Title :
Thermally-induced soft errors in nanoscale CMOS circuits
Author :
Li, H. ; Mundy, J. ; Paterson, W. ; Kazazis, D. ; Zaslavsky, A. ; Bahar, R.I.
Author_Institution :
Div. of Eng., Brown Univ., Providence, RI
Abstract :
Electrical noise will play an increasingly critical role in future nanoscale CMOS circuit operation characterized by lower supply voltages VDD and smaller device sizes. Both of these downscaling approaches reduce the margin of immunity to thermal noise, alpha particle strikes, and threshold voltage variations. This paper investigates the noise probability distributions for both equilibrium and non-equilibrium logic states of advanced CMOS flip-flops operated at ultra-low VDD. The theoretical distribution of transition times from one stable operation point to the other stable operation point is also derived, which is a useful representation of the soft error rate. It is shown that such nanoscale flip-flop designs are extremely sensitive to threshold variations, reducing average failure time to a few days. Monte Carlo simulations are provided to validate the theoretical model and its predictions.
Keywords :
CMOS integrated circuits; Monte Carlo methods; flip-flops; integrated circuit design; integrated circuit modelling; low-power electronics; nanoelectronics; Monte Carlo simulations; electrical noise; lower supply voltages VDD; nanoscale CMOS circuits; nanoscale flip flop designs; noise probability distributions; smaller device sizes; soft error rate; thermally induced soft errors; transition times; Alpha particles; CMOS logic circuits; Circuit noise; Error analysis; Flip-flops; Logic devices; Nanoscale devices; Noise reduction; Probability distribution; Threshold voltage; birth-death queue; flip-flop; noise; soft errors;
Conference_Titel :
Nanoscale Architectures, 2007. NANOSARCH 2007. IEEE International Symposium on
Conference_Location :
San Jose, CA
Print_ISBN :
978-1-4244-1790-2
Electronic_ISBN :
978-1-4244-1791-9
DOI :
10.1109/NANOARCH.2007.4400859
