A New Classification of Existing Techniques for Error/Defect Detection in Image Processing
محورهای موضوعی : Majlesi Journal of Telecommunication DevicesHaider Abdulzahra Saad Alsaide 1 , Mohammad Reza Soltanaghaei 2 , Wael Hussein Zayer Al-Lami 3 , Razieh Asgarnezhad 4
1 - Department of Computer Engineering, Isfahan (Khorasgan) Branch, Islamic Azad University, Isfahan, Iran
2 - Department of Computer Engineering, Isfahan (Khorasgan) Branch, Islamic Azad University, Isfahan, Iran
3 - Electronic Department, Amara Technical Institute, Southern Technical University, Missan, Iraq
4 - Department of Computer Engineering, Aghigh Institute of Higher Education Shahinshahr, 8314678755, Isfahan, Iran.
کلید واژه: Machine Learning, Deep Learning, Defect Detection,
چکیده مقاله :
The detection of defects is important in quality control in manufacturing. These defects raise the costs incurred by enterprises, compress the service life of simulated products, and result in the expansive destruction of resources, thereby significantly harming people and their safety. Defect detection and classification need to be feasted as unique problems associated with the field of artificial vision. We categorize the defects like electronic components, pipes, welded parts, textile materials, etc. We express artificial visual processing techniques aimed at comprehending the charged picture in a mathematical/analytical manner. Recent mainstream and deep-learning techniques in defect detection are studied with their features, stability, and weaknesses explained. We resume with a survey of textural defect detection based on statistical, structural, and other methods. We investigate the application of ultrasonic testing, filtering, deep learning, machine vision, and other technologies utilized for defect detection to offer a new classification. In addition, high precision, high positioning, fast detection, and small objects through examination are the biggest challenges in applying quality detection.
The detection of defects is important in quality control in manufacturing. These defects raise the costs incurred by enterprises, compress the service life of simulated products, and result in the expansive destruction of resources, thereby significantly harming people and their safety. Defect detection and classification need to be feasted as unique problems associated with the field of artificial vision. We categorize the defects like electronic components, pipes, welded parts, textile materials, etc. We express artificial visual processing techniques aimed at comprehending the charged picture in a mathematical/analytical manner. Recent mainstream and deep-learning techniques in defect detection are studied with their features, stability, and weaknesses explained. We resume with a survey of textural defect detection based on statistical, structural, and other methods. We investigate the application of ultrasonic testing, filtering, deep learning, machine vision, and other technologies utilized for defect detection to offer a new classification. In addition, high precision, high positioning, fast detection, and small objects through examination are the biggest challenges in applying quality detection.
[1] T. Wang, Y. Chen, M. Qiao, and H. Snoussi, "A fast and robust convolutional neural network-based defect detection model in product quality control," The International Journal of Advanced Manufacturing Technology, vol. 94, pp. 3465-3471, 2018.
[2] B. Li, M. Cobo-Medina, J. Lecourt, N. Harrison, R. J. Harrison, and J. V. Cross, "Application of hyperspectral imaging for nondestructive measurement of plum quality attributes," Postharvest Biology and Technology, vol. 141, pp. 8-15, 2018.
[3] P. Li, I. Dolado, F. J. Alfaro-Mozaz, F. Casanova, L. E. Hueso, S. Liu, et al., "Infrared hyperbolic metasurface based on nanostructured van der Waals materials," Science, vol. 359, pp. 892-896, 2018.
[4] X. Xie, "A review of recent advances in surface defect detection using texture analysis techniques," ELCVIA: electronic letters on computer vision and image analysis, pp. 1-22, 2008.
[5] H. Y. Ngan, G. K. Pang, and N. H. Yung, "Automated fabric defect detection—A review," Image and vision computing, vol. 29, pp. 442-458, 2011.
[6] P. Mahajan, S. Kolhe, and P. Patil, "A review of automatic fabric defect detection techniques," Advances in Computational Research, vol. 1, pp. 18-29, 2009.
[7] I. J. Aldave, P. V. Bosom, L. V. González, I. L. De Santiago, B. Vollheim, L. Krausz, et al., "Review of thermal imaging systems in composite defect detection," Infrared Physics & Technology, vol. 61, pp. 167-175, 2013.
