一个ghz级电荷恢复逻辑

ISLPED '05. Proceedings of the 2005 International Symposium on Low Power Electronics and Design, 2005. Pub Date : 2005-08-08 DOI:10.1145/1077603.1077627

V. Sathe, M. Papaefthymiou, C. Ziesler

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引用次数: 3

摘要

Boost Logic是一种依赖于电压缩放、栅极超速驱动和能量回收的逻辑系列，可在GHz频率下实现高能效。我们设计的关键特征是一个能量回收“升压”级，它在接近阈值的电源电压下为积极的电压缩放逻辑提供高栅极超速驱动。我们通过在0.13/spl mu/m CMOS工艺(V/sub /=340mV)中8位进位节省乘法器的布局后仿真来评估Boost Logic。在1.6GHz和1.3V供电电压下，Boost乘法器每次计算耗散8.11pJ，比其流水线、电压缩放的静态CMOS对应物节省68%的能量。使用低V/sub /器件，Boost Logic乘法器已被验证工作在2GHz下，电压为1.25V，每周期能量消耗为8.50pJ。

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A GHz-class charge recovery logic

This paper describes Boost Logic, a logic family which relies on voltage scaling, gate overdrive, and energy recovery, to achieve high energy efficiency at GHz frequencies. The key feature of our design is an energy recovering "boost" stage that provides a high gate overdrive to an aggressively voltage-scaled logic at near-threshold supply voltage. We have evaluated Boost Logic through post-layout simulation of an 8-bit carry-save multiplier in a 0.13/spl mu/m CMOS process with V/sub th/=340mV. At 1.6GHz and 1.3V supply voltage, the Boost multiplier dissipates 8.11pJ per computation, yielding 68% energy savings over its pipelined, voltage-scaled static CMOS counterpart. Using low V/sub th/ devices, the Boost Logic multiplier has been verified to operate at 2GHz with a 1.25V voltage supply and 8.50pJ energy dissipation per cycle.

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ISLPED '05. Proceedings of the 2005 International Symposium on Low Power Electronics and Design, 2005.

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