A PRISMA-driven systematic review of data mining methods used for defects detection and classification in the manufacturing industry

Bártová, Blanka; Bína, Vladislav; Váchová, Lucie

doi:10.1590/0103-6513.20210097

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Systematic Review • Prod. 32 • 2022 • https://doi.org/10.1590/0103-6513.20210097 copy

A PRISMA-driven systematic review of data mining methods used for defects detection and classification in the manufacturing industry

Authorship SCIMAGO INSTITUTIONS RANKINGS

Abstract

Paper aims

This research aims to analyze the primary studies published in recent years focusing on defect detection or classification in manufacturing and extract information about frequently used data mining (DM) methods, their accuracy, strengths, and limitations.

Originality

Industrial production is now undergoing a dynamic transformation in the context of Industry 4.0, where implementation of data mining is a frequently discussed topic, and such an overall summary is missing.

Research method

In this study, the PRISMA-driven systematic literature review is combined with the approach defined by Kitchenham (2004).

Main findings

The most frequently used data mining methods for defect detection are Bayesian network (BN) and Support vector machine (SVM). Besides previously mentioned methods, the Decision trees (DT) and Clustering are often used for defect classification. Neural Networks (NN) use is common for both defect detection and classification. DT, together with the Genetic algorithm (GA) and SVM, achieved the highest average accuracy. Recently, authors often combine different DM methods, and also methods for data dimensionality reduction are often used.

Implications for theory and practice

This study contributes to the quality management literature by extending a summary of recently used DM methods for defect detection and classification. This summary can help researchers choose a suitable method and build models for achieving its research purpose.

Keywords
Data mining; Defect; Detection; Classification; Manufacturing

Question ID	Research Question
RQ1	Which are the most frequently used DM methods for defect detection and classification in the manufacturing process?
RQ2	Which DM methods are the most efficient for defect classification/detection according to the chosen criteria?
RQ3	Do authors combine different DM methods for quality management tasks in manufacturing?
RQ4	Do authors use some dimensionality reduction methods for efficient work with high-volume data?
RQ5	What are the main strength and limitations of individual DM methods?

Item ID	Database Search Terms
a	data mining
b	defect
c	detection
d	classification
e	data mining method

Source	Address
Scopus	Scopus (2021)Scopus. (2021). Retrieved in 12 March 2021, from http://www.scopus.com/. http://www.scopus.com/...
ISI Web of Science	Web of Science (2021)Web of Science. (2021). Retrieved in 15 March 2021, from http://isiknowledge.com/. http://isiknowledge.com/...
ProQuest central	ProQuest (2021)ProQuest. (2021). Retrieved in 14 March 2021, from https://www.proquest.com/. https://www.proquest.com/...

Query	Results
Query	Scopus	WoS	ProQuest
(“neural network”) AND (“defect”) AND (“detection) OR (“classification”) AND (“manufacturing”)	498	605	23545
(“support vector machine”) AND (“defect”) AND (“detection”) OR (“classification”) AND (“manufacturing”)	137	179	20574
(“baies network”) AND (“defect”) AND (“detection) OR (“classification”) AND (“manufacturing”)	5	5	4450
(“decision trees”) AND (“defect”) AND (“detection) OR (“classification”) AND (“manufacturing”)	67	45	33910
(“rough set theory”) AND (“defect”) AND (“detection) OR (“classification”) AND (“manufacturing”)	7	5	24605
(“genetic algorithm”) AND (“defect”) AND (“detection) OR (“classification”) AND (“manufacturing”)	48	53	15625
(“association”) AND (“defect”) AND (“detection) OR (“classification”) AND (“manufacturing”)	7	8	61043
(“clustering”) AND (“defect”) AND (“detection) OR (“classification”) AND (“manufacturing”)	84	179	17279
(“regression”) AND (“defect”) AND (“detection) OR (“classification”) AND (“manufacturing”)	70	112	23922

Question ID	Question	Percentage
Question ID	Question	Yes	Partially	No
Design
Q1	Are the aims of the study clearly stated?	68.85	29.51	1.64
Q2	Are the chosen quality attributes distinctly defined?	55.74	24.59	19.67
Q3	Are the used DM methods discussed?	36.07	45.90	18.03
Conduct
Q4	Is the used approach clearly described?	75.41	24.59	0.00
Q5	Are the datasets completely described (source. size. and programming languages)?	29.51	29.51	40.98
Q6	Is it clear how accuracy was measured?	57.38	11.48	31.15
Analysis
Q7	Is the purpose of the analysis clear?	73.77	26.23	0.00
Q8	Were all model construction methods fully defined (use of tools and methods)?	44.26	50.82	4.92
Q9	Is the accuracy of the results reported?	98.36	1.64	0.00
Conclusion
Q10	Are the results compared with other methods?	60.66	14.75	24.59
Q11	Do the results support the conclusions?	62.30	37.70	0.00
Q12	Are validity threats discussed?	21.31	29.51	49.18