[8] W. Zhang, C. Ye, K. Zheng, J. Zhong, Y. Tang, Y. Fan, et al., "Tensan silk-inspired hierarchical fibers for smart textile applications," ACS nano, vol. 12, pp. 6968-6977, 2018.
[9] E. Moulin, L. Chehami, J. Assaad, J. De Rosny, C. Prada, E. Chatelet, et al., "Passive defect detection in plate from nonlinear conversion of low-frequency vibrational noise," The Journal of the Acoustical Society of America, vol. 140, pp. 3002-3002, 2016.
[10] Y. Li, W. Zhao, and J. Pan, "Deformable patterned fabric defect detection with fisher criterion-based deep learning," IEEE Transactions on Automation Science and Engineering, vol. 14, pp. 1256-1264, 2016.
[11] A. L. Elrefai and I. Sasada, "Magnetic particle detection system using fluxgate gradiometer on a permalloy shielding disk," IEEE Magnetics Letters, vol. 7, pp. 1-4, 2016.
[12] G. D’Angelo, M. Laracca, S. Rampone, and G. Betta, "Fast eddy current testing defect classification using Lissajous figures," IEEE Transactions on Instrumentation and Measurement, vol. 67, pp. 821-830, 2018.
[13] M. Kusano, H. Hatano, M. Watanabe, S. Takekawa, H. Yamawaki, K. Oguchi, et al., "Mid-infrared pulsed laser ultrasonic testing for carbon fiber reinforced plastics," Ultrasonics, vol. 84, pp. 310-318, 2018.
[14] J. Yang, S. Li, Z. Gao, Z. Wang, and W. Liu, "Real-time recognition method for 0.8 cm darning needles and KR22 bearings based on convolution neural networks and data increase," Applied Sciences, vol. 8, p. 1857, 2018.
[15] J. Li, G. Wang, and Z. Xu, "Environmentally-friendly oxygen-free roasting/wet magnetic separation technology for in situ recycling cobalt, lithium carbonate and graphite from spent LiCoO2/graphite lithium batteries," Journal of Hazardous Materials, vol. 302, pp. 97-104, 2016.
[16] T. Rymarczyk, K. Szumowski, P. Adamkiewicz, P. Tchórzewski, and J. Sikora, "Moisture Wall Inspection Using Electrical Tomography Measurements," Przegląd Elektrotechniczny, vol. 94, pp. 97-100, 2018.
[17] G. Shelikhov and Y. A. Glazkov, "On the improvement of examination questions during the nondestructive testing of magnetic powder," Russian Journal of Nondestructive Testing, vol. 47, pp. 112-117, 2011.
[18] A. García-Arribas, F. Martínez, E. Fernández, I. Ozaeta, G. Kurlyandskaya, A. Svalov, et al., "GMI detection of magnetic-particle concentration in continuous flow," Sensors and Actuators A: Physical, vol. 172, pp. 103-108, 2011.
[19] J. Chen, Z. Liu, H. Wang, A. Núñez, and Z. Han, "Automatic defect detection of fasteners on the catenary support device using deep convolutional neural network," IEEE Transactions on Instrumentation and Measurement, vol. 67, pp. 257-269, 2017.
[20] G. Y. Tian and A. Sophian, "Defect classification using a new feature for pulsed eddy current sensors," Ndt & E International, vol. 38, pp. 77-82, 2005.
[21] H. Yang and L. Yu, "Feature extraction of wood-hole defects using wavelet-based ultrasonic testing," Journal of forestry research, vol. 28, pp. 395-402, 2017.
[22] S. Gholizadeh, "A review of non-destructive testing methods of composite materials," Procedia structural integrity, vol. 1, pp. 50-57, 2016.
[23] Y. Fang, L. Lin, H. Feng, Z. Lu, and G. W. Emms, "Review of the use of air-coupled ultrasonic technologies for nondestructive testing of wood and wood products," Computers and electronics in agriculture, vol. 137, pp. 79-87, 2017.
[24] H.-D. Lin and H.-L. Chen, "Automated visual fault inspection of optical elements using machine vision technologies," Journal of Applied Engineering Science, vol. 16, pp. 447-453, 2018.
