Accounting for inherent circuit resilience and process variations in analyzing gate oxide reliability

Author

Fang, Jianxin ; Sapatnekar, Sachin S.

Author_Institution

Dept. of ECE, Univ. of Minnesota, Minneapolis, MN, USA

fYear

2011

fDate

25-28 Jan. 2011

Firstpage

689

Lastpage

694

Abstract

Gate oxide breakdown is a major cause of reliability failures in future nanometer-scale CMOS designs. This paper develops an analysis technique that can predict the probability of a functional failure in a large digital circuit due to this phenomenon. Novel features of the method include its ability to account for the inherent resilience in a circuit to a breakdown event, while simultaneously considering the impact of process variations. Based on standard process variation models, at a specified time instant, this procedure determines the circuit failure probability as a lognormal distribution. Experimental results demonstrate this approach is accurate compared with Monte Carlo simulation, and gives 4.7-5.9× better lifetime prediction over existing methods that are based on pessimistic area-scaling models.

Keywords

CMOS digital integrated circuits; failure analysis; integrated circuit design; integrated circuit reliability; log normal distribution; Monte Carlo simulation; circuit failure probability; digital circuit; functional failure probability; gate oxide breakdown; gate oxide reliability; inherent circuit resilience; lognormal distribution; nanometer-scale CMOS designs; pessimistic area-scaling models; reliability failures; standard process variation models; Correlation; Electric breakdown; Equations; Integrated circuit modeling; MOS devices; Mathematical model; Probability;

fLanguage

English

Publisher

ieee

Conference_Titel

Design Automation Conference (ASP-DAC), 2011 16th Asia and South Pacific

Conference_Location

Yokohama

ISSN

2153-6961

Print_ISBN

978-1-4244-7515-5

Type

conf

DOI

10.1109/ASPDAC.2011.5722275

Filename

5722275