TY - GEN
T1 - Enhancing Good-Die-in-Bad-Neighborhood Methodology with Wafer-Level Defect Pattern Information
AU - Liu, Ching Min
AU - Yen, Chia Heng
AU - Lee, Shu Wen
AU - Wu, Kai Chiang
AU - Chao, Mango Chia Tso
N1 - Publisher Copyright:
© 2023 IEEE.
PY - 2023
Y1 - 2023
N2 - In semiconductor manufacturing processes, there are several causes of typical defects in silicon wafers, such as operational flaws or equipment malfunctions, which may lead to circuit failure and defective products. Therefore, testing is instrumental in improving overall yield and reliability. GDBN (good die in bad neighborhood) is a widely-used technique of rejecting potentially defective wafers in advance based on the concept that defects tend to cluster together. However, previous studies related to GDBN are limited to a local observation by using a narrow-sighted window and thus ignore the defects patterns of the wafers. In this paper, by leveraging information of wafer defect patterns and extending the observation range to the entire wafer, we strengthen the GDBN method to recognize the potentially defective dice more effectively based on the feature of the different defect patterns. The method proposed in this paper is realized by convolutional neural network technology, and it is also the first method to consider defect patterns of wafers as features to solve the problem of GDBN. Several experiments are conducted on a real-world WM-811K dataset, and the results show that our proposed method not only reduce the cost of return merchandise authorization (RMA) but the DPPM (Defective Parts Per Million) more significantly over other existing methods.
AB - In semiconductor manufacturing processes, there are several causes of typical defects in silicon wafers, such as operational flaws or equipment malfunctions, which may lead to circuit failure and defective products. Therefore, testing is instrumental in improving overall yield and reliability. GDBN (good die in bad neighborhood) is a widely-used technique of rejecting potentially defective wafers in advance based on the concept that defects tend to cluster together. However, previous studies related to GDBN are limited to a local observation by using a narrow-sighted window and thus ignore the defects patterns of the wafers. In this paper, by leveraging information of wafer defect patterns and extending the observation range to the entire wafer, we strengthen the GDBN method to recognize the potentially defective dice more effectively based on the feature of the different defect patterns. The method proposed in this paper is realized by convolutional neural network technology, and it is also the first method to consider defect patterns of wafers as features to solve the problem of GDBN. Several experiments are conducted on a real-world WM-811K dataset, and the results show that our proposed method not only reduce the cost of return merchandise authorization (RMA) but the DPPM (Defective Parts Per Million) more significantly over other existing methods.
UR - http://www.scopus.com/inward/record.url?scp=85182602176&partnerID=8YFLogxK
U2 - 10.1109/ITC51656.2023.00053
DO - 10.1109/ITC51656.2023.00053
M3 - Conference contribution
AN - SCOPUS:85182602176
T3 - Proceedings - International Test Conference
SP - 357
EP - 366
BT - Proceedings - 2023 IEEE International Test Conference, ITC 2023
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 2023 IEEE International Test Conference, ITC 2023
Y2 - 7 October 2023 through 15 October 2023
ER -