自动空洞检测tsv从2D x射线扫描使用监督学习与3D x射线扫描

R. Pahwa, S. Gopalakrishnan, Huang Su, Ong Ee Ping, Haiwen Dai, D. Wee, Ren Qin, V. S. Rao
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引用次数: 3

摘要

良率的提高是半导体制造的关键组成部分。它是通过收集、分析、确定缺陷的原因,然后提出解决根本原因的实际解决方案来完成的。半导体元件,如硅通孔(tsv)和其他封装互连正变得越来越小,随着工业的不断小型化的进展。在这些隐藏的互连中检测缺陷变得越来越困难和重要。我们收集含有缺陷(如空洞)的缺陷tsv的二维和三维x射线扫描。我们在3D中标记数据,并在2D和3D扫描之间进行配准。我们使用这些配准信息来定位这些二维x射线扫描中的tsv和空洞缺陷,这些缺陷很难手工标记,因为这些空洞在二维扫描中看起来非常模糊。然后,我们使用最先进的深度学习分割网络来训练模型,以从背景中识别前景(TSV,空洞缺陷)。我们表明,我们的模型可以准确地识别图像中不可能手动定位缺陷的tsv及其空洞。我们报告了TSV分割的骰子得分为0.87,空洞检测的骰子得分为0.67。空洞的骰子分数证明了我们的模型在2D中直接检测这些困难的隐藏缺陷的能力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Automated Void Detection in TSVs from 2D X-Ray Scans using Supervised Learning with 3D X-Ray Scans
Yield improvement is a critical component of semiconductor manufacturing. It is done by collecting, analyzing, identifying the causes of defects, and then coming up with a practical solution to resolve the root causes. Semiconductor components such as Through Silicon Vias (TSVs) and other package interconnects are getting smaller and smaller with the ongoing miniaturization progress in the industry. Detecting defects in these buried interconnects is becoming both more difficult and more important. We collect both 2D and 3D X-Ray scans of defective TSVs containing defects such as voids. We label the data in 3D and perform registration between 2D and 3D scans. We use this registration information to locate the TSVs and void defects in these 2D X-ray scans which would be difficult to label manually as these voids look very fuzzy in 2D scans. Thereafter we use a state-of-the-art deep-learning segmentation network to train models to identify foreground (TSV, void defects) from the background. We show that our model can accurately identify the TSVs and their voids in images where it is impossible to locate the defects manually. We report a dice score of 0.87 for TSV segmentation and a dice score of 0.67 for void detection. The dice score for voids demonstrates the capability of our models to detect these difficult buried defects in 2D directly.
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