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- Title
Control chart pattern recognition using the convolutional neural network.
- Authors
Zan, Tao; Liu, Zhihao; Wang, Hui; Wang, Min; Gao, Xiangsheng
- Abstract
Unnatural control chart patterns (CCPs) usually correspond to the specific factors in a manufacturing process, so the control charts have become important means of the statistical process control. Therefore, an accurate and automatic control chart pattern recognition (CCPR) is of great significance for manufacturing enterprises. In order to improve the CCPR accuracy, experts have designed various complex features, which undoubtedly increases the workload and difficulty of the quality control. To solve these problems, a CCPR method based on a one-dimensional convolutional neural network (1D-CNN) is proposed. The proposed method does not require to extract complex features manually; instead, it uses a 1D-CNN to obtain the optimal feature set from the raw data of the CCPs through the feature learning and completes the CCPR. The dataset for training and validation, containing six typical CCPs, is generated by the Monte-Carlo simulation. Then, the influence of the network structural parameters and activation functions on the recognition performance is analyzed and discussed, and some suggestions for parameter selection are given. Finally, the performance of the proposed method is compared with that of the traditional multi-layer perceptron method using the same dataset. The comparison results show that the proposed 1D-CNN method has obvious advantages in the CCPR tasks. Compared with the related literature, the features extracted by the 1D-CNN are of higher quality. Furthermore, the 1D-CNN trained with simulation dataset still perform well in recognizing the real dataset from the production environment.
- Subjects
ARTIFICIAL neural networks; QUALITY control charts; PATTERN recognition systems; STATISTICAL process control; QUALITY control
- Publication
Journal of Intelligent Manufacturing, 2020, Vol 31, Issue 3, p703
- ISSN
0956-5515
- Publication type
Article
- DOI
10.1007/s10845-019-01473-0