Revisiting Dynamic Logic-A True Candidate for Energy-Efficient Cryogenic Operation in Nanoscaled Technologies

Dynamic logic is a high-speed technology that was previously used in mature technologies, but lost popularity due to the increased leakage and process variations in advanced technologies. However, the recent popularity of circuits running in the cryogenic region provides a new opportunity for dynami...

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Veröffentlicht in:	IEEE transactions on circuits and systems. I, Regular papers Regular papers, 2024-03, Vol.71 (3), p.987-999
Hauptverfasser:	Stanger, Inbal, Roknian, Noam, Shavit, Netanel, Shoshan, Yonatan, Weizman, Yoav, Teman, Adam, Charbon, Edoardo, Fish, Alexander
Format:	Artikel
Sprache:	eng
Schlagworte:	16 nm Circuit design Cryogenic temperature cryogenic temperatures Cryogenics Digital electronics dual mode logic (DML) dual mode pass logic (DMPL) dynamic logic energy-efficiency FinFETs Logic logic families Logic gates low power Low temperature Nanoscale devices pass-transistor logic (PTL) Power efficiency Scattering Silicon Threshold voltage
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container_title	IEEE transactions on circuits and systems. I, Regular papers
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creator	Stanger, Inbal Roknian, Noam Shavit, Netanel Shoshan, Yonatan Weizman, Yoav Teman, Adam Charbon, Edoardo Fish, Alexander
description	Dynamic logic is a high-speed technology that was previously used in mature technologies, but lost popularity due to the increased leakage and process variations in advanced technologies. However, the recent popularity of circuits running in the cryogenic region provides a new opportunity for dynamic operation, thanks to the reduced leakages at such low temperatures. This paper revisits dynamic logic as a true candidate for high-performance and energy-efficient circuits for cryogenic operation in nanoscaled technologies. The paper first overviews and analyzes transistor operation at cryogenic temperatures and how it influences digital circuit design targeted to this regime. With these effects in mind, the use of dynamic logic families, including the classical dynamic (NORA) logic and the recently introduced Dual Mode Logic (DML) and Dual Mode Pass Logic (DMPL) families, are examined under cryogenic operation, showcasing improved performance and power efficiency. Measurements conducted on a 16 nm FinFET test chip validate their operation at low temperatures down to 4K, with supply voltages ranging 0.4-0.8-V. Furthermore, the considered dual mode logic families exhibit performance enhancements of up to 26% in dynamic mode and power efficiency increases up to 53% in static mode, compared to CMOS.
doi_str_mv	10.1109/TCSI.2023.3332817
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subjects	16 nm Circuit design Cryogenic temperature cryogenic temperatures Cryogenics Digital electronics dual mode logic (DML) dual mode pass logic (DMPL) dynamic logic energy-efficiency FinFETs Logic logic families Logic gates low power Low temperature Nanoscale devices pass-transistor logic (PTL) Power efficiency Scattering Silicon Threshold voltage
title	Revisiting Dynamic Logic-A True Candidate for Energy-Efficient Cryogenic Operation in Nanoscaled Technologies
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