[25] F. Jia, Y. Lei, J. Lin, X. Zhou, and N. Lu, "Deep neural networks: A promising tool for fault characteristic mining and intelligent diagnosis of rotating machinery with massive data," Mechanical systems and signal processing, vol. 72, pp. 303-315, 2016.
[26] M. A. Habib, C. H. Kim, and J.-M. Kim, "A crack characterization method for reinforced concrete beams using an acoustic emission technique," Applied Sciences, vol. 10, p. 7918, 2020.
[27] Y. Yang, L. Pan, J. Ma, R. Yang, Y. Zhu, Y. Yang, et al., "A high-performance deep learning algorithm for the automated optical inspection of laser welding," Applied Sciences, vol. 10, p. 933, 2020.
[28] M. Meng, Y. J. Chua, E. Wouterson, and C. P. K. Ong, "Ultrasonic signal classification and imaging system for composite materials via deep convolutional neural networks," Neurocomputing, vol. 257, pp. 128-135, 2017.
[29] M. G. Droubi, N. H. Faisal, F. Orr, J. A. Steel, and M. El-Shaib, "Acoustic emission method for defect detection and identification in carbon steel welded joints," Journal of Constructional Steel Research, vol. 134, pp. 28-37, 2017.
[30] W. M. Alobaidi, E. A. Alkuam, H. M. Al-Rizzo, and E. Sandgren, "Applications of ultrasonic techniques in oil and gas pipeline industries: A review," American Journal of Operations Research, vol. 5, p. 274, 2015.
[31] N. Boaretto and T. M. Centeno, "Automated detection of welding defects in pipelines from radiographic images DWDI," Ndt & E International, vol. 86, pp. 7-13, 2017.
[32] B. Masserey and P. Fromme, "Surface defect detection in stiffened plate structures using Rayleigh-like waves," Ndt & E International, vol. 42, pp. 564-572, 2009.
[33] I. G. Kazantsev, I. Lemahieu, G. Salov, and R. Denys, "Statistical detection of defects in radiographic images in nondestructive testing," Signal Processing, vol. 82, pp. 791-801, 2002.
[34] J. W. Wilson and G. Y. Tian, "Pulsed electromagnetic methods for defect detection and characterisation," NDT & E International, vol. 40, pp. 275-283, 2007.
[35] D. Marr and E. Hildreth, "Theory of edge detection," Proceedings of the Royal Society of London. Series B. Biological Sciences, vol. 207, pp. 187-217, 1980.
[36] D.-M. Tsai and T.-Y. Huang, "Automated surface inspection for statistical textures," Image and Vision computing, vol. 21, pp. 307-323, 2003.
[37] J. G. Daugman, "Two-dimensional spectral analysis of cortical receptive field profiles," Vision research, vol. 20, pp. 847-856, 1980.
[38] K. L. Mak and P. Peng, "An automated inspection system for textile fabrics based on Gabor filters," Robotics and Computer-Integrated Manufacturing, vol. 24, pp. 359-369, 2008.
[39] A. Bodnarova, M. Bennamoun, and S. Latham, "Optimal Gabor filters for textile flaw detection," Pattern recognition, vol. 35, pp. 2973-2991, 2002.
[40] J. J. Liu and J. F. MacGregor, "Estimation and monitoring of product aesthetics: application to manufacturing of “engineered stone” countertops," Machine Vision and Applications, vol. 16, pp. 374-383, 2006.
[41] S. G. Mallat, "A theory for multiresolution signal decomposition: the wavelet representation," IEEE transactions on pattern analysis and machine intelligence, vol. 11, pp. 674-693, 1989.
[42] B. B. Mandelbrot and B. B. Mandelbrot, The fractal geometry of nature vol. 1: WH freeman New York, 1982.
[43] R. M. Haralick, "Statistical and structural approaches to texture," Proceedings of the IEEE, vol. 67, pp. 786-804, 1979.
[44] J. L. Marroquin, E. A. Santana, and S. Botello, "Hidden Markov measure field models for image segmentation," IEEE Transactions on Pattern Analysis and Machine Intelligence, vol. 25, pp. 1380-1387, 2003.
