一种利用AFPT降低异步电路功率的新方法

2014 Eleventh International Conference on Wireless and Optical Communications Networks (WOCN) Pub Date : 2014-10-16 DOI:10.1109/WOCN.2014.6923091

Shravan, Pavan Kumar, K. Sivani

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引用次数: 1

摘要

本文介绍了一种利用异步细粒度功率门控技术(AFPT)降低异步电路功耗的新方法。改进的高效电荷恢复逻辑(IECRL)开发了一种AFPT，为下一阶段提供了逻辑功能。在AFPT电路中，IECRL门从握手控制器获得功率，并仅在执行所需计算时才激活。在有源模式下，通过上拉网络中的NMOS晶体管提供高阻通路来减小泄漏电流。在非活动模式下，IECRL栅极不需要任何功率，这给了微不足道的泄漏功耗。与ECRL相比，它的最大节电高达89.35%。在AFPT电路中，握手控制器用于向IECRL门供电，并处理与相邻级的握手。在AFPT电路中，利用PCR机制将IECRL栅极放电相的电荷转移到另一个IECRL栅极的相上，以减少能量消耗。IECRL栅极的早期放电可以通过采用改进型C单元(C*-单元)实现。

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A novel approach for power reduction in asynchronous circuits by using AFPT

In this paper, a novel approach for power reduction in asynchronous circuits by using Asynchronous Fine-Grain Power-Gated Technique (AFPT) introduced. An AFPT developed by Improved Efficient Charge Recovery Logic (IECRL), which gives logic function to the next succeeding stage. In the AFPT circuit, IECRL gates attains power from hand shake controller and become active only when executing required calculations. In active mode the leakage currents are reduced by providing high resistance path through the NMOS transistor in pull-up network. In inactive mode IECRL gates are not taken any amount of power, this gives insignificant leakage power dissipation. Its maximum power saving against ECRL is up to 89.35%. In AFPT circuit handshake controller used to provide power to the IECRL gate and which handles the hand shaking with the neighboring stages. In the AFPT circuit PCR mechanism is used to transfer the charge of discharging phase of IECRL gate to evaluate phase of the another IECRL gate, to reduce the energy dissipation. Early discharging of IECRL gate can be achieved by using modified C-element called C*-element.

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2014 Eleventh International Conference on Wireless and Optical Communications Networks (WOCN)

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