Automated Defect Classification In Semiconductor Devices Using Deep Learning Networks

2022 IEEE International Symposium on the Physical and Failure Analysis of Integrated Circuits (IPFA) Pub Date : 2022-07-18 DOI:10.1109/IPFA55383.2022.9915706

A. S. Nair, P. Hoffrogge, P. Czurratis, E. Kuehnicke, Mario Wolf

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引用次数: 2

Abstract

More effective Failure Analysis (FA) technologies are required to meet the upcoming challenges in complex semiconductor devices. Because of recent advances in AI (Artificial Intelligence), we can now concentrate our efforts on developing AI-based algorithms for high precision-automated signal interpretation for failure detection in Scanning Acoustic Microscopes (SAM). Typically, flaw detection in ultrasonic data relies heavily on human expertise, and the majority of automated classifications are based on image-based decision algorithms. For defect classification, the image-based ML approach necessitates a large dataset. On signals, the traditional machine learning approach requires manual feature extraction and selection of the best features. DL approaches are commonly used to automate feature learning and classification from raw signals. This paper proposes a method for creating datasets, preprocessing signals, and semi-supervised signal training for defect classification. For performance evaluation, different DL architectures such as 1D CNN, RNN, and hybrid networks were studied. The models were trained to categorize C4 bumps in flip chips into a defect and intact classes. Even with fewer learnable, 1D-CNN with wavelet applied A-Scan as input outperforms other models with an accuracy of up to 99 percent. The model was then validated by destructive analysis on an unknown sample.

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基于深度学习网络的半导体器件缺陷自动分类

为了应对复杂半导体器件中即将到来的挑战，需要更有效的失效分析(FA)技术。由于AI(人工智能)的最新进展，我们现在可以集中精力开发基于AI的算法，用于扫描声学显微镜(SAM)故障检测的高精度自动信号解释。通常，超声波数据中的缺陷检测严重依赖于人类的专业知识，而大多数自动分类都是基于基于图像的决策算法。对于缺陷分类，基于图像的机器学习方法需要一个大的数据集。对于信号，传统的机器学习方法需要人工提取特征并选择最佳特征。深度学习方法通常用于从原始信号中自动学习特征和分类。本文提出了一种用于缺陷分类的数据集创建、信号预处理和半监督信号训练的方法。为了进行性能评估，研究了不同的深度学习架构，如1D CNN、RNN和混合网络。这些模型经过训练，将倒装芯片中的C4凸起分类为缺陷和完整类。即使具有较少的可学习性，使用小波应用A-Scan作为输入的1D-CNN也以高达99%的准确率优于其他模型。然后通过对未知样品的破坏性分析验证了该模型。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2022 IEEE International Symposium on the Physical and Failure Analysis of Integrated Circuits (IPFA)

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