Low-voltage low-power CMOS true-single-phase clocking scheme with locally asynchronous logic circuits

Hong Yi Huang; Kuo Hsing Cheng; Jinn Shyan Wang; Yuan Hua Chu; Tain Shun Wu; Chung Yu Wu

Low-voltage low-power CMOS true-single-phase clocking scheme with locally asynchronous logic circuits

Hong Yi Huang, Kuo Hsing Cheng, Jinn Shyan Wang, Yuan Hua Chu, Tain Shun Wu, Chung Yu Wu

Department of Electrical Engineering

Research output: Contribution to journal › Conference article › peer-review

3 Scopus citations

Abstract

New CMOS differential logic circuits, called asynchronous latched CMOS differential logic (ALCDL) circuits, are proposed and analyzed. The ALCDL can implement a complex function in a single gate and achieve high operation speed without dc power dissipation. New CMOS differential latches, which can be used to prevent extra transitions and reduce the power dissipation, are also proposed. A new clocking scheme is designed by locally using the ALCDL circuits and the entire system is synchronized to a single global clock. As compared to the conventional true-single-phase clock system, the loading of the global clock line and transient noise induced by precharge operation can be largely reduced. Simulation results show that the new clocking scheme and logic circuits benefit in high-speed and low-power performances, especially in low supply voltage.

Original language	English
Pages (from-to)	1572-1575
Number of pages	4
Journal	Proceedings - IEEE International Symposium on Circuits and Systems
Volume	3
State	Published - 1995
Event	Proceedings of the 1995 IEEE International Symposium on Circuits and Systems-ISCAS 95. Part 3 (of 3) - Seattle, WA, USA Duration: 30 Apr 1995 → 3 May 1995

Cite this

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title = "Low-voltage low-power CMOS true-single-phase clocking scheme with locally asynchronous logic circuits",

abstract = "New CMOS differential logic circuits, called asynchronous latched CMOS differential logic (ALCDL) circuits, are proposed and analyzed. The ALCDL can implement a complex function in a single gate and achieve high operation speed without dc power dissipation. New CMOS differential latches, which can be used to prevent extra transitions and reduce the power dissipation, are also proposed. A new clocking scheme is designed by locally using the ALCDL circuits and the entire system is synchronized to a single global clock. As compared to the conventional true-single-phase clock system, the loading of the global clock line and transient noise induced by precharge operation can be largely reduced. Simulation results show that the new clocking scheme and logic circuits benefit in high-speed and low-power performances, especially in low supply voltage.",

author = "Huang, {Hong Yi} and Cheng, {Kuo Hsing} and Wang, {Jinn Shyan} and Chu, {Yuan Hua} and Wu, {Tain Shun} and Wu, {Chung Yu}",

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TY - JOUR

T1 - Low-voltage low-power CMOS true-single-phase clocking scheme with locally asynchronous logic circuits

AU - Huang, Hong Yi

AU - Cheng, Kuo Hsing

AU - Wang, Jinn Shyan

AU - Chu, Yuan Hua

AU - Wu, Tain Shun

AU - Wu, Chung Yu

PY - 1995

Y1 - 1995

N2 - New CMOS differential logic circuits, called asynchronous latched CMOS differential logic (ALCDL) circuits, are proposed and analyzed. The ALCDL can implement a complex function in a single gate and achieve high operation speed without dc power dissipation. New CMOS differential latches, which can be used to prevent extra transitions and reduce the power dissipation, are also proposed. A new clocking scheme is designed by locally using the ALCDL circuits and the entire system is synchronized to a single global clock. As compared to the conventional true-single-phase clock system, the loading of the global clock line and transient noise induced by precharge operation can be largely reduced. Simulation results show that the new clocking scheme and logic circuits benefit in high-speed and low-power performances, especially in low supply voltage.

AB - New CMOS differential logic circuits, called asynchronous latched CMOS differential logic (ALCDL) circuits, are proposed and analyzed. The ALCDL can implement a complex function in a single gate and achieve high operation speed without dc power dissipation. New CMOS differential latches, which can be used to prevent extra transitions and reduce the power dissipation, are also proposed. A new clocking scheme is designed by locally using the ALCDL circuits and the entire system is synchronized to a single global clock. As compared to the conventional true-single-phase clock system, the loading of the global clock line and transient noise induced by precharge operation can be largely reduced. Simulation results show that the new clocking scheme and logic circuits benefit in high-speed and low-power performances, especially in low supply voltage.

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M3 - 會議論文

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VL - 3

SP - 1572

EP - 1575

JO - Proceedings - IEEE International Symposium on Circuits and Systems

JF - Proceedings - IEEE International Symposium on Circuits and Systems

T2 - Proceedings of the 1995 IEEE International Symposium on Circuits and Systems-ISCAS 95. Part 3 (of 3)

Y2 - 30 April 1995 through 3 May 1995

ER -

Low-voltage low-power CMOS true-single-phase clocking scheme with locally asynchronous logic circuits

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