Item ID	Extracted data	Description	Type
1	Authors	Research author’s other relevant studies	Whole research
2	Publication year	Indicating the trend of research	Whole research
3	Study title	Reflect the relevant research direction	Whole research
4	Context study	Understand the full text	Whole research
5	DM method or combinations	Methods used in the model	RQ1, RQ2
6	Achieved accuracy	The effectiveness of the methods	RQ2, RQ3
7	Method strengths	The advantages of the approach	RQ5
8	Method limitation	The disadvantages of the approach	RQ5
9	Dimensionality reduction	Method used for dimensionality reduction	RQ4

Method	Number of studies	Used in Combination	Detection/ Classification	Strengths	Limitations	Average accuracy	Field of Application	Reference
Association	1	NO	100% Classification	- Counting transparency	- Depend on the human factor	100% Confidence	- Garment industry	- Lee et al. (2013)Lee, C. K. H., Choy, K. L., Ho, G. T. S., Chin, K. S., Law, K. M. Y., & Tse, Y. K. (2013). A hybrid OLAP-association rule mining based quality management system for extracting defect patterns in the garment industry. Expert Systems with Applications, 40(7), 2435-2446. http://dx.doi.org/10.1016/j.eswa.2012.10.057. http://dx.doi.org/10.1016/j.eswa.2012.10...
					- Too many generated combinations
					- Long run time
Bayes network	2	NO	100% Detection	- High robustness	- Low interpretability	94.31%	- Textile manufacturing	- Romli et al. (2021)Romli, I., Pardamean, T., Butsianto, S., Wiyatno, T. N., & Mohamad, E. (2021). Naive bayes algorithm implementation based on particle swarm optimization in analyzing the defect product. Journal of Physics: Conference Series, 1845(1), 012020. http://dx.doi.org/10.1088/1742-6596/1845/1/012020. http://dx.doi.org/10.1088/1742-6596/1845...
				- Simple to implement	- Low learning ability			- Yapi et al. (2017)Yapi, D., Allili, M. S., & Baaziz, N. (2017). Automatic fabric defect detection using learning-based local textural distributions in the contourlet domain. IEEE Transactions on Automation Science and Engineering, 15(3), 1017-1026.
				- Great computational efficiency	- Long run time
					- Requires a vast number of records
Clustering	5	YES	60% Classification/ Pattern recognition	- Well suited for multimodal classes	- Location solution	92.55%	- Semiconductor manufacturing	- Taha et al. (2018)Taha, K., Salah, K., & Yoo, P. D. (2018). Clustering the dominant defective patterns in semiconductor wafer maps. IEEE Transactions on Semiconductor Manufacturing, 31(1), 156-165. http://dx.doi.org/10.1109/TSM.2017.2768323. http://dx.doi.org/10.1109/TSM.2017.27683...
			40% Detection	- Zero costs of the learning process	- Sensitive to noisy or irrelevant attributes		- IC manufacturing	- Hsu (2015)Hsu, C.-Y. (2015). Clustering ensemble for identifying defective wafer bin map in semiconductor manufacturing. Mathematical Problems in Engineering, 2015, 1-11. http://dx.doi.org/10.1155/2015/707358. http://dx.doi.org/10.1155/2015/707358...
					- Performance of the algorithm depends on the number of dimensions used			- Ooi et al. (2013)Ooi, M., Sok, H. K., Kuang, Y. C., Demidenko, S., & Chan, C. (2013). Defect cluster recognition system for fabricated semiconductor wafers. Engineering Applications of Artificial Intelligence, 26(3), 1029-1043. http://dx.doi.org/10.1016/j.engappai.2012.03.016. http://dx.doi.org/10.1016/j.engappai.201...
								- Yuan et al. (2011)Yuan, T., Kuo, W., & Bae, S. J. (2011). Detection of spatial defect patterns generated in semiconductor fabrication processes. IEEE Transactions on Semiconductor Manufacturing, 24(3), 24. http://dx.doi.org/10.1109/TSM.2011.2154870. http://dx.doi.org/10.1109/TSM.2011.21548...
								- Yuan et al. (2010)Yuan, T., Bae, S. J., & Park, J. I. (2010). Bayesian spatial defect pattern recognition in semiconductor fabrication using support vector clustering. International Journal of Advanced Manufacturing Technology, 51(5-8), 671-683. http://dx.doi.org/10.1007/s00170-010-2647-x. http://dx.doi.org/10.1007/s00170-010-264...
Decision trees	3	YES	100% Classification/ Pattern recognition	- High Interpretability	- Low robustness	98.50%	- Steel parts manufacturing	- Chien et al. (2020)Chien, J., Wu, M., & Lee, J. (2020). Inspection and classification of semiconductor wafer surface defects using CNN deep learning networks. Applied Sciences, 10(15), 5340. http://dx.doi.org/10.3390/app10155340. http://dx.doi.org/10.3390/app10155340...
				- Fast training	- Low learning ability		- Semiconductor manufacturing	- Mao et al. (2018)Mao, Q., Ma, H., Zhang, X., & Zhang, G. (2018). An improved skewness decision tree svm algorithm for the classification of steel cord conveyor belt defects. Applied Sciences, 8(12), 2574. http://dx.doi.org/10.3390/app8122574. http://dx.doi.org/10.3390/app8122574...
				- Easy to understand				- Radhika et al. (2013)Radhika, N., Senapathi, S. B., Subramaniam, R., Subramany, R., & Vishnu, K. N. (2013). Pattern recognition based surface roughness prediction in turning hybrid metal matrix composite using random forest algorithm. Industrial Lubrication and Tribology, 65(5), 311-319. http://dx.doi.org/10.1108/ILT-02-2011-0015. http://dx.doi.org/10.1108/ILT-02-2011-00...
				- High accuracy
				- Proper handling of missing values
				- Robustness to outliers in input space
Genetic algorithm	2	YES	100% Classification	- Superior classification performance	- Time-consuming iterations	97.50%	- Steel parts manufacturing	- Song et al. (2019)Song, J., Kim, Y., & Park, T. (2019). SMT defect classification by feature extraction region optimization and machine learning. International Journal of Advanced Manufacturing Technology, 101(5-8), 1303-1313. http://dx.doi.org/10.1007/s00170-018-3022-6. http://dx.doi.org/10.1007/s00170-018-302...
				- Good compatibility with other methods	- No global optimum		- PCB manufacturing
								- Chondronasios et al. (2016)Chondronasios, A., Popov, I., & Jordanov, I. (2016). Feature selection for surface defect classification of extruded aluminum profiles. International Journal of Advanced Manufacturing Technology, 83(1-4), 33-41. http://dx.doi.org/10.1007/s00170-015-7514-3. http://dx.doi.org/10.1007/s00170-015-751...