[45] H. Deng and D. A. Clausi, "Gaussian MRF rotation-invariant features for image classification," IEEE transactions on pattern analysis and machine intelligence, vol. 26, pp. 951-955, 2004.
[46] X.-c. Yuan, L.-s. Wu, and Q. Peng, "An improved Otsu method using the weighted object variance for defect detection," Applied surface science, vol. 349, pp. 472-484, 2015.
[47] M. Aminzadeh and T. Kurfess, "Automatic thresholding for defect detection by background histogram mode extents," Journal of Manufacturing Systems, vol. 37, pp. 83-92, 2015.
[48] X. Li, H. Jiang, and G. Yin, "Detection of surface crack defects on ferrite magnetic tile," Ndt & E International, vol. 62, pp. 6-13, 2014.
[49] D. Zhu, R. Pan, W. Gao, and J. Zhang, "Yarn-dyed fabric defect detection based on autocorrelation function and GLCM," Autex research journal, vol. 15, pp. 226-232, 2015.
[50] L. Zhang, J. Jing, and H. Zhang, "Fabric defect classification based on LBP and GLCM," Journal of Fiber Bioengineering and Informatics, vol. 8, pp. 81-89, 2015.
[51] J. Wang, Q. Li, J. Gan, H. Yu, and X. Yang, "Surface defect detection via entity sparsity pursuit with intrinsic priors," IEEE Transactions on Industrial Informatics, vol. 16, pp. 141-150, 2019.
[52] X. Kang, P. Yang, and J. Jing, "Defect detection on printed fabrics via gabor filter and regular band," Journal of Fiber Bioengineering and Informatics, vol. 8, pp. 195-206, 2015.
[53] Y. Huang and K. L. Chan, "Texture decomposition by harmonics extraction from higher order statistics," IEEE Transactions on Image Processing, vol. 13, pp. 1-14, 2004.
[54] C. E. Costa and M. Petrou, "Automatic registration of ceramic tiles for the purpose of fault detection," Machine Vision and Applications, vol. 11, pp. 225-230, 2000.
[55] K. Y. Song, J. Kittler, and M. Petrou, "Defect detection in random colour textures," Image and vision computing, vol. 14, pp. 667-683, 1996.
[56] W. Wen and A. Xia, "Verifying edges for visual inspection purposes," Pattern recognition letters, vol. 20, pp. 315-328, 1999.
[57] A. Tolba and H. M. Raafat, "Multiscale image quality measures for defect detection in thin films," The International Journal of Advanced Manufacturing Technology, vol. 79, pp. 113-122, 2015.
[58] J. Cao, J. Zhang, Z. Wen, N. Wang, and X. Liu, "Fabric defect inspection using prior knowledge guided least squares regression," Multimedia Tools and Applications, vol. 76, pp. 4141-4157, 2017.
[59] J. P. Yun, S. J. Lee, G. Koo, C. Shin, and C. Park, "Automatic defect inspection system for steel products with exhaustive dynamic encoding algorithm for searches," Optical Engineering, vol. 58, pp. 023107-023107, 2019.
[60] X. Zhou, Y. Wang, C. Xiao, Q. Zhu, X. Lu, H. Zhang, et al., "Automated visual inspection of glass bottle bottom with saliency detection and template matching," IEEE Transactions on Instrumentation and Measurement, vol. 68, pp. 4253-4267, 2019.
[61] C.-h. Chan and G. K. Pang, "Fabric defect detection by Fourier analysis," IEEE transactions on Industry Applications, vol. 36, pp. 1267-1276, 2000.
[62] S. Gai, "New banknote defect detection algorithm using quaternion wavelet transform," Neurocomputing, vol. 196, pp. 133-139, 2016.
[63] D.-M. Tsai, C.-P. Lin, and K.-T. Huang, "Defect detection in coloured texture surfaces using Gabor filters," The Imaging Science Journal, vol. 53, pp. 27-37, 2005.
[64] Q. Zhu, M. Wu, J. Li, and D. Deng, "Fabric defect detection via small scale over-complete basis set," Textile Research Journal, vol. 84, pp. 1634-1649, 2014.
[65] A. Conci and C. B. Proença, "A system for real-time fabric inspection and industrial decision," in Proceedings of the 14th international conference on Software engineering and knowledge engineering, 2002, pp. 707-714.
