低功耗16T 1位混合全加法器的设计实现

2021 International Conference on Control, Automation, Power and Signal Processing (CAPS) Pub Date : 2021-12-10 DOI:10.1109/CAPS52117.2021.9730701

Ayush Kanojia, Sachin Agrawal, R. Lorenzo

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引用次数: 2

摘要

对低功耗和节能计算设备的需求正在迅速增长。这些器件的一个重要的基本部件是加法器。因此，它的功耗需要最小化。提出了一种采用传输门和互补金属氧化物半导体逻辑的1位混合全加法器。与其他设计相比，它提供全摆幅输出，功耗非常低。在180nm和90nm技术节点上进行了布局设计、仿真和性能测试。180nm的总功耗降低约77%，90nm的总功耗降低约89%。此外，在180nm和90nm的情况下，功率延迟产品分别减少了79%和87%。此外，与现有设计相比，拟议设计的面积开销也更小。

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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Design Implementation of a Low-Power 16T 1-bit Hybrid Full Adder

The demand for low-power and energy-efficient computing devices is rising rapidly. One of the important fundamental components of these devices is an adder. Hence, its power consumption needs to be minimized. A 1-bit hybrid full adder employing transmission gates and complementary metal-oxide semiconductor logic is presented in this paper. It provides full swing outputs and consumes very low power in comparison with other presented designs. The layout design, simulation and performance measurement are done in 180 nm and 90 nm technology nodes. The reduction in total power consumption in 180 nm is found to be about 77% and, 89% in 90 nm. In addition, the power-delay product is reduced by 79% in the case of 180 nm and 87% in 90 nm. Furthermore, the area overhead of the proposed design is also less as compared to existing designs.

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2021 International Conference on Control, Automation, Power and Signal Processing (CAPS)

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