Neural network	38	NO	18% Classification	- High robustness	- Low interpretability	93.47%	- Automotive industry	- Jeong et al. (2021)Jeong, E., Kim, J., Jang, W., Lim, H., Noh, H., & Choi, J. (2021). A more reliable defect detection and performance improvement method for panel inspection based on artificial intelligence. Journal of Information Display, 22(3), 127-136. http://dx.doi.org/10.1080/15980316.2021.1876174. http://dx.doi.org/10.1080/15980316.2021....
			82% Detection	- High accuracy	- Time inefficiency		- Steel parts manufacturing	- Zhu et al. (2021)Zhu, Y., Yang, R., He, Y., Ma, J., Guo, H., Yang, Y., & Zhang, L. (2021). A Lightweight multiscale attention semantic segmentation algorithm for detecting laser welding defects on safety vent of power battery. IEEE Access : Practical Innovations, Open Solutions, 9, 39245-39254. http://dx.doi.org/10.1109/ACCESS.2021.3064180. http://dx.doi.org/10.1109/ACCESS.2021.30...
				- Fault tolerance	- Lack of explanatory power		- Semiconductor manufacturing	- Zhao et al. (2020b) Zhao, S., Yin, L., Zhang, J., Wang, J., & Zhong, R. (2020b). Real-time fabric defect detection based onmulti-scale convolutional neural network. IET Collaborative Intelligent Manufacturing, 2(4), 189-196. http://dx.doi.org/10.1049/iet-cim.2020.0062. http://dx.doi.org/10.1049/iet-cim.2020.0...
				- Versatility of use	- Not easy to understand		- Concrete products	- Huang et al. (2020)Huang, Y., Qiu, C., Wang, X., Wang, S., & Yuan, K. (2020). A compact convolutional neural network for surface defect inspection. Sensors, 20(7), 1974. http://dx.doi.org/10.3390/s20071974. PMid:32244764. http://dx.doi.org/10.3390/s20071974...
				- Able to handle noisy data	- Approximation errors		- PCB manufacturing	- Chen et al. (2020b) Chen, X., Chen, J., Han, X., Zhao, C., Zhang, D., Zhu, K., & Su, Y. (2020b). A light-weighted CNN model for wafer structural defect detection. IEEE Access: Practical Innovations, Open Solutions, 8, 24006-24018. http://dx.doi.org/10.1109/ACCESS.2020.2970461. http://dx.doi.org/10.1109/ACCESS.2020.29...
					- Slow learning		- IC manufacturing	- Shin et al. (2020)Shin, S., Jin, C., Yu, J., & Rhee, S. (2020). Real-time detection of weld defects for automated welding process base on deep neural network. Metals, 10(3), 389. http://dx.doi.org/10.3390/met10030389. http://dx.doi.org/10.3390/met10030389...
					- Over-fitting		- Textile manufacturing	- Shi et al. (2020b)Shi, W., Zhang, L., Li, Y., & Liu, H. (2020b). Adversarial semi-supervised learning method for printed circuit board unknown defect detection. Journal of Engineering, 2020(13), 505-510. http://dx.doi.org/10.1049/joe.2019.1181. http://dx.doi.org/10.1049/joe.2019.1181...
					- Local minima			- Ma et al. (2019)Ma, L., Xie, W., & Zhang, Y. (2019). Blister defect detection based on convolutional neural network for polymer lithium-ion battery. Applied Sciences, 9(6), 1085. http://dx.doi.org/10.3390/app9061085. http://dx.doi.org/10.3390/app9061085...