[66] S. Moradi and T. Zayed, "Real-time defect detection in sewer closed circuit television inspection videos," in Pipelines 2017, ed, 2017, pp. 295-307.
[67] X. Xie and M. Mirmehdi, "TEXEMS: Texture exemplars for defect detection on random textured surfaces," IEEE transactions on pattern analysis and machine intelligence, vol. 29, pp. 1454-1464, 2007.
[68] H. Wang, J. Zhang, Y. Tian, H. Chen, H. Sun, and K. Liu, "A simple guidance template-based defect detection method for strip steel surfaces," IEEE Transactions on Industrial Informatics, vol. 15, pp. 2798-2809, 2018.
[69] T. Czimmermann, G. Ciuti, M. Milazzo, M. Chiurazzi, S. Roccella, C. M. Oddo, et al., "Visual-based defect detection and classification approaches for industrial applications—A survey," Sensors, vol. 20, p. 1459, 2020.
[70] D.-T. Hoang and H.-J. Kang, "A survey on deep learning based bearing fault diagnosis," Neurocomputing, vol. 335, pp. 327-335, 2019.
[71] X. Wei, Z. Yang, Y. Liu, D. Wei, L. Jia, and Y. Li, "Railway track fastener defect detection based on image processing and deep learning techniques: A comparative study," Engineering Applications of Artificial Intelligence, vol. 80, pp. 66-81, 2019.
[72] J. Isavand, A. Kasaei, A. Peplow, X. Wang, and J. Yan, "A reduced-order machine-learning-based method for fault recognition in tool condition monitoring," Measurement, vol. 224, p. 113906, 2024.
[73] L. Luo, W. Wang, S. Bao, X. Peng, and Y. Peng, "Robust and sparse canonical correlation analysis for fault detection and diagnosis using training data with outliers," Expert Systems with Applications, vol. 236, p. 121434, 2024.
[74] L. Deng and D. Yu, "Deep learning: methods and applications," Foundations and trends® in signal processing, vol. 7, pp. 197-387, 2014.
[75] P. Bergmann, S. Löwe, M. Fauser, D. Sattlegger, and C. Steger, "Improving unsupervised defect segmentation by applying structural similarity to autoencoders," arXiv preprint arXiv:1807.02011, 2018.
[76] J. C. Cheng and M. Wang, "Automated detection of sewer pipe defects in closed-circuit television images using deep learning techniques," Automation in Construction, vol. 95, pp. 155-171, 2018.
[77] J. Yang and G. Yang, "Modified convolutional neural network based on dropout and the stochastic gradient descent optimizer," Algorithms, vol. 11, p. 28, 2018.
[78] K. Sun, J. Zhang, C. Zhang, and J. Hu, "Generalized extreme learning machine autoencoder and a new deep neural network," Neurocomputing, vol. 230, pp. 374-381, 2017.
[79] L. Yu, H. Chen, Q. Dou, J. Qin, and P.-A. Heng, "Automated melanoma recognition in dermoscopy images via very deep residual networks," IEEE transactions on medical imaging, vol. 36, pp. 994-1004, 2016.
[80] Y. Xue and Y. Li, "A fast detection method via region‐based fully convolutional neural networks for shield tunnel lining defects," Computer‐Aided Civil and Infrastructure Engineering, vol. 33, pp. 638-654, 2018.
[81] J. Lei, X. Gao, Z. Feng, H. Qiu, and M. Song, "Scale insensitive and focus driven mobile screen defect detection in industry," Neurocomputing, vol. 294, pp. 72-81, 2018.
[82] Z.-Q. Zhao, P. Zheng, S.-t. Xu, and X. Wu, "Object detection with deep learning: A review," IEEE transactions on neural networks and learning systems, vol. 30, pp. 3212-3232, 2019.
[83] D. Tabernik, S. Šela, J. Skvarč, and D. Skočaj, "Segmentation-based deep-learning approach for surface-defect detection," Journal of Intelligent Manufacturing, vol. 31, pp. 759-776, 2020.
[84] H. Lin, B. Li, X. Wang, Y. Shu, and S. Niu, "Automated defect inspection of LED chip using deep convolutional neural network," Journal of Intelligent Manufacturing, vol. 30, pp. 2525-2534, 2019.
