Detection and Identification of Defects in 3D-Printed Dielectric Structures via Thermographic Inspection and Deep Neural Networks

Szymanik, Barbara; Psuj, Grzegorz; Hashemi, Maryam; Łopato, Przemysław

doi:10.3390/ma14154168

Cited by 20 publications

(10 citation statements)

References 50 publications

(52 reference statements)

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“…The modeling strategy is effective for modern complex materials (such as composite materials). The use of DCNNs has been proven to be able to identify the defect parameters of 3D printing materials [130], and the use of RNN models can also predict the plastic deformation of materials with unique geometric shapes (such as 3D materials) [52].…”

Section: Discussionmentioning

confidence: 99%

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Deep learning modeling strategy for material science: from natural materials to metamaterials

Chen

Xiong

et al. 2022

J. Phys. Mater.

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Computational modeling is a crucial approach in material-related research for discovering new materials with superior properties. However, the high design flexibility in materials, especially in the realm of metamaterials where the sub-wavelength structure provides an additional degree of freedom in design, poses a formidable computational cost in various real-world applications. With the advent of big data, deep learning brings revolutionary breakthroughs in many conventional machine learning and pattern recognition tasks such as image classification. The accompanied data-driven modeling paradigm also provides transformative methodology shift in materials science, from trial-and-error routine to intelligent material discovery and analysis. This review systematically summarize the application of deep learning in material science, based on a model selection perspective for both natural materials and metamaterials. The review aims to uncover the logic behind data-model relation with emphasis on suitable data structures for different scenarios in the material study and the corresponding problem-solving deep learning model architectures.

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Section: Discussionmentioning

confidence: 99%

“…The use of hybrid models can also solve the optimization design of multilayer coatings in perovskite solar cells [129] and evaluate the status of 3D printing structures [130]. A more complex hybrid model is used to predict the properties of the grain boundary (GB).…”

Section: Hybrid Models With Other Algorithmsmentioning

confidence: 99%

Deep learning modeling strategy for material science: from natural materials to metamaterials

Chen

Xiong

et al. 2022

J. Phys. Mater.

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“…Due to their properties, CNN networks find many applications in computer vision and image recognition [ 41 ]. Applications in object recognition and tracking [ 41 ], medicine—for imaging diagnosis of diseases [ 52 ] or in technology—for the assessment of the state of structures [ 42 , 45 , 53 , 54 , 55 , 56 ] or design [ 57 ], and testing the properties [ 53 ] of materials, comprise a special area. For example, in [ 52 ], the effectiveness of detecting carious lesions was on average between 82% and 89%.…”

Section: Deep Cnn-based Go Steel Identification Proceduresmentioning

confidence: 99%

“…The CNN are also used in the field of non-destructive testing (NDT). In [ 54 ] and [ 55 ], the CNNs have been used for the automatic defect identification, respectively, in steel elements based on magnetic imaging and in 3D printouts by thermal examination, achieving an overall accuracy of over 90%. The CNN are also used to detect changes in dynamic systems and classify their states based on STFT spectral characteristics [ 58 , 59 , 60 ].…”

Section: Deep Cnn-based Go Steel Identification Proceduresmentioning

confidence: 99%

Identification of Grain Oriented SiFe Steels Based on Imaging the Instantaneous Dynamics of Magnetic Barkhausen Noise Using Short-Time Fourier Transform and Deep Convolutional Neural Network

2021

Self Cite

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This paper presents a new approach to the extraction and analysis of information contained in magnetic Barkhausen noise (MBN) for evaluation of grain oriented (GO) electrical steels. The proposed methodology for MBN analysis is based on the combination of the Short-Time Fourier Transform for the observation of the instantaneous dynamics of the phenomenon and deep convolutional neural networks (DCNN) for the extraction of hidden information and building the knowledge. The use of DCNN makes it possible to find even complex and convoluted rules of the Barkhausen phenomenon course, difficult to determine based solely on the selected features of MBN signals. During the tests, several samples made of conventional and high permeability GO steels were tested at different angles between the rolling and transverse directions. The influences of the angular resolution and the proposed additional prediction update algorithm on the DCNN accuracy were investigated, obtaining the highest gain for the angle of 3.6°, for which the overall accuracy exceeded 80%. The obtained results indicate that the proposed new solution combining time–frequency analysis and DCNN for the quantification of information from MBN having stochastic nature may be a very effective tool in the characterization of the magnetic materials.

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“…Extracting such a collection from the same data set, which is then assessed by a trained network, is the most often employed approach. In our previous work, we have shown that, for this purpose, the convolutional neural networks may be used [ 40 ], and other researchers have worked on a similar problem [ 41 ]. This results in the obvious issue of a network adjusting to a single−use case, rendering it very inflexible and unsuited for jobs requiring some automation.…”

Section: Introductionmentioning

confidence: 99%

An Evaluation of 3D-Printed Materials’ Structural Properties Using Active Infrared Thermography and Deep Neural Networks Trained on the Numerical Data

Szymanik

2022

Materials

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This article describes an approach to evaluating the structural properties of samples manufactured through 3D printing via active infrared thermography. The mentioned technique was used to test the PETG sample, using halogen lamps as an excitation source. First, a simplified, general numerical model of the phenomenon was prepared; then, the obtained data were used in a process of the deep neural network training. Finally, the network trained in this manner was used for the material evaluation on the basis of the original experimental data. The described methodology allows for the automated assessment of the structural state of 3D−printed materials. The usage of a generalized model is an innovative method that allows for greater product assessment flexibility.

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Detection and Identification of Defects in 3D-Printed Dielectric Structures via Thermographic Inspection and Deep Neural Networks

Cited by 20 publications

References 50 publications

Deep learning modeling strategy for material science: from natural materials to metamaterials

Deep learning modeling strategy for material science: from natural materials to metamaterials

Identification of Grain Oriented SiFe Steels Based on Imaging the Instantaneous Dynamics of Magnetic Barkhausen Noise Using Short-Time Fourier Transform and Deep Convolutional Neural Network

An Evaluation of 3D-Printed Materials’ Structural Properties Using Active Infrared Thermography and Deep Neural Networks Trained on the Numerical Data

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