Artigo em revista científica Q1
Graph-based contrastive learning for self-supervised semiconductor wafer defect detection
Muhammad Awais (Awais, M.); Octavian Postolache (Postolache, O. A.); Sancho Moura Oliveira (Oliveira, S. M.);
Título Revista
Journal of Intelligent Manufacturing
Ano (publicação definitiva)
N/A
Língua
Inglês
País
Reino Unido
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Abstract/Resumo
Semiconductor wafer defect detection faces a critical challenge: traditional supervised methods require extensive labeled datasets that are costly to obtain. This paper presents a novel self-supervised approach combining Graph Neural Networks (GNNs) with contrastive learning for defect detection that minimizes reliance on labeled training data. Our method introduces a theoretically-grounded graph construction using 8-connectivity patterns that preserves spatial locality, with edge weights capturing geometric and semantic relationships. The core innovation is a multi-criteria contrastive learning framework incorporating spatial pattern similarity, defect density proximity, and production lot relationships to define positive-negative pairs using domain-driven heuristics rather than manual annotations. We implement this using a Graph Isomorphism Network (GIN) with jumping knowledge connections for multi-scale defect patterns. Evaluation on the WM-811K dataset (811,457 wafer maps from 46,293 lots) demonstrates that unsupervised clustering on learned embeddings achieves ARI of 0.89 and NMI of 0.87, while supervised fine-tuning on these embeddings yields 98.6% classification accuracy (ARI 0.98, NMI 0.96), maintaining 95.7% accuracy with only 25% labeled data. Our approach handles class imbalance (91.5% normal vs. 8.5% defective) across 9 defect patterns. Deployment analysis shows 8.3ms inference time, 387MB memory footprint, and 78% cost reduction versus manual inspection, with robustness to sensor noise and an 89.3% out-of-distribution detection rate. This provides the first contrastive learning-GNN application for wafer defect detection, offering scalable industrial quality control where labeled data is scarce.
Agradecimentos/Acknowledgements
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Palavras-chave
Self-supervised learning,Wafer defect detection,Contrastive learning,Graph neural networks,Clustering,Semiconductor manufacturing
  • Engenharia Eletrotécnica, Eletrónica e Informática - Engenharia e Tecnologia
Registos de financiamentos
Referência de financiamento Entidade Financiadora
UID/50008: Instituto de Telecomunicações Fundação para a Ciência e a Tecnologia