Abstract
Generic object detection algorithms for natural images have been proven to have excellent performance. In this paper, fabric defect detection on optical image datasets is systematically studied. In contrast to generic datasets, defect images are multi-scale, noise-filled, and blurred. Back-light intensity would also be sensitive for visual perception. Large-scale fabric defect datasets are collected, selected, and employed to fulfill the requirements of detection in industrial practice in order to address these imbalanced issues. An improved two-stage defect detector is constructed for achieving better generalization. Stacked feature pyramid networks are set up to aggregate cross-scale defect patterns on interpolating mixed depth-wise block in stage one. By sharing feature maps, center-ness and shape branches merges cascaded modules with deformable convolution to filter and refine the proposed guided anchors. After balanced sampling, the proposals are down-sampled by position-sensitive pooling for region of interest, in order to characterize interactions among fabric defect images in stage two. The experiments show that the end-to-end architecture improves the occluded defect performance of region-based object detectors as compared with the current detectors.
Highlights
Industrial defect detection is important in manufacturing
Fabric defect control is the main content of quality control in the textile industry, which would significantly increase the additional processing costs of the fabric
This paper proposes large-scale optical fabric images, which is named as Fabric only in the production stage, and in transportation, sorting, and even cutting
Summary
Industrial defect detection is important in manufacturing. Fabric defect control is the main content of quality control in the textile industry, which would significantly increase the additional processing costs of the fabric. The cost is derived from manual positioning and the detection of defects and suspending to remove them. Manual quality inspections are inefficient and they must often be seen under good backlighting. There is no quantitative defect classification indicator or boundary. This can result in false or mis-detection, and it is not conducive to the late repair of defects or the removal of defects before they occur
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