Battery Surface and Edge Defect Inspection Based on Sub-Regional Gaussian and Moving Average Filter

Detecting the defects of a battery on the surface and edge has always been difficult, especially for concave and convex ones, thereby seriously affecting its quality. Thus, sub-regional Gaussian and moving average filtering are innovatively proposed in this study considering the effect of the nonuni...

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Bibliographic Details
Published in:Applied sciences 2019-08, Vol.9 (16), p.3418
Main Authors: Hu, Haibing, Zhang, Bo, Xu, Dongjian, Xia, Guo
Format: Article
Language:English
Subjects:
Accuracy
Algorithms
battery defects
Cameras
Defects
Filtration
Gaussian filter
Industrial production
Inspection
Light emitting diodes
moving average filter
Noise
real-time performance
sub-regional
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Summary:Detecting the defects of a battery on the surface and edge has always been difficult, especially for concave and convex ones, thereby seriously affecting its quality. Thus, sub-regional Gaussian and moving average filtering are innovatively proposed in this study considering the effect of the nonuniform background illumination of the battery edge and the difference between the edge background and the internal surface defects of the battery. The battery surface image is divided into two areas, namely, edge area W 1 and inner area W 2 . Gaussian and moving average filtering are carried out row-by-row and column-by-column in the inner area W 2 and the edge area W 1 , respectively. The algorithm is tested on 600 battery samples that mainly possess concave and convex defects. The proposed method has higher detection accuracy and lower omission detection rate than the traditional unpartitioned processing method, especially in detecting the accuracy of edge defects. The accuracy rates were approximately 20% higher than that obtained by the traditional processing algorithm. The proposed method has remarkable real-time performance that can process four 8192 Ă— 10,240 pixel battery images per second, thereby meeting the industrial production line speed requirements while satisfying accuracy. The proposed method has been applied in actual production for defect inspection.
ISSN:2076-3417
2076-3417
DOI:10.3390/app9163418