基於多尺度注意力、可變形卷積與深度可分離卷積的晶圓缺陷辨識模型;An Integrated Model for Wafer Defect Pattern Recognition Based on Multi-Scale Attention ,Deformable Convolution and Depth-wise Separable Convolution

NCUIR > School of Management at National Central University > Graduate Institute of Industrial Management > Electronic Thesis & Dissertation > Item 987654321/94553

Please use this identifier to cite or link to this item: http://ir.lib.ncu.edu.tw/handle/987654321/94553

Title:	基於多尺度注意力、可變形卷積與深度可分離卷積的晶圓缺陷辨識模型;An Integrated Model for Wafer Defect Pattern Recognition Based on Multi-Scale Attention ,Deformable Convolution and Depth-wise Separable Convolution
Authors:	王兆玄;Wang, Jhao-Syuan
Contributors:	工業管理研究所
Keywords:	晶圓缺陷辨識;卷積神經網路;注意力機制;wafer defect recognition;multi-scale attention;convolution neural network
Date:	2024-07-16
Issue Date:	2024-10-09 15:15:35 (UTC+8)
Publisher:	國立中央大學
Abstract:	本研究針對半導體製造中晶圓缺陷檢測這一關鍵問題展開探討。隨著電路積體密度的增加和晶圓設計複雜性的增加，晶圓缺陷變得更加普遍。每個晶圓缺陷的發生都是源於某些製造流程的特定異常行為，一套識別晶圓缺陷的系統，有助於發現半導體製造中的異常製程並採取相應措施加以解決。在半導體製造流程中，準確檢測並識別晶圓上的各種缺陷至關重要，但傳統基於卷積神經網絡（CNN）的方法存在一些固有的缺陷，例如高計算量、過擬合和對特定型態缺陷的處理不足。因此，本研究旨在提出一種新型的卷積神經網絡，將深度可分離卷積、多尺度注意力和可變形卷積等技術結合，以提升模型效率、改善缺陷處理能力並增強模型泛化能力。透過這些方法的綜合應用，我們期望能夠有效解決晶圓缺陷檢測中的挑戰，提高檢測準確性和效率，從而促進半導體製造流程的持續優化與提升。;This study focuses on the crucial issue of wafer defect detection in semiconductor manufacturing. With the increase in circuit integration density and the complexity of wafer design, wafer defects have become more prevalent. Each wafer defect originates from specific abnormal behaviors in the manufacturing process. Accurate detection and identification of various defects on wafers are essential in semiconductor manufacturing. However, traditional convolutional neural network (CNN)-based methods suffer from inherent drawbacks such as high computational complexity, overfitting, and inadequate handling of specific types of defects. Therefore, this study aims to propose a novel convolutional neural network that integrates techniques such as depth-wise separable convolution, multi-scale attention, and deformable convolution to improve model efficiency, enhance defect processing capabilities, and strengthen model generalization ability. Through the comprehensive application of these methods, we expect to effectively address the challenges in wafer defect detection, enhance detection accuracy and efficiency, and promote continuous optimization and improvement of semiconductor manufacturing processes.
Appears in Collections:	[Graduate Institute of Industrial Management] Electronic Thesis & Dissertation

Files in This Item:

File	Description	Size	Format
index.html		0Kb	HTML	10	View/Open

社群 sharing

Loading...