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International Journal of Intelligent Data and Machine Learning

Open Access Peer Review International
Open Access

Data-Driven Model Supporting Defect Analysis through Vision Techniques in Press-Formed Vehicle Components

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Dr. Tashi Wangchuk 1 , Karma Lhendup 1 ,
4 Department of Data Science and Artificial Intelligence Royal University of Bhutan Thimphu, Bhutan
4 Faculty of Information Technology College of Science and Technology, Royal University of Bhutan Phuentsholing, Bhutan

Abstract

The increasing complexity of automotive manufacturing, particularly in press-formed metal components, necessitates advanced inspection systems capable of ensuring high-quality standards while maintaining production efficiency. Traditional inspection approaches, often reliant on manual evaluation and rule-based systems, suffer from limitations including subjectivity, low scalability, and inability to detect subtle defects. This research presents a comprehensive data-driven model that integrates machine vision and learning-based techniques for defect analysis in press-formed vehicle components. The proposed framework leverages image acquisition systems, feature extraction mechanisms, and classification algorithms, particularly K-nearest neighbor (KNN) variants and hybrid machine learning architectures, to identify surface and structural anomalies in stamped parts.

The study systematically examines the theoretical foundations of visual inspection systems, the role of machine learning in defect classification, and the integration of data-driven methodologies within manufacturing pipelines. By synthesizing insights from existing literature, the research identifies critical gaps, particularly in real-time adaptability, model generalization, and robustness in varying industrial conditions. A modular architecture is proposed, incorporating preprocessing, feature engineering, and predictive modeling stages, enabling scalable and efficient defect detection.

Experimental simulations and analytical evaluations demonstrate that the proposed model significantly enhances detection accuracy, reduces false positives, and improves processing speed compared to conventional approaches. Furthermore, the study highlights the impact of data quality, feature selection, and algorithm optimization on overall system performance. The findings underscore the importance of integrating advanced machine vision techniques with intelligent algorithms to achieve reliable quality assurance in automotive manufacturing.

The research contributes to the field by offering a structured, scalable, and adaptable framework for defect analysis, addressing both theoretical and practical challenges. It also provides insights into future directions, including deep learning integration, real-time deployment, and adaptive learning systems. The proposed approach holds significant potential for improving manufacturing efficiency, reducing costs, and ensuring product reliability in the automotive industry.

Keywords

Machine vision, defect detection, press forming, automotive components

References

📄 K. Ashwini and S. B. Rudraswamy, “Automated inspection system for automobile bearing seals,” Materials Today: Proceedings, vol. 46, pp. 4709–4715, 2021.
📄 N. Baluch, N. Nordin, and S. Mohtar, “AHSS auto structural metal stampings: Crucial role of lubricant,” Applied Mechanics and Materials, vol. 590, pp. 289–293, 2014.
📄 Y. Bo, C. Bo, Y. Yao, and C. Tan, “A spectroscopic method based on support vector machine and artificial neural network for fiber laser welding defects detection and classification,” NDT and E International, vol. 108, pp. 1–9, 2019.
📄 M. Buongiorno, M. Prunella, S. Grossi, S. M. Hussain, A. Rennola, N. Longo, G. D. Stefano, V. Bevilacqua, and A. Brunetti, “Inline defective laser weld identification by processing thermal image sequences with machine and deep learning techniques,” Applied Sciences, vol. 12, p. 6455, 2022.
📄 M. David and M. A. Firdaus, “Defect rate prediction in manufacturing process using K-nearest neighbor algorithm,” International Journal of Informatics, Economics, Management and Science, vol. 3, no. 2, pp. 161–173, 2024.
📄 Y. P. Fan, “Sheet metal cover drawing forming process analysis,” Advanced Materials Research, pp. 971–973, 2014.
📄 J. M. Grochowalski and T. Chady, “Rapid identification of material defects based on pulsed multifrequency eddy current testing and the k-nearest neighbor method,” Materials, vol. 16, 6650, 2023.
📄 S. Gupta, N. Bhadoria, and P. Satpute, “Survey paper on visual inspection of a mechanical part using machine learning,” International Journal of Engineering Research & Technology (IJERT), vol. 9, pp. 106–109, 2015.
📄 M. Hafizzul, “Design and development of a checking fixture for an automotive press part,” Project Report, Faculty of Manufacturing, Universiti Teknikal Malaysia Melaka, Malaysia, 2017.
📄 R. K. Halder, M. N. Uddin, and M. A. Uddin, “Enhancing K-nearest neighbor algorithm: a comprehensive review and performance analysis of modifications,” Journal of Big Data, vol. 11, pp. 113–120, 2024.
📄 E. Hoffman, Jig and Fixture Design. Singapore: Delmar, pp. 1–86.
📄 C. D. Horvath, “Advanced steels for lightweight automotive structures,” Journal of Materials, Design and Manufacturing for Lightweight Vehicles, pp. 39–95, 2020.
📄 T. Huang, Y. Zhang, Z. Yu, R. Cheng, Y. Li, R. Xiong, L. Ma, J. Zhao, S. Dong, L. Zhu, J. Li, S. Jia, Y. Fu, B. Shi, S. Wu, and Y. Tian, “Faster camera and machine vision with ordinary devices,” Engineering, vol. 25, pp. 110–119, 2023.
📄 A. K. Kausik, A. B. Rashid, R. F. Baki, and M. M. J. Maktum, “Machine learning algorithms for manufacturing quality assurance: A systematic review of performance metrics and applications,” Array, vol. 26, 100393, 2025.
📄 W. Li, E. Nilsson, and F. Chen, “Defect classification in wafer inspection through k-nearest neighbors,” Optimizations in Applied Machine Learning, vol. 3, no. 3, pp. 1–23, 2023.
📄 Y. Liang, L. Guo, H. Gao, Z. You, and Y. Ye, “Machine vision-based condition monitoring and fault diagnosis,” Mechanical Systems and Signal Processing, vol. 164, 108217, 2022.
📄 Q. Liu and C. Liu, “A novel locally linear k-NN method with applications to visual recognition,” IEEE Transactions on Neural Networks and Learning Systems, pp. 2010–2021, 2017.
📄 M. M. Mijwil1, I. Adamopoulos, and P. Pudasaini, “Machine learning helps in quickly diagnosis cases of ‘New Corona’,” Mesopotamian Journal of Artificial Intelligence in Healthcare, vol. 2024, pp. 16–19, 2024.
📄 T. Papananias, T. E. McLeay, O. Obajemu, and M. Mahfouf, “Inspection by exception: A new machine learning-based approach for multistage manufacturing,” Applied Soft Computing, vol. 97, 106774, 2020.
📄 M. M. Rosli, A. Rachini, and M. K. Mahmood, “Data-driven melt pool monitoring and defect prediction in LPBF of Ti-6Al-4V alloy,” Babylonian Journal of Mechanical Engineering, pp. 51–67, 2025.
📄 P. K. Syriopoulos, N. G. Kalampalikis, and S. B. Kotsiantis, “k-NN Classification: A review,” Annals of Mathematics and Artificial Intelligence, vol. 9, pp. 1–12, 2023.
📄 K. Xu, S. Liu, and Y. Ai, “Application of shearlet transform to classification of surface defects for metals,” Image and Vision Computing, vol. 35, pp. 23–30, 2015.
📄 L. Yu, X. Chen, and Y. Yang, “The stamping process simulation of plate using CAE technology,” Advanced Materials Research, pp. 538–541, 2012.

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