Surface defects generated during laser-arc hybrid welding of dissimilar Al-steel joints act as critical fatigue crack initiators, yet process qualification often relies on subjective inspection and trial-intensive parameter exploration. This study presents an end-to-end framework that converts in-line weld-surface imaging into quantitative, fatigue-relevant quality guidance for laser-leading hybrid welding of AA6061-T6/DP590. Distance-triggered imaging with controlled illumination, pixel-to-mm calibration, and flat-field normalization ensures stable acquisition. A U-Net segmentation model achieves robust performance with Intersection over Union (IoU) of 0.92/0.89/0.88 (train/validation/test) and test-set AUPRC of 0.91. Post-processing enables instance-level defect quantification, and multiple descriptors are integrated into a Defect Severity Index (DSI) exhibiting high repeatability (DSI CV 0.60) demonstrates systematically longer life at lower DSI, establishing a deployable accept/monitor/rework decision framework that links surface quality directly to lifecycle performance.
Zhiheng Xu (Wed,) studied this question.
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