Micro-scale linear guideways require rapid inspection of face-seal gaskets whose defects are minute and low-contrast. High labeling costs and a 20Formula: see texts takt time limit the practicality of fully supervised CNNs. We propose GLASS-FFT-SA, which fuses dual-layer anomaly synthesis with spectrum-efficient convolution and a lightweight spectral attention block to amplify high-frequency cues. Local synthesis inserts defect textures into normal images to create strong anomalies, while global synthesis performs gradient ascent on the feature manifold to generate subtle, near-boundary cases, yielding abundant, diverse training data. Replacing large Formula: see text and Formula: see text spatial kernels in a ResNet-34 backbone with FFT-based convolutions reduces complexity and latency; a gated cross-attention mechanism triggers the pixel branch only when the image head’s anomaly score exceeds a learnable hard-sigmoid gate. Trained on 10,000 normal images and 8000 synthetic anomalies, GLASS-FFT-SA attains image-level AUROC 0.97, pixel-level AUROC 0.96, AUPRO 0.94 and 35 FPS on RTX 3090 — matching the precision of GLASS while running Formula: see text faster. It sustains AUROCs Formula: see text across shifts in product type, illumination and resolution, and outperforms unsupervised baselines under identical preprocessing, input resolution and fixed thresholds. These findings show that spectrum-efficient convolution plus targeted anomaly synthesis yields a favorable accuracy–throughput trade-off for fine-grained defect inspection.
Chen et al. (Tue,) studied this question.
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