Energy efficient low-power full-adder by 65 nmCMOS technology in ALU

Suresh Kumar N; Paramasivam K

首页> 外文期刊>Concurrency and computation: practice and experience >Energy efficient low-power full-adder by 65 nmCMOS technology in ALU

【24h】

Energy efficient low-power full-adder by 65 nmCMOS technology in ALU

机译：通过65 NMCMOS技术在ALU中的节能低功耗全加法器

获取原文

获取原文并翻译 | 示例

开具论文收录证明 >>

页面导航

摘要
著录项
引文网络
相似文献
相关主题

摘要

The arrangement of energy efficient low-power full adder has vital role in VLSI systems. In this paper Energy Efficient Low-power 9T full-adder is proposed. Its functioning basis of Power Delay Product (PDP), Delay, power and area is distinguished in accordance with that current 1 bit full-adder simulated by utilizing various Complementary MOS logic designs. Output provides an average minimization of 99.28% in power usage, 67.87% in area, 99.89% in delay, and 99.99% in Power-Delay Product (PDP) distinguished to the traditional 28 Transistors CMOS logic. The ALU design has been implemented using 9T full adder. These logic gates are analysis at 65 nm technology of CMOS by utilizing Schematic Editor Tool.

机译：节能低功耗全加法器的排列在VLSI系统中具有重要作用。在本文中，提出了节能低功耗9T全加法器。它的功率延迟产品（PDP）的功能基础（PDP），延迟，功率和面积是根据通过利用各种互补MOS逻辑设计模拟的电流1位全加法器的特征。输出提供电力使用量为99.28％的平均最小化，面积67.87％，延迟99.89％，电源延迟产品（PDP）中的99.99％区别于传统的28晶体管CMOS逻辑。 ALU设计已使用9T完整加法器实现。这些逻辑门通过利用原理图编辑器工具在CMOS的65 nm技术中进行分析。

著录项

来源
《Concurrency and computation: practice and experience》 |2019年第12期|e4741.1-e4741.6|共6页
作者
Suresh Kumar N; Paramasivam K;
展开▼
作者单位

Department of Electronics and Communication Engineering MAMSchool of Engineering Tamil Nadu 621 105 India;

Department of Electronics and Communication Engineering Kumaraguru College of Technology Chinavedampatti Coimbatore Tamil Nadu 641049 India;

展开▼
收录信息
原文格式 PDF
正文语种 eng
中图分类
关键词
area; average power; delay; power delay product (PDP);

机译：区域;平均力量;延迟;功率延迟产品（PDP）;

相似文献

外文文献
中文文献
专利

1. Energy efficient low-power full-adder by 65 nmCMOS technology in ALU [J] . Suresh Kumar N, Paramasivam K Concurrency and computation: practice and experience . 2019,第12期

机译：ALU中采用65 nmCMOS技术的高能效低功耗全加器
2. Hardware-efficient low-power 2-bit ternary ALU design in CNTFET technology [J] . Murotiya Sneh Lata, Gupta Anu International journal of electronics . 2016,第4a6期

机译：CNTFET技术中具有硬件效率的低功耗2位三元ALU设计
3. Energy-efficient Reduced Swing Domino Logic Circuits in 65 nm Technology [J] . Salendra.Govindarajulu, Dr. T.Jayachandra Prasad International Journal of Engineering Science and Technology . 2010,第6期

机译：采用65 nm技术的节能型低摆摆Domino逻辑电路
4. GTL based wireless sensor specific energy efficient ALU design on 65nm FPGA [C] . Kartik Kalia, Shivani Malhotra, Khyati Nanda, IEEE International Conference on Signal Processing, Computing and Control . 2015

机译：基于GTL的65nm FPGA无线传感器专用节能ALU设计
5. Time-Based, Low-Power, Low-Offset 5-Bit 1 Gs/S Flash ADC Design in 65nm CMOS Technology [D] . Nasrollahpour, Mehdi 2017

机译：采用65nm CMOS技术的基于时间的低功耗，低失调5位1 Gs / S闪存ADC设计
6. Two novel low-power and high-speed dynamic carbon nanotube full-adder cells [O] . Mehdi Bagherizadeh, Mohammad Eshghi 2011

机译：两个新颖的低功耗高速动态碳纳米管全加电池
7. Design of an Efficient Current Mode Full-Adder Applying Carbon Nanotube Technology [O] . Parisa Nejadzadeh, Mohammad Reza Reshadinezhad 2018

机译：应用碳纳米管技术有效电流模式全加法器的设计

Energy efficient low-power full-adder by 65 nmCMOS technology in ALU

摘要

著录项

引文网络

相似文献

相关主题

期刊订阅