Multi-Voltage Domain Power Distribution Network for Optimized Ultra-Low Voltage Clock Delivery

2018 Ninth International Green and Sustainable Computing Conference (IGSC) Pub Date : 2018-10-01 DOI:10.1109/IGCC.2018.8752126

Md. Shazzad Hossain, I. Savidis

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引用次数: 2

Abstract

In this paper, the co-design of the clock and power delivery networks is proposed for ultra-low power IoT applications operating in sub-threshold. A distributed, multi-voltage domain and hierarchical power distribution network is proposed to deliver current to the clock buffers, registers, and combinational circuits in local clock distribution networks. The variation of the clock skew, setup time, hold time, and clock-to-q delay are analyzed under process and supply voltage variation. The effect on timing due to supply and process variation is analyzed for a target operating voltage and frequency of, respectively, 250 mV and 2 MHz in a 130 nm CMOS technology. The minimum clock period, skew, and insertion delay are reduced to, respectively, 0.74×, 0.52×, and 0.79× when optimized sub-threshold buffers are implemented, as compared and normalized to a clock network that includes non-optimized buffers. In addition, the co-designed clock and power networks were resilient to as much as 10% variation in the supply voltage when the proposed multi-voltage domain and distributed power distribution network is used with the optimized clock buffers.

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超低电压时钟优化的多电压域配电网

本文提出了时钟和电力传输网络的协同设计，用于在亚阈值下运行的超低功耗物联网应用。提出了一种分布式、多电压域和分层配电网络，将电流输送到本地时钟分配网络中的时钟缓冲器、寄存器和组合电路。分析了制程和电源电压变化对时钟偏差、设置时间、保持时间和时钟到q延迟的影响。在130 nm CMOS技术中，以250 mV和2 MHz为目标工作电压和频率，分析了电源和工艺变化对时序的影响。当实现优化的亚阈值缓冲区时，与包含非优化缓冲区的时钟网络相比，最小时钟周期、偏差和插入延迟分别减少到0.74 x、0.52 x和0.79 x。此外，当所提出的多电压域和分布式配电网络与优化的时钟缓冲器一起使用时，共同设计的时钟和电网对电源电压变化的弹性高达10%。

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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2018 Ninth International Green and Sustainable Computing Conference (IGSC)

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