低压ic -3.3 V高性能CMOS器件的电气封装要求作为案例研究

Proceedings of IEEE Electrical Performance of Electronic Packaging Pub Date : 1993-10-20 DOI:10.1109/EPEP.1993.394604

R. Senthinathan, A. Mehra, M. Mahalingam, Y. Doi, H. Astrain

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引用次数: 3

摘要

仅给出摘要形式，如下。讨论了5v和3.3 V工作的高性能CMOS器件技术。片外封装延迟和同时开关噪声(SSN)被选为衡量封装影响的指标。器件被封装在四平面封装(QFPs)和引脚网格阵列(PGAs)封装中。使用3.3 V电源，要获得计算上可比较的系统，需要改变器件尺寸以获得相似的电流驱动。在降低电源电压的情况下，对器件进行缩放以实现类似的增强性能。维持计算吞吐量(CTP)在5 V和3.3 V操作时引入了相当的噪声水平。这增加了3.3 V操作中误开关的概率。给出了更小、可比较和更快的CTP 3.3 v封装器件的噪声水平。利用接收机动态抗扰度(DNI)分析了3.3 V工作时的误开关。给出了进一步降低电源电压时总体信噪比的趋势。

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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Electrical packaging requirements for low voltage ICs-3.3 V High Performance CMOS devices as a case study

Summary form only given, as follows. High performance CMOS device technology for 5 V and 3.3 V operations is discussed. Off-chip package delays and simultaneous switching noise (SSN) are selected as metrics to evaluate the impact due to packaging. Devices are housed in quad flat packages (QFPs) and pin grid array (PGAs) packages. With 3.3 V supply, to have a computationally comparable system, device sizes need to be changed to obtain similar current drive. Devices are scaled to achieve similar and enhanced performance for reduced supply voltage. Maintaining computational throughput (CTP) introduces comparable noise levels for 5 V and 3.3 V operations. This increases the probability of false switching in 3.3 V operation. Noise levels for lesser, comparable, and faster CTP 3.3-V packaged devices are given. False switching for 3.3 V operation is analyzed using receiver dynamic noise immunity (DNI). Trends in overall noise-to-signal ratio for further reduced supply voltages are given.<>

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Proceedings of IEEE Electrical Performance of Electronic Packaging

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