负电容场效应管的全芯片功率优势

2017 IEEE/ACM International Symposium on Low Power Electronics and Design (ISLPED) Pub Date : 2017-07-01 DOI:10.1109/ISLPED.2017.8009170

S. Samal, S. Khandelwal, A. Khan, S. Salahuddin, C. Hu, S. Lim

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引用次数: 20

摘要

我们首次研究了负电容FET (NCFET)器件技术在商业级gdsi级设计中的全芯片功率优势。由于ncfet具有低于60mv /decade的特性，在给定电压下，ncfet比标准fet提供更高的驱动电流，通过降低VDD实现显著的等性能功耗节约。我们使用了14nm节点对应的ncfet的SPICE模型，其中包含了实验校准的铁电模型。然后，我们描述了基于ncfeet的标准单元库，随后是基于ncfeet的全芯片gdsii级设计实现的不同基准。我们的研究结果表明，即使增加器件电容，在相同性能下，与标称VDD基准fet相比，低VDD ncfet可以实现约4倍(高达74.7%)的全芯片功耗降低。在多个基准测试中，节能效果是一致的，对于低功耗设计，节能效果更高。

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Full chip power benefits with negative capacitance FETs

We study, for the first time, full chip power benefits of negative capacitance FET (NCFET) device technology for commercial-grade GDSII-level designs. Owing to sub-60mV/decade characteristics, NCFETs provide significantly higher drive-current than standard FETs at a given voltage, enabling significant iso-performance power savings by lowering VDD. We use SPICE models of NCFETs corresponding to 14nm node, which incorporate experimentally calibrated models of ferroelectric. We then characterize NCFET-based standard-cell libraries followed by full-chip NCFET-based GDSII-level design implementations of different benchmarks. Our results show that even with increased device capacitance, we can achieve about 4× (up to 74.7%) full-chip power reduction with low-VDD NCFETs over nominal VDD baseline FETs at iso-performance. The power savings are consistent across multiple benchmarks and are higher for low power designs.

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2017 IEEE/ACM International Symposium on Low Power Electronics and Design (ISLPED)

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