Abstract
The surface quality of aluminum ingot is crucial for subsequent products, so it is necessary to adaptively detect different types of defects in milled aluminum ingots surfaces. In order to quickly apply the calculations to a real production line, a novel two-stage detection approach is proposed. Firstly, we proposed a novel mask gradient response-based threshold segmentation (MGRTS) in which the mask gradient response is the gradient map after the strong gradient has been eliminated by the binary mask, so that the various defects can be effectively extracted from the mask gradient response map by iterative threshold segmentation. In the region of interest (ROI) extraction, we combine the MGRTS and the Difference of Gaussian (DoG) to effectively improve the detection rate. In the aspect of the defect classification, we train the inception-v3 network with a data augmentation technology and the focal loss in order to overcome the class imbalance problem and improve the classification accuracy. The comparative study shows that the proposed method is efficient and robust for detecting various defects on an aluminum ingot surface with complex milling grain. In addition, it has been applied to the actual production line of an aluminum ingot milling machine, which satisfies the requirement of accuracy and real time very well.
Highlights
Surface defect detection is a critical step of the metal industry
It can be seen that the combination of mask gradient response-based threshold segmentation (MGRTS) and Difference of Gaussian (DoG) boosts the region of interest (ROI) extraction performance, especially the recall rate, which is more important to the production line
Failure cases of of ourour method: observation, we we increased the contrast by 20%); (b) False positives of Pitted slag inclusion (PSI); (c) False negatives; (b) False positives of PSI; (c) False negatives of box) of PSI; (d) Incomplete detection of PSI; (d) Incomplete detection of Oxide film (OF)
Summary
Since the technologies under development are becoming more and more feasible, and the results are reliable enough for a decision, the optical non-destructive testing (ONDT) has gained more and more attention in this filed. This is mainly due to the development of the used tools: laser, cameras, and those faster computers that are capable of processing large amounts of encrypted data in optical measurements [1]. Both the statistical statistical andand structural textures appear as placement rules, as in
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