[85] S. Ren, K. He, R. Girshick, and J. Sun, "Faster r-cnn: Towards real-time object detection with region proposal networks," Advances in neural information processing systems, vol. 28, 2015.
[86] Y. J. Cha, W. Choi, G. Suh, S. Mahmoudkhani, and O. Büyüköztürk, "Autonomous structural visual inspection using region‐based deep learning for detecting multiple damage types," Computer‐Aided Civil and Infrastructure Engineering, vol. 33, pp. 731-747, 2018.
[87] Y. Wang, M. Liu, P. Zheng, H. Yang, and J. Zou, "A smart surface inspection system using faster R-CNN in cloud-edge computing environment," Advanced Engineering Informatics, vol. 43, p. 101037, 2020.
[88] Y. Liu, Y. Yang, W. Chao, X. Xu, and T. Zhang, "Research on Surface Defect Detection Based on Semantic Segmentation," DEStech Trans. Comput. Sci. Eng, 2019.
[89] S. S. Kumar, D. M. Abraham, M. R. Jahanshahi, T. Iseley, and J. Starr, "Automated defect classification in sewer closed circuit television inspections using deep convolutional neural networks," Automation in Construction, vol. 91, pp. 273-283, 2018.
[90] Y. Li and C. Zhang, "Automated vision system for fabric defect inspection using Gabor filters and PCNN," SpringerPlus, vol. 5, pp. 1-12, 2016.
[91] H. Yang, T. Haist, M. Gronle, and W. Osten, "Realistic simulation of camera images of micro-scale defects for automated defect inspection," in Forum Bildverarbeitung, 2016.
[92] A. Krizhevsky, I. Sutskever, and G. E. Hinton, "Imagenet classification with deep convolutional neural networks," Advances in neural information processing systems, vol. 25, 2012.
[93] Y. He, K. Song, Q. Meng, and Y. Yan, "An end-to-end steel surface defect detection approach via fusing multiple hierarchical features," IEEE transactions on instrumentation and measurement, vol. 69, pp. 1493-1504, 2019.
[94] J. Li, Z. Su, J. Geng, and Y. Yin, "Real-time detection of steel strip surface defects based on improved yolo detection network," IFAC-PapersOnLine, vol. 51, pp. 76-81, 2018.
[95] S. Ozkan, B. Kaya, and G. B. Akar, "Endnet: Sparse autoencoder network for endmember extraction and hyperspectral unmixing," IEEE Transactions on Geoscience and Remote Sensing, vol. 57, pp. 482-496, 2018.
[96] M. Toğaçar, B. Ergen, and Z. Cömert, "Waste classification using AutoEncoder network with integrated feature selection method in convolutional neural network models," Measurement, vol. 153, p. 107459, 2020.
[97] J. Long, Z. Sun, C. Li, Y. Hong, Y. Bai, and S. Zhang, "A novel sparse echo autoencoder network for data-driven fault diagnosis of delta 3-D printers," IEEE Transactions on Instrumentation and Measurement, vol. 69, pp. 683-692, 2019.
[98] K. Chen, K. Chen, Q. Wang, Z. He, J. Hu, and J. He, "Short-term load forecasting with deep residual networks," IEEE Transactions on Smart Grid, vol. 10, pp. 3943-3952, 2018.
[99] A. Creswell, T. White, V. Dumoulin, K. Arulkumaran, B. Sengupta, and A. A. Bharath, "Generative adversarial networks: An overview," IEEE signal processing magazine, vol. 35, pp. 53-65, 2018.
[100] J. Long, E. Shelhamer, and T. Darrell, "Fully convolutional networks for semantic segmentation," in Proceedings of the IEEE conference on computer vision and pattern recognition, 2015, pp. 3431-3440.
[101] Y. Liu, K. Xu, Y. Xu, J. Liu, J. Wu, and Z. Zhang, "HTR: An ultra-high speed algorithm for cage recognition of clathrate hydrates," Nanotechnology Reviews, vol. 11, pp. 699-711, 2022.
[102] N. Kheradmandi and V. Mehranfar, "A critical review and comparative study on image segmentation-based techniques for pavement crack detection," Construction and Building Materials, vol. 321, p. 126162, 2022.
