MOSFET
晶体管
CMOS芯片
平面的
阈值电压
短通道效应
消散
缩放比例
场效应晶体管
材料科学
电路设计
电子工程
技术路线图
电气工程
工程物理
计算机科学
电压
工程类
光电子学
物理
数学
计算机图形学(图像)
几何学
热力学
营销
业务
作者
Shams Ul Haq,Vijay Kumar Sharma
出处
期刊:Current Nanoscience
[Bentham Science]
日期:2022-12-07
卷期号:19 (5): 651-662
被引量:10
标识
DOI:10.2174/1573413719666221206122301
摘要
Background: The insatiable need for low-power and high-performance integrated circuit (IC) results in the development of alternative options for metal oxide semiconductor field effect transistor (MOSFET) in the ultra-nanoscale regime. The practical challenge of the device scaling limits the use of MOSFET for future technology nodes. ICs are equipped with billions of transistors whose size must be scaled while increasing performance. As the size of the transistor shrinks for the new technology node, the control of the gate over the channel also reduces, leading to sub-threshold leakage. The non-planar technology is the potential methodology to design the ICs for the future technology nodes. The fin-shaped field effect transistor (FinFET) is the most valuable non-planar technology. High sub-threshold slope, better short channel effect (SCE) control, high current drive strength, low dopant-prompted variations, and decreased power dissipation are the prominent features of FinFET technology. Objective: FinFET is an advanced version of MOSFET in terms of geometrical structure. Therefore, in this review paper, the different geometrical structures, working operations, design challenges, future aspects, and the different configurations of FinFETs are presented. The performance of the different configurations of a 1-bit full adder is evaluated and compared. Methods: An overview of FinFET evolution from the planar MOSFET, along with its architecture supported by the requisite equations, is presented in the paper. Besides this, it also gives an insight into the circuit simulation using the FinFETs for the process voltage temperature (PVT) variations, width quantization, design challenges, and the future of FinFETs. A comparative study of FinFET-based 1-bit full adder using various techniques is done to compute and compare the leakage power, delay, and power delay product (PDP). Results: The full adders using FinFETs show less leakage power and PDP. The AND-OR logicbased hybrid full adder using FinFETs shows the least energy consumption per switching. Fin- FET-based gate diffusion input adder shows a 74 % reduction in dynamic power compared to the full adder using MOSFET technology. The low power FinFET-based full adder shows a 54.16 % reduction in leakage power compared to the MOSFET-based full adder. The results signify the effect of multi-gates in curbing the leakage power dissipation. Conclusion: MOSFET faces the practical challenge of device scaling and SCEs at lower technology nodes. It initiates the multi-gate technology for future system generation. FinFET has the capability to design low-power and high-performance circuits in an ultra-nanoscale regime. The geometrical structure of FinFET plays a key role to improve the performance metrics in an ultrananoscale regime.
科研通智能强力驱动
Strongly Powered by AbleSci AI