Accelerate Your 3D X-ray Failure Analysis by Deep Learning High Resolution Reconstruction

A. Gu, A. Andreyev, M. Terada, Bernice Zee, Syahirah Mohammad-Zulkifli, Yanjing Yang
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引用次数: 8

Abstract

Over the past decade, 3D X-ray technique has played a critical role in semiconductor package failure analysis (FA), primarily owing to its non-destructive nature and high resolution capability [1,2]. As novel complex IC packages soar in recent years [3,4], X-ray failure analysis faces increasing challenges in imaging new advanced packages because IC interconnects are more densely packed in larger platforms. It takes several hours to overnight to image fault regions at high resolution or the crucial details of a defect remain undetected. A high-productivity X-ray solution is required to substantially speed up data acquisition while maintaining image quality. In this paper, we propose a new deep learning high-resolution reconstruction (DLHRR) method, capable of speeding up data acquisition by at least a factor of four through the implementation of pretrained neural networks. We will demonstrate that DLHRR extracts signals from low-dose data more efficiently than the conventional Feldkamp-Davis-Kress (FDK) method, which is sensitive to noise and prone to the aliasing image artifacts. Several semiconductor packages and a commercial smartwatch battery module will be analyzed using the proposed technique. Up to 10x scan throughput improvement was demonstrated on a commercial IC package. Without the need of any additional X-ray beam-line hardware, the proposed method can provide a viable and affordable solution to turbocharge X-ray failure analysis.
通过深度学习高分辨率重建加速3D x射线故障分析
在过去的十年中,3D x射线技术在半导体封装失效分析(FA)中发挥了关键作用,主要是由于其非破坏性和高分辨率能力[1,2]。随着近年来新型复杂IC封装的激增[3,4],x射线失效分析在成像新型先进封装方面面临越来越大的挑战,因为IC互连在更大的平台中更加密集。以高分辨率对故障区域进行成像需要几个小时,或者缺陷的关键细节仍未被检测到。需要一个高生产率的x射线解决方案,以大大加快数据采集,同时保持图像质量。在本文中,我们提出了一种新的深度学习高分辨率重建(DLHRR)方法,能够通过实现预训练的神经网络将数据采集速度提高至少四倍。我们将证明DLHRR比传统的Feldkamp-Davis-Kress (FDK)方法更有效地从低剂量数据中提取信号,而传统的FDK方法对噪声敏感,容易产生混叠图像伪影。几个半导体封装和商业智能手表电池模块将使用该技术进行分析。在商用IC封装上演示了高达10倍的扫描吞吐量改进。在不需要任何额外的x射线束线硬件的情况下,该方法可以为涡轮增压x射线故障分析提供一种可行且经济实惠的解决方案。
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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