9D-6 Signal Analysis in Scanning Acoustic Microscopy for Non-Destructive Assessment of Connective Defects in Flip-Chip BGA Devices

S. Brand, K. Raum, P. Czuratis, P. Hoffrogge
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引用次数: 8

Abstract

Failure analysis in industrial applications often require methods working non-destructively for allowing a variety of tests at a single device. Scanning acoustic microscopy in the frequency range above 100 MHz provides high axial and lateral resolution, a moderate penetration depth and the required non-destructivity. The goal of this work was the development of a method for detecting and evaluating connective defects in densely integrated flip-chip ball grid array (BGA) devices. A major concern was the ability to automatically detect and differentiate the ball-connections from the surrounding underfill and the derivation of a binary classification between void and intact connection. Flip chip ball grid arrays with a 750 mum silicon layer on top of the BGA were investigated using time resolved scanning acoustic microscopy. The microscope used was an Evolution II (SAM TEC, Aalen, Germany) in combination with a 230 MHz transducer. Short acoustic pulses were emitted into the silicon through an 8 mm liquid layer. In receive mode reflected signals were recorded, digitized and stored at the SAM's internal hard drive. The off-line signal analysis was performed using custom-made MATLAB (The Mathworks, Natick, USA) software. The sequentially working analysis characterized echo signals by pulse separation to determine the positions of BGA connectors. Time signals originated at the connector interface were then investigated by wavelet- (WVA) and pulse separation analysis (PSA). Additionally the backscattered amplitude integral (BAI) was estimated. For verification purposes defects were evaluated by X-ray- and scanning electron microscopy (SEM). It was observed that ball connectors containing cracks seen in the SEM images show decreased values of wavelet coefficients (WVC). However, the relative distribution was broader compared to intact connectors. It was found that the separation of pulses originated at the entrance and exit of the ball array corresponded to the condition of the connector. The success rate of the acoustic method in detecting voids was 96.8%, as verified by SEM images. Defects revealed by the acoustic analysis and confirmed by SEM could be detected by X-ray microscopy only in 64% of the analysed cases. The combined analyses enabled a reliable and non destructive detection of defect ball-grid array connectors. The performance of the automatically working acoustical method seemed superior to X-ray microscopy in detecting defect ball connectors.
9D-6信号分析在倒装BGA器件连接缺陷无损检测中的应用
工业应用中的故障分析通常需要非破坏性工作方法,以允许在单个设备上进行各种测试。在100 MHz以上的频率范围内扫描声学显微镜提供高轴向和横向分辨率,中等穿透深度和所需的非破坏性。这项工作的目标是开发一种检测和评估密集集成倒装芯片球栅阵列(BGA)器件中连接缺陷的方法。一个主要的问题是能否自动检测和区分球形连接和周围的下填体,以及在空隙和完整连接之间进行二元分类。利用时间分辨扫描声学显微镜研究了在BGA上有750 μ m硅层的倒装芯片球栅阵列。使用的显微镜是Evolution II (SAM TEC, Aalen, Germany),结合230 MHz换能器。短声脉冲通过一个8毫米的液体层发射到硅中。在接收模式下,反射信号被记录、数字化并存储在地对空导弹的内部硬盘驱动器中。离线信号分析使用定制的MATLAB (The Mathworks, Natick, USA)软件进行。通过脉冲分离对回波信号进行顺序工作分析,确定BGA连接器的位置。然后用小波变换(WVA)和脉冲分离分析(PSA)对来自连接器接口的时间信号进行分析。此外,还估计了后向散射振幅积分(BAI)。为了验证目的,用x射线和扫描电子显微镜(SEM)对缺陷进行了评估。结果表明,含裂纹的球接插件在扫描电镜图像中显示小波系数(WVC)值减小。然而,与完整连接器相比,相对分布范围更广。结果表明,在球阵的入口和出口产生的脉冲分离与连接器的情况相对应。扫描电镜(SEM)图像验证了声学方法检测孔洞的成功率为96.8%。通过声学分析发现并经扫描电镜证实的缺陷,x射线显微镜只能在64%的分析病例中检测到。综合分析能够可靠且无损地检测球栅阵列连接器的缺陷。自动工作声学方法的性能似乎优于x射线显微镜在检测缺陷球连接器。
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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