用于高能效低温计算的 14 纳米 FinFET 设计探索

IF 2 Q3 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE
Amol D. Gaidhane;Rakshith Saligram;Wriddhi Chakraborty;Suman Datta;Arijit Raychowdhury;Yu Cao
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引用次数: 0

摘要

CMOS 晶体管的低温运行(即低温-CMOS)可有效实现超深亚阈值斜率(SS)和超低漏电,从而通过适当调整阈值电压和电源电压实现高能效。另一方面,cryo-CMOS 对工艺和电压变化的敏感度较高。为促进早期设计探索,我们开发了预测性 BSIM-CMG 模型卡,并利用 14 纳米 TCAD 仿真和 FinFET 实验数据(从 300 K 到 77 K)对其进行了校准。在此基础上,我们对各种电路示例进行了基准测试,以说明在存在工艺变化的情况下,低温-CMOS 在高能效计算方面的巨大潜力。对于逻辑电路,例如典型关键路径,与室温(RT)下的运行相比,在 77 K 等延迟条件下,总能耗减少了 15 倍以上。在阈值电压和电源电压自适应增加后,变化的存在对能效的影响微乎其微。不过,变化对 SNM 的影响要比对逻辑电路的影响明显得多。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Design Exploration of 14 nm FinFET for Energy-Efficient Cryogenic Computing
Cryogenic operation of CMOS transistors (i.e., cryo-CMOS) effectively brings an ultrasteep subthreshold slope (SS) and ultralow leakage, enabling high energy efficiency with appropriate tuning of threshold voltage and supply voltage. On the other hand, cryo-CMOS suffers from elevated sensitivity to process and voltage variations. To facilitate early-stage design exploration, we develop predictive BSIM-CMG model cards, which are calibrated with 14 nm TCAD simulation and our experimental FinFET data from 300 to 77 K. These models are scalable with temperatures from 300 K down to 77 K, device engineering and variations. Based on them, we benchmark various circuit examples to illustrate the tremendous potential of cryo-CMOS for energy-efficient computing, in the presence of process variations. For logic circuits, such as a canonical critical path, more than $15\times $ reduction in total energy consumption is demonstrated at 77 K for the iso–Delay condition, compared to the operation at the room temperature (RT). The presence of variations only has a marginal impact on energy efficiency, after threshold voltage and supply voltage are adaptively increased. For static noise margin (SNM), it is consistently improved at 77 K. However, the impact of variations on SNM is much more pronounced than that on logic circuits.
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来源期刊
CiteScore
5.00
自引率
4.20%
发文量
11
审稿时长
13 weeks
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