Journal of Jilin University(Engineering and Technology Edition) ›› 2023, Vol. 53 ›› Issue (5): 1449-1457.doi: 10.13229/j.cnki.jdxbgxb.20210855

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Surface defect detection algorithm of magnetic tiles based on multi⁃branch convolutional neural network

Pei-yong LIU1,2(),Jie DONG1,Luo-feng XIE1,Yang-yang ZHU1,Guo-fu YIN1()   

  1. 1.School of Mechanical Engineering,Sichuan University,Chengdu 610065,China
    2.Chengdu Aeronautic Polytechnic,Chengdu 610100,China
  • Received:2021-08-13 Online:2023-05-01 Published:2023-05-25
  • Contact: Guo-fu YIN E-mail:peiyongliu@126.com;gfyin@scu.edu.cn

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Abstract:

Aiming at the problem of great difficulty and low accuracy in the detection of magnetic tile surface defects(DMTSD), a novel algorithm of DMTSD is proposed. In this paper, a multi-branch network structure is designed, and a convolutional neural network which can effectively extract the features of the magnetic tile images is constructed in each branch, and then the attention module is introduced to highlight the important features of the image. Finally, the correlation of the intra-class features and the difference of the inter-class features is maximized through discriminant correlation analysis, and the optimized fusion feature of magnetic tile images is obtained by concatenation fusion. The performance of the algorithm is tested on the magnetic tile image data set, and the test accuracy is up to 99.90%. In the actual detection work, the detection accuracy of the algorithm remains above 99%, and the detection speed reaches 129 pcs/min. The results of test and operation show that the algorithm has the advantage of high detection accuracy and stable performance, and can meet the requirements of real-time online detection in mass production of magnetic tiles.

Key words: computer application, magnetic tile, defect detection, multi-branch, convolutional neural network, feature fusion

CLC Number: 

  • TP391

Fig.1

Overall structure of the MBIVGG network"

Fig.2

Three dimensional models of typical magnetic tiles"

Fig.3

Schematic diagram of image acquisition for larger radian magnetic tiles"

Fig.4

Performance comparison of four classical CNN for surface defect detection of magnetic tiles"

Table 1

Performance test of four classical CNN in surface defect detection of magnetic tiles"

网络名称训练精度测试精度平均测试 时间t1/s单张图像平均测试时间t2/s最大测试 时间t3/s最大平均 测试时间t4/s检测速度n/(块·min-1
VGG160.99120.9922.930.02933.450.0345217
AlexNet0.98420.9841.990.01992.580.0258290
ResNet180.98920.9892.340.02342.390.0239313
GoogLeNet0.98480.9854.690.04694.780.0478156

Fig.5

Structure of IVGG convolutional neural network"

Fig.6

Training results of IVGG network"

Fig.7

Attention mechanism of CBAM"

Fig.8

Classification of magnetic tiles"

Fig.9

Flexible intelligent detection equipment for magnetic tile surface defects"

Table 2

Sample partition"

数据集线状缺陷块状缺陷正常图像合计
训练集9609609602880
验证集320320320960
测试集320320320960

Fig.10

Training results of MBIVGG network"

Table 3

Comparison of test results(VGG16/MBIVGG)"

实际类别检测结果样品数量
合格线状缺陷块状缺陷
合格289/2997/04/1300
线状缺陷16/3279/2965/1300
块状缺陷9/17/0284/299300
正确拒绝率3.67% / 0.33%
错误接受率6.17% / 0.83%
分类准确率94.67% / 99.33%

Table 4

Comparison of network architecture performance"

支路网络训练精度测试精度
AlexNet0.99290.9927
ResNet180.99590.9956
GoogLeNet0.99370.9938
VGG160.99630.9958
IVGG0.99870.9990

Table 5

Performance comparison with other algorithms"

测试方法准确率/%

FDCT-TA

NSST-EGLG

文献[3

文献[12

本文

92.34

94.27

98.66

93.30

99.62

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