Nontraditional Design of Dynamic Logics Using FDSOI for Ultra-Efficient Computing

IF 2 Q3 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE IEEE Journal on Exploratory Solid-State Computational Devices and Circuits Pub Date : 2023-04-21 DOI:10.1109/JXCDC.2023.3269141
Shubham Kumar;Swetaki Chatterjee;Chetan Kumar Dabhi;Yogesh Singh Chauhan;Hussam Amrouch
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Abstract

In this article, we propose a nontraditional design of dynamic logic circuits using fully-depleted silicon-on-insulator (FDSOI) FETs. FDSOI FET allows the threshold voltage ( $V_{\text {t}}$ ) to be adjustable (i.e., low- $V_{\text {t}}$ and high- $V_{\text {t}}$ states) by using the back gate (BG) bias. Our design utilizes the front gate (FG) and BG of an FDSOI FET as the input terminals and proposes the dynamic logic gates (like NAND, NOR, AND, OR, XOR, and XNOR) and circuits (like a half-adder and full-adder). It requires fewer transistors to build dynamic logic gates and achieves high performance with low power dissipation compared to conventional dynamic logic designs. The compact industrial model of FDSOI FET (BSIM-IMG) has been used to simulate dynamic logic gates and is fully calibrated to reproduce the 14 nm FDSOI FET technology node data. Calibration is performed for both electrical characteristics and process variations. The simulation results show an average improvement in transistor count, propagation delay, power, and power-delay product (PDP) of 23.43%, 57.16%, 47.05%, and 77.29%, respectively, compared to the conventional designs. Further, our design reduces the charge-sharing effect, which affects the drivability of the dynamic logic gates. In addition, we have analyzed the impact of the process, supply voltage, and load capacitance variations on the propagation delay of the dynamic logic family in detail. The results show that these variations have a minor impact on the propagation delay of the proposed FDSOI-based dynamic logic gates compared to the conventional dynamic logic gates.
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利用FDSOI实现超高效计算的非传统动态逻辑设计
在本文中,我们提出了一种使用完全耗尽绝缘体上硅(FDSOI)FET的动态逻辑电路的非传统设计。FDSOI FET允许通过使用背栅(BG)偏置来调整阈值电压($V_{\text{t}}$)(即,低-$V_{\text{t}}$和高-$V_{\text{t}}$状态)。我们的设计利用FDSOI FET的前栅极(FG)和BG作为输入端,并提出了动态逻辑门(如NAND、NOR、and、OR、XOR和XNOR)和电路(如半加法器和全加法器)。与传统的动态逻辑设计相比,它需要更少的晶体管来构建动态逻辑门,并以低功耗实现高性能。FDSOI FET的紧凑型工业模型(BSIM-IMG)已被用于模拟动态逻辑门,并被完全校准以再现14nm FDSOI场效应管技术节点数据。对电气特性和工艺变化进行校准。仿真结果显示,与传统设计相比,晶体管计数、传播延迟、功率和功率延迟乘积(PDP)的平均改善分别为23.43%、57.16%、47.05%和77.29%。此外,我们的设计减少了电荷共享效应,这影响了动态逻辑门的可驱动性。此外,我们还详细分析了工艺、电源电压和负载电容变化对动态逻辑族传播延迟的影响。结果表明,与传统动态逻辑门相比,这些变化对所提出的基于FDSOI的动态逻辑门的传播延迟影响较小。
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来源期刊
CiteScore
5.00
自引率
4.20%
发文量
11
审稿时长
13 weeks
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