIVE adversarial networks, *CARBON fibers, *THERMOGRAPHY, *PRINCIPAL components analysis

Abstract

Increasing machine learning methods are being applied to infrared non-destructive assessment for internal defects assessment of composite materials. However, most of them extract only linear features, which is not in accord with the nonlinear characteristics of infrared data. Moreover, limited infrared images tend to restrict the data analysis capabilities of machine learning methods. In this work, a novel generative kernel principal component thermography (GKPCT) method is proposed for defect detection of carbon fiber reinforced polymer (CFRP) composites. Specifically, the spectral normalization generative adversarial network is proposed to augment the thermograms for model construction. Sequentially, the KPCT method is used by feature mapping of all thermogram data using kernel principal component analysis, which allows for differentiation of defects and background in the dimensionality-reduced data. Additionally, a defect-background separation metric is designed to help the performance evaluation of data analysis methods. Experimental results on CFRP demonstrate the feasibility and advantages of the proposed GKPCT method. [ABSTRACT FROM AUTHOR]

Published

2021