Design and Simulation of New High Speed, Low Power D-Flip-Flops, Implemented Using Graphene Nanoribbon and Carbon Nanotube Field Effect Transistors

IF 1.5 4区 工程技术 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC Iranian Journal of Science and Technology-Transactions of Electrical Engineering Pub Date : 2024-06-19 DOI:10.1007/s40998-024-00742-w
Hoda Fereidounpour, Navid Yasrebi, Hossein Pakniat
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Abstract

A novel 13-transistor, low-power true single-phase clocked (TSPC) flip-flop design is proposed which improves clock loading, power consumption, and performance. The power reduction is achieved by applying the stackly arranged low power-on transistor technique to the last stage of the proposed TSPC flip-flop. The circuit is separately implemented using carbon nanotube field effect transistors (CNTFETs), and graphene nanoribbons field effect transistors (GNRFETs). Prior to the final simulations, the optimum parameters of the CNTFETs, and GNRFETs were determined by sweeping their respective design parameters such as oxide thicknesses, nanotube diameters, and the number of nanoribbons. The proposed circuit is then simulated using the optimum transistors. Results demonstrate power consumptions as low as 0.0303 μW and 0.0263 μW, for the CNTFET and GNRFET transistor implementations, respectively, which are at least 72.26% and 94.9% lower than the previously reported flip-flops. Furthermore, it is shown that the proposed flip-flop exhibits better power-delay products (1.830 aJ and 1.519 aJ for CNTFET, and GNRFET implementations, respectively), which are 56.22% and 97.83% lower than those of existing carbon-based or silicon-based designs. This suggests our carbon-based designs as a promising CMOS substitution for low-power, high-performance applications. Both implementations were also investigated for robustness against the variations of supply voltage and operating temperature, and the effects of physical parameters on CNTFET-based implementation were investigated using Monte Carlo analysis. It was shown that although the GNRFET implementation has slightly better performance, by having better power, speed, and PDP, the CNTFET remains completely robust over the simulated ranges of parameters.

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利用石墨烯纳米带和碳纳米管场效应晶体管实现的新型高速、低功耗 D-Flip-Flops 的设计与仿真
本论文提出了一种新型 13 晶体管、低功耗真正单相时钟(TSPC)触发器设计,可改善时钟负载、功耗和性能。通过在所提出的 TSPC 触发器的最后一级应用堆叠排列的低功耗晶体管技术,实现了功耗的降低。电路分别使用碳纳米管场效应晶体管(CNTFET)和石墨烯纳米带场效应晶体管(GNRFET)实现。在最终仿真之前,先通过扫频确定碳纳米管场效应晶体管和石墨烯纳米带场效应晶体管各自的设计参数,如氧化层厚度、纳米管直径和纳米带数量。然后使用最佳晶体管对拟议电路进行仿真。结果表明,CNTFET 和 GNRFET 晶体管实现的功耗分别低至 0.0303 μW 和 0.0263 μW,比以前报告的触发器至少低 72.26% 和 94.9%。此外,研究还表明,所提出的触发器具有更好的功率-延迟积(CNTFET 和 GNRFET 实现的功率-延迟积分别为 1.830 aJ 和 1.519 aJ),比现有的碳基或硅基设计分别低 56.22% 和 97.83%。这表明我们的碳基设计有望成为低功耗、高性能应用的 CMOS 替代品。我们还研究了这两种实现方法对电源电压和工作温度变化的稳健性,并使用蒙特卡洛分析法研究了物理参数对基于 CNTFET 的实现方法的影响。结果表明,虽然 GNRFET 实施方案的性能略好,因为它具有更好的功率、速度和 PDP,但 CNTFET 在模拟的参数范围内仍然完全稳健。
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来源期刊
CiteScore
5.50
自引率
4.20%
发文量
93
审稿时长
>12 weeks
期刊介绍: Transactions of Electrical Engineering is to foster the growth of scientific research in all branches of electrical engineering and its related grounds and to provide a medium by means of which the fruits of these researches may be brought to the attentionof the world’s scientific communities. The journal has the focus on the frontier topics in the theoretical, mathematical, numerical, experimental and scientific developments in electrical engineering as well as applications of established techniques to new domains in various electical engineering disciplines such as: Bio electric, Bio mechanics, Bio instrument, Microwaves, Wave Propagation, Communication Theory, Channel Estimation, radar & sonar system, Signal Processing, image processing, Artificial Neural Networks, Data Mining and Machine Learning, Fuzzy Logic and Systems, Fuzzy Control, Optimal & Robust ControlNavigation & Estimation Theory, Power Electronics & Drives, Power Generation & Management The editors will welcome papers from all professors and researchers from universities, research centers, organizations, companies and industries from all over the world in the hope that this will advance the scientific standards of the journal and provide a channel of communication between Iranian Scholars and their colleague in other parts of the world.
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