利用BSIMPD研究栅极隧道效应对部分耗尽SOI CMOS动态特性的影响

Proceedings International Symposium on Quality Electronic Design Pub Date : 2002-08-07 DOI:10.1109/ISQED.2002.996792

P. Su, S. Fung, Weidong Liu, C. Hu

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引用次数: 9

摘要

在这项工作中，我们借助物理精确的BSIMPD模型，研究和分析了栅极隧道效应对部分耗尽SOI CMOS动态行为的影响。我们特别研究了栅极隧道效应对逆变器时延历史依赖性的影响。研究揭示了在SPICE建模中捕获历史效果的关键需求。研究表明，栅极隧道效应对延迟范围有较大影响，在SOI电路仿真中应予以考虑。对于电路设计者来说，理解和控制由门电流引起的滞后延迟变化是至关重要的。应该使用包含氧化物隧道机制的精确SPICE模型来量化效果，而不会破坏部分耗尽SOI技术的性能优势。BSIMPD是一种试图弥合先进SOI技术和电路设计之间差距的模型。凭借其内置的浮体、自加热和体接触模块，BSIMPD捕获了特定于SOI的效果，因此能够提高PD SOI芯片的设计质量。BSIMPD已经在Berkeley SPICE3f4和其他商业SPICE模拟器中实现。它也可以作为计算用于高级时序模拟的查找表的基础。

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Studying the impact of gate tunneling on dynamic behaviors of partially-depleted SOI CMOS using BSIMPD

In this, work, we investigate and analyze the impact of gate tunneling on dynamic behaviors of partially depleted SOI CMOS with the aid of the physically accurate BSIMPD model. We examine in particular the impact of gate tunneling on the history dependence of inverter delays. The examination reveals key requirements for capturing the history effect in SPICE modeling. This study suggests that gate tunneling has a strong impact on the delay range and should be considered in SOI circuit simulation. It is crucial for circuit, designers to understand and contain the hysteretic delay variations caused by gate current. An accurate SPICE model that includes the oxide tunneling mechanism should be used to quantify the effect without undermining the performance benefit of a partially depleted SOI technology. BSIMPD is one model that attempts to bridge the gap between advanced SOI technologies and circuit design. With its built-in floating-body, self-heating and body-contact modules, BSIMPD captures SOI-specific effects and therefore is able to raise the design quality of PD SOI chips. BSIMPD has been implemented in Berkeley SPICE3f4 and other commercial SPICE simulators. It may also be the basis for computing the look-up tables used for higher-level timing simulation.

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Proceedings International Symposium on Quality Electronic Design

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