								- Mei et al. (2018)Mei, S., Wang, Y., & Wen, G. (2018). Automatic fabric defect detection with a multi-scale convolutional denoising autoencoder network model. Sensors, 18(4), 1064. http://dx.doi.org/10.3390/s18041064. PMid:29614813. http://dx.doi.org/10.3390/s18041064...
								- Kholief et al. (2017)Kholief, E. A., Darwish, S. H., & Fors, M. N. (2017). Detection of steel surface defect based on machine learning using deep auto-encoder network. In Proceedings of the International Conference on Industrial Engineering and Operations Management. Rabat, Morocco, IEOM.
								- Etc.
Regression	1	YES	100% Detection	- Good computation speed	- Approximation errors	91.30%	- Automotive industry	- Jiang et al. (2014)Jiang, Y., Wu, J., & Zong, C. (2014). An effective diagnosis method for single and multiple defects detection in gearbox based on nonlinear feature selection and kernel-based extreme learning machine. Journal of Vibroengineering, 16(1), 499-512.
				- Low false alarm rate	- Poor parameter estimates due to data sparsity, overfitting, missing or incomplete data
				- Easy to interpret
Support Vector Machine	9	YES	33% Classification	- High classification accuracy	- Low interpretability	95.66%	- Automotive industry	- Hoang & Nguyen (2020)Hoang, N., & Nguyen, Q. (2020). A novel approach for automatic detection of concrete surface voids using image texture analysis and history-based adaptive differential evolution optimized support vector machine. Advances in Civil Engineering, 2020, 1-15. http://dx.doi.org/10.1155/2020/4190682. http://dx.doi.org/10.1155/2020/4190682...
		- GA-SVM	67% Detection	- High robustness	- High complexity		- Semiconductor manufacturing	- Bumrungkun (2019)Bumrungkun, P. (2019). Defect detection in textile fabrics with snake active contour and support vector machines. Journal of Physics: Conference Series, 1195, 012006. http://dx.doi.org/10.1088/1742-6596/1195/1/012006. http://dx.doi.org/10.1088/1742-6596/1195...
		- DT-SVM		- Generalization ability			- Concrete products	- Jingzhong et al. (2018)Jingzhong, H., Kewen, X., Fan, Y., & Baokai, Z. (2018). Strip steel surface defects recognition based on socp optimized multiple kernel RVM. Mathematical Problems in Engineering, 2018, 1-8. http://dx.doi.org/10.1155/2018/9298017. http://dx.doi.org/10.1155/2018/9298017...
		- CNN-SVM		- Stability			- PCB manufacturing	- Takada et al. (2017)Takada, Y., Shiina, T., Usami, H., Iwahori, Y., & Bhuyan, M. K. (2017). Defect detection and classification of electronic circuit boards using keypoint extraction and CNN features. In The Ninth International Conferences on Pervasive Patterns and Applications. Athens, Greece: Iaria.
				- Ability to extract a linear combination of features				- Wang et al. (2015)Wang, L., Törngren, M., & Onori, M. (2015). Current status and advancement of cyber-physical systems in manufacturing. Journal of Manufacturing Systems, 37(2), 517-527. http://dx.doi.org/10.1016/j.jmsy.2015.04.008. http://dx.doi.org/10.1016/j.jmsy.2015.04...
				- Predictive power				- Etc.

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[1] *blanka.bartova@vse.cz, **vladislav.bina@vse.cz, ***lucie.vachova@vse.cz