Integration of threshold logic gates with RRAM devices for energy efficient and robust operation

Jinghua Yang, Niranjan S. Kulkarni, Shimeng Yu, S. Vrudhula
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引用次数: 12

Abstract

Differential mode threshold-logic gates can be programmed to compute complex logic functions within a single cell, resulting in significant reduction in area and power. However the circuit yield reduces if they are operated at low voltages. This paper describes a novel integration of RRAM with such threshold-logic gates to achieve robust, low voltage (0.6V for 65nm technology) and energy efficient computation of threshold-logic functions. Below 0.6V, we observed that the performance(and thereby, energy delay product) of conventional CMOS circuits degrades substantially compared to the proposed threshold-logic circuits. The improvement in performance and energy of the new circuit architecture are demonstrated while considering process variations in both the MOSFET and RRAM devices. For each threshold function implementable by threshold-logic gate, comparison of energy, delay and energy delay product with equivalent CMOS implementation is given. The advantages in area, energy and delay of threshold logic implementations over conventional CMOS logic gates is demonstrated by two commonly used functional components.
阈值逻辑门与RRAM器件的集成,以实现节能和稳健的运行
差分模式阈值逻辑门可以编程计算复杂的逻辑功能在一个单元内,导致面积和功率显著降低。然而,如果它们在低电压下工作,电路产量会降低。本文描述了一种新的RRAM与阈值逻辑门的集成,以实现鲁棒、低电压(65纳米技术为0.6V)和阈值逻辑功能的节能计算。在0.6V以下,我们观察到传统CMOS电路的性能(以及能量延迟积)与所提出的阈值逻辑电路相比大幅下降。在考虑MOSFET和RRAM器件的工艺变化的同时,展示了新电路结构在性能和能量方面的改进。对于每个可由阈值逻辑门实现的阈值函数,给出了与等效CMOS实现的能量、延迟和能量延迟积的比较。通过两个常用的功能元件,证明了阈值逻辑实现相对于传统CMOS逻辑门在面积、能量和延迟方面的优势。
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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