Title :
Reactivation Noise Suppression With Sleep Signal Slew Rate Modulation in MTCMOS Circuits
Author :
Hailong Jiao ; Kursun, V.
Author_Institution :
Dept. of Electron. & Comput. Eng., Hong Kong Univ. of Sci. & Technol., Hong Kong, China
fDate :
3/1/2013 12:00:00 AM
Abstract :
Multi-threshold CMOS (MTCMOS) is commonly used for suppressing leakage currents in idle integrated circuits. Power and ground distribution network noise produced during SLEEP to ACTIVE mode transitions is an important reliability concern in MTCMOS circuits. Sleep signal slew rate modulation techniques for suppressing mode-transition noise are explored in this paper. A triple-phase sleep signal slew rate modulation (TPS) technique with a novel digital sleep signal generator is proposed. Reactivation time, mode-transition energy consumption, leakage power consumption, and layout area of different MTCMOS circuits are characterized under an equal-noise constraint. Influences of within-die and die-to-die parameter variations on the reactivation noise, time, and energy consumption of sleep signal slew rate modulated MTCMOS circuits are evaluated with a process imperfections aware robustness metric. The proposed triple-phase sleep signal slew rate modulation technique enhances the tolerance to process parameter fluctuations by up to 183.1× as compared to various alternative MTCMOS noise suppression techniques in a UMC 80-nm CMOS technology.
Keywords :
CMOS integrated circuits; integrated circuit layout; integrated circuit noise; integrated circuit reliability; interference suppression; leakage currents; modulation; signal generators; MTCMOS circuit layout area; TPS technique; UMC CMOS technology; active mode transitions; circuit reliability; die-to-die parameter variations; digital sleep signal generator; equal-noise constraint; ground distribution network noise; idle integrated circuits; leakage current suppression; leakage power consumption; multithreshold CMOS circuit; power distribution network noise; process parameter fluctuations; reactivation noise suppression; reactivation time mode-transition energy consumption; size 80 nm; sleep mode transitions; sleep signal slew rate modulation techniques; triple-phase sleep signal slew rate modulation technique; Delay; Energy consumption; Modulation; Noise; Switching circuits; Threshold voltage; Transistors; Digital sleep signal slew rate modulator; low noise; mode transition energy; power and ground bouncing noise; process variations; reactivation time; sleep signal rise delay; triple-phase wake-up;
Journal_Title :
Very Large Scale Integration (VLSI) Systems, IEEE Transactions on
DOI :
10.1109/TVLSI.2012.2190116
