An Investigation for the Negative-Bias Temperature Instability Aware CMOS Logic

Q3 Engineering
Kajal, V. Sharma
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引用次数: 0

Abstract

Scaling of the dimensions of semiconductor device plays a very important role in the advancement of very large-scale integration (VLSI) technology. There are many advantages of scaling in VLSI technology such as increment in the speed of the device and less area requirement of the device. Aggressive device scaling causes some limitations in the form of short channel effects which produce large leakage current. Large leakage current harms the characteristics of the device and affects the reliability of the device. The most important and popular reliability issue in deep submicron (DSM) regime is negative-bias temperature instability (NBTI). NBTI effect increases the threshold voltage of p-channel metal oxide semiconductor (PMOS) device over the time and affects the different characteristics of the device. As a result, circuit delay exceeds the design specification and there may be timing violations or logic failure. Different performance parameters are observed under NBTI effect for different logic gates. This paper presents an impact of NBTI at 22nm Berkeley short-channel IGFET model4 (BSIM4) predictive technology model (PTM) for complementary metal oxide semiconductor (CMOS) logic gates. Reliability simulations are utilised to evaluate the amount of gradual damage in PMOS device due to NBTI effect. The impact of NBTI degradation is checked for various CMOS logic gates using Mentor Graphics’s Eldo circuit simulator. Output voltage and drain current are reducing over the time under NBTI effect. NBTI degradation increases the threshold voltage of PMOS device over the time and affects the different characteristics of the device.
负偏置温度不稳定性感知CMOS逻辑的研究
半导体器件尺寸的缩小对超大规模集成电路(VLSI)技术的发展起着非常重要的作用。超大规模集成电路技术具有许多优点,如器件速度的提高和器件面积的减少。侵略性的器件缩放导致一些限制,以产生大泄漏电流的短通道效应的形式。大的泄漏电流会损害器件的特性,影响器件的可靠性。深亚微米(DSM)系统中最重要和最受欢迎的可靠性问题是负偏置温度不稳定性(NBTI)。NBTI效应使p沟道金属氧化物半导体(PMOS)器件的阈值电压随着时间的推移而增加,并影响器件的不同特性。因此,电路延迟超过设计规格,可能会出现时序违规或逻辑故障。不同逻辑门在NBTI效应下的性能参数不同。本文介绍了NBTI在22nm Berkeley短沟道IGFET model4 (BSIM4)预测技术模型(PTM)对互补金属氧化物半导体(CMOS)逻辑门的影响。利用可靠性模拟来评估由于NBTI效应引起的PMOS器件的逐渐损伤量。使用Mentor Graphics的Eldo电路模拟器检查NBTI退化对各种CMOS逻辑门的影响。在NBTI效应下,输出电压和漏极电流随时间减小。NBTI降解使PMOS器件的阈值电压随着时间的推移而增加,并影响器件的不同特性。
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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来源期刊
Micro and Nanosystems
Micro and Nanosystems Engineering-Building and Construction
CiteScore
1.60
自引率
0.00%
发文量
50
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