Area and power efficient divide-by-32/33 dual-modulus pre-scaler using split-path TSPC with AVLS for frequency divider

IF 1 4区 工程技术 Q4 ENGINEERING, ELECTRICAL & ELECTRONIC Journal of Electrical Engineering-elektrotechnicky Casopis Pub Date : 2023-10-01 DOI:10.2478/jee-2023-0048
Premananda Belegehalli Siddaiah, Sahithi Narsepalli, Sanya Mittal, Abdur Rehman
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Abstract

Abstract Pre-scalers are electronic circuits used in phase-locked loops to multiply frequencies. This is achieved by dividing the high-frequency signals generated from a voltage-controlled oscillator. The high-frequency operation of pre-scaler circuits leads to significantly higher power consumption. To address this, D flip-flops (D-FF) realized using true-single phase clocking (TSPC) logic. The work suggests incorporating the Adaptive Voltage Level Source (AVLS) circuit with the Dual Modulus Pre-Scaler (DMPS) circuit to reduce power consumption. In addition to the incorporation of the AVLS circuit, pass transistor logic (PTL) used in the feedback, further minimizes transistors and power. This paper proposes three different designs for divide-by-32/33 DMPS circuit. The proposed-1 design combines regular TSPC-based D-FF with PTL in the feedback and an AVLS circuit, resulting in an average power reduction of 36.5%. The proposed-2 design employs split-path TSPC-based D-FF with logic gates and an AVLS circuit, achieving a power reduction of 46.9%. The proposed-3 design employs split-path TSPC-based D-FF with PTL in the feedback and an AVLS circuit, achieving a significant power reduction of 47.8% compared to the existing DMPS circuit and transistor count by 9.1%. The proposed circuits are realized using a CMOS 180 nm technology node. Cadence Virtuoso and Spectre tools are used. The proposed divide-by-32/33 DMPS circuits also realized in the CMOS 45 nm technology node to verify the functionality in the lower technology node. A power reduction of 46.86% observed when compared to the reference circuit. The proposed designs are both power- and area-efficient, making them promising solutions for minimizing power consumption in pre-scaler circuits.
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面积和功率效率除以32/33双模预标器,使用分频器AVLS的分频路径TSPC
预标度器是锁相环中用于频率倍增的电子电路。这是通过分割由电压控制振荡器产生的高频信号来实现的。预缩放电路的高频工作导致显著更高的功耗。为了解决这个问题,D触发器(D- ff)使用真单相时钟(TSPC)逻辑实现。该工作建议将自适应电压电平源(AVLS)电路与双模预标器(DMPS)电路相结合,以降低功耗。除了结合AVLS电路外,在反馈中使用的晶体管逻辑(PTL)进一步减少了晶体管和功率。本文提出了三种不同的32/33分频DMPS电路设计。提出的1型设计将常规的基于tsc的D-FF与反馈中的PTL和AVLS电路相结合,平均功耗降低36.5%。所提出的2型设计采用了分路tsc型带逻辑门和AVLS电路的D-FF,功耗降低46.9%。该设计采用了基于分路tsc的带PTL反馈的D-FF和AVLS电路,与现有的DMPS电路相比,功耗降低了47.8%,晶体管数量减少了9.1%。该电路采用CMOS 180 nm技术节点实现。使用Cadence Virtuoso和Spectre工具。所提出的除以32/33 DMPS电路也在CMOS 45纳米技术节点上实现,以验证其在较低技术节点上的功能。与参考电路相比,功耗降低46.86%。所提出的设计具有功耗和面积效率,使其成为最小化预缩放电路功耗的有希望的解决方案。
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来源期刊
Journal of Electrical Engineering-elektrotechnicky Casopis
Journal of Electrical Engineering-elektrotechnicky Casopis 工程技术-工程:电子与电气
CiteScore
1.70
自引率
12.50%
发文量
40
审稿时长
6-12 weeks
期刊介绍: The joint publication of the Slovak University of Technology, Faculty of Electrical Engineering and Information Technology, and of the Slovak Academy of Sciences, Institute of Electrical Engineering, is a wide-scope journal published bimonthly and comprising. -Automation and Control- Computer Engineering- Electronics and Microelectronics- Electro-physics and Electromagnetism- Material Science- Measurement and Metrology- Power Engineering and Energy Conversion- Signal Processing and Telecommunications
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