基于tsv电感和电容的新型三维集成电路LC谐振时钟

2017 IEEE Electrical Design of Advanced Packaging and Systems Symposium (EDAPS) Pub Date : 2017-12-01 DOI:10.1109/EDAPS.2017.8277019

Shaoheng Luo, Baixin Chen, Ke Li, Cheng Zhuo, Yiyu Shi

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引用次数: 2

摘要

在14nm以下的工艺中，片上电容和电感产生的大面积开销是确保电源完整性或实现片上应用的主要问题。为了克服这一问题，本文研究了一种新型的基于三维通硅孔(TSV)的电容器，该电容器可以实现高密度和高性能。本文所模拟的电容器在TSV周围加入掺杂区，减轻了损耗效应，使电容器在工作电压范围内保持其最大值。此外，通过掺杂和分布式接地触点技术降低了电容器的等效串联电阻。本文还对LC谐振时钟进行了仿真，通过将传统的电容和电感替换为基于TSV的结构，在性能基本保持不变的情况下，电容面积减少16.3倍，电感面积减少2.2倍。

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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Novel LC resonant clocking for 3D IC using TSV-inductor and capacitor

At sub-14nm regime, large area overhead induced by on-chip capacitor and inductor is a major concern to ensure power integrity or enable on-chip applications. To overcome this issue, a novel 3D Through-Silicon-Via (TSV) based capacitor is investigated in this work, which may achieve both high density and high performance. The capacitor simulated in this work alleviates the depletion effect adding doping region around the TSV so that the capacitor can maintain its maximum value within operation voltage range. Moreover, the equivalent serial resistance of the proposed capacitor is reduced through doping and distributed grounded contact technology. An LC resonant clock is also simulated in this work, by replacing conventional capacitor and inductor to TSV based structures, it may achieve a 16.3x capacitor area reduction and 2.2x inductor area reduction while the performance stays almost the same.

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2017 IEEE Electrical Design of Advanced Packaging and Systems Symposium (EDAPS)

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