Title :
Modeling and minimization of PMOS NBTI effect for robust nanometer design
Author :
Vattikonda, Rakesh ; Wang, Wenping ; Cao, Yu
Author_Institution :
Dept. of EE, ASU, Tempe, AZ
Abstract :
Negative bias temperature instability (NBTI) has become the dominant reliability concern for nanoscale PMOS transistors. In this paper, a predictive model is developed for the degradation of NBTI in both static and dynamic operations. Model scalability and generality are comprehensively verified with experimental data over a wide range of process and bias conditions. By implementing the new model into SPICE for an industrial 90nm technology, key insights are obtained for the development of robust design solutions: (1) the most effective techniques to mitigate the NBTI degradation are VDD tuning, PMOS sizing, and reducing the duty cycle; (2) an optimal VDD exists to minimize the degradation of circuit performance; (3) tuning gate length or the switching frequency has little impact on the NBTI effect; (4) a new switching scenario is identified for worst case timing analysis during NBTI stress
Keywords :
MOSFET; nanoelectronics; semiconductor device breakdown; semiconductor device models; semiconductor device reliability; 90 nm; NBTI degradation; PMOS NBTI effect; SPICE; model generality; model scalability; nanometer design; nanoscale PMOS transistors; negative bias temperature instability; predictive model; robust design solutions; timing analysis; Circuit optimization; Degradation; MOSFETs; Minimization; Negative bias temperature instability; Niobium compounds; Predictive models; Robustness; Scalability; Titanium compounds; Design; Experimentation; NBTI; Performance; Performance Degradation; Reliability; Temperature; Threshold Voltage; Variability;
Conference_Titel :
Design Automation Conference, 2006 43rd ACM/IEEE
Conference_Location :
San Francisco, CA
Print_ISBN :
1-59593-381-6
DOI :
10.1109/DAC.2006.229436
