Feedback Redundancy: A Power Efficient SEU-Tolerant Latch Design for Deep Sub-Micron Technologies

Author

Fazeli, M. ; Patooghy, A. ; Miremadi, S.G. ; Ejlali, A.

Author_Institution

Sharif Univ. of Technol., Tehran

fYear

2007

fDate

25-28 June 2007

Firstpage

276

Lastpage

285

Abstract

The continuous decrease in CMOS technology feature size increases the susceptibility of such circuits to single event upsets (SEU) caused by the impact of particle strikes on system flip flops. This paper presents a novel SEU-tolerant latch where redundant feedback lines are used to mask the effects of SEUs. The power dissipation, area, reliability, and propagation delay of the presented SEU-tolerant latch are analyzed by SPICE simulations. The results show that this latch consumes about 50% less power and occupies 42% less area than a TMR-latch. However, the reliability and the propagation delay of the proposed latch are still the same as the TMR-latch. the reliability of the proposed latch is also compared with other SEU-tolerant latches.

Keywords

CMOS digital integrated circuits; SPICE; fault tolerant computing; flip-flops; integrated circuit design; integrated circuit reliability; redundancy; system recovery; CMOS technology