Assessing the Impact of Temperature and Supply Voltage Variations in Near-threshold Circuits using an Analytical Model

Proceedings of the 2018 on Great Lakes Symposium on VLSI Pub Date : 2018-05-30 DOI:10.1145/3194554.3194589

Sneh Saurabh, Vishav Vikash

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引用次数: 2

Abstract

In this paper, we develop an analytical model based on Enz Krummenacher Vittoz (EKV) current equations to assess the impact of temperature and supply voltage (VDD) variations in circuits operating in near-threshold voltage (NTV) regime. Using the proposed model, we derive parameters that can be optimized to reduce the impact of these variations on devices operating in the NTV regime and highlight the dominant role of the inversion coefficient of the EKV equations. Further, we show that, instead of operating circuits such as a CMOS inverter very close to the threshold voltage (VTH.), it is beneficial to operate these circuits 3 - 4kT/q above the VTH. At these voltages, the impact of the temperature variations on the delay is minimized and the impact of VDD variations on delay is 0.7x lower than when operated at VDD =VTH. Additionally, compared to the super-threshold operation, the power consumption reduces by 5x and the delay increases by 5x. The results presented in this paper can be employed in estimating the increase in the time margins required when a circuit is migrated from the super-threshold operation to the near-threshold operation.

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用分析模型评估近阈值电路中温度和电源电压变化的影响

在本文中，我们建立了一个基于Enz Krummenacher Vittoz (EKV)电流方程的分析模型，以评估在近阈值电压(NTV)状态下工作的电路中温度和电源电压(VDD)变化的影响。利用所提出的模型，我们推导出可以优化的参数，以减少这些变化对在NTV状态下运行的设备的影响，并突出EKV方程的反转系数的主导作用。此外，我们表明，而不是操作电路，如CMOS逆变器非常接近阈值电压(VTH)，这是有益的操作这些电路高于VTH 3 - 4kT/q。在这些电压下，温度变化对延迟的影响最小，VDD变化对延迟的影响比VDD =VTH时低0.7倍。此外，与超阈值操作相比，功耗降低了5倍，延迟增加了5倍。本文的结果可用于估计电路从超阈值操作迁移到近阈值操作时所需的时间裕度的增加。

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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Proceedings of the 2018 on Great Lakes Symposium on VLSI

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