[103] K. E. Hazzan and M. Pacella, "Crack identification in tungsten carbide using image processing techniques," Procedia Structural Integrity, vol. 37, pp. 274-281, 2022.
[104] R. Yadhunath, S. Srikanth, A. Sudheer, C. Jyotsna, and J. Amudha, "Detecting surface cracks on buildings using computer vision: an experimental comparison of digital image processing and deep learning," in Soft Computing and Signal Processing: Proceedings of 3rd ICSCSP 2020, Volume 2, 2022, pp. 197-210.
[105] N. Aravind, S. Nagajothi, and S. Elavenil, "Machine learning model for predicting the crack detection and pattern recognition of geopolymer concrete beams," Construction and Building Materials, vol. 297, p. 123785, 2021.
[106] H. S. Munawar, A. W. Hammad, A. Haddad, C. A. P. Soares, and S. T. Waller, "Image-based crack detection methods: A review," Infrastructures, vol. 6, p. 115, 2021.
[107] N. Safaei, O. Smadi, B. Safaei, and A. Masoud, "Efficient road crack detection based on an adaptive pixel-level segmentation algorithm," Transportation Research Record, vol. 2675, pp. 370-381, 2021.
[108] S. Kostić and D. Vasović, "Prediction model for compressive strength of basic concrete mixture using artificial neural networks," Neural Computing and Applications, vol. 26, pp. 1005-1024, 2015.
[109] Y. Liu, B. He, F. Liu, S. Lu, and Y. Zhao, "Feature fusion using kernel joint approximate diagonalization of eigen-matrices for rolling bearing fault identification," Journal of Sound and Vibration, vol. 385, pp. 389-401, 2016.
[110] Y. Meng, L. Lu, and J. Yan, "Shaft orbit feature based rotator early unbalance fault identification," Procedia CIRP, vol. 56, pp. 512-515, 2016.
[111] K. Ščupáková, V. Terzopoulos, S. Jain, D. Smeets, and R. M. Heeren, "A patch-based super resolution algorithm for improving image resolution in clinical mass spectrometry," Scientific reports, vol. 9, p. 2915, 2019.
[112] J. Zhang, P. Wang, R. X. Gao, and R. Yan, "An image processing approach to machine fault diagnosis based on visual words representation," Procedia Manufacturing, vol. 19, pp. 42-49, 2018.
[113] K.-L. Hung and C. H. Tsai, "Image error detection and error concealment technique based on interleaving prediction and direction information hiding," in 2010 First International Conference on Pervasive Computing, Signal Processing and Applications, 2010, pp. 371-376.
[114] R. Lukac, K. Martin, and K. Platanoitis, "Digital camera zooming based on unified CFA image processing steps," IEEE Transactions on Consumer Electronics, vol. 50, pp. 15-24, 2004.
[115] F. Wu, Z. Yang, X. Mo, Z. Wu, W. Tang, J. Duan, et al., "Detection and counting of banana bunches by integrating deep learning and classic image-processing algorithms," Computers and Electronics in Agriculture, vol. 209, p. 107827, 2023.
[116] K. Adem, M. M. Ozguven, and Z. Altas, "A sugar beet leaf disease classification method based on image processing and deep learning," Multimedia Tools and Applications, vol. 82, pp. 12577-12594, 2023.
[117] M. Rottmann and M. Reese, "Automated detection of label errors in semantic segmentation datasets via deep learning and uncertainty quantification," in Proceedings of the IEEE/CVF Winter Conference on Applications of Computer Vision, 2023, pp. 3214-3223.
[118] S. Prabhakaran, R. A. Uthra, and J. Preetharoselyn, "Deep Learning-Based Model for Defect Detection and Localization on Photovoltaic Panels," Computer Systems Science & Engineering, vol. 44, 2023.
[119] T.-Y. Lin, P. Dollár, R. Girshick, K. He, B. Hariharan, and S. Belongie, "Feature pyramid networks for object detection," in Proceedings of the IEEE conference on computer vision and pattern recognition, 2017, pp. 2117-2125.
[120] C. Edwards, "Growing pains for deep learning," Communications of the ACM, vol. 58, pp. 14-16, 2015.