Title :
A general cost-effective design structure for probabilistic-based noise-tolerant logic functions in nanometer CMOS technology
Author :
Kaikai Liu ; Ting An ; Hao Cai ; Naviner, L. ; Naviner, Jean-Francois ; Petit, Herve
Author_Institution :
Inst. Mines-TELECOM, TELECOM-ParisTech, Paris, France
Abstract :
Noise-immunity of a logic gate or a circuit is now an important design criterion with dimension scaling to nanometers. Two noise-immune design structures based on Markov random field (MRF) have been proposed in [1], [2] and [3]. These design structures can achieve an excellent noise-immunity but with a large number of redundant transistors. In this paper, a general noise-immune design structure easy to implement has been proposed. It can achieve nearly the same noise-immunity as Master-and-Slave MRF (MAS MRF) [3] but with a significantly less area penalty. Basic logic gates are simulated and comparison of different circuits based on different design structures is presented. These simulations are based on the Berkeley Predictive Technology Model (BPTM) 65nm CMOS Technology [4] and ST 65nm CMOS models.
Keywords :
CMOS logic circuits; Markov processes; integrated circuit design; integrated circuit modelling; integrated circuit noise; logic design; logic gates; nanoelectronics; random processes; Berkeley predictive technology model; CMOS model; Markov random field; cost effective design structure; logic circuit; logic gate; master-and-slave MRF; nanometer CMOS technology; noise immune design structure; noise immunity; probabilistic based noise tolerant logic function; size 65 nm; CMOS integrated circuits; CMOS technology; Integrated circuit modeling; Logic gates; Predictive models; Semiconductor device modeling; Transistors; CMOS; Markov random field (MRF); general cost-effective structure; noise-immunity;
Conference_Titel :
EUROCON, 2013 IEEE
Conference_Location :
Zagreb
Print_ISBN :
978-1-4673-2230-0
DOI :
10.1109/EUROCON.2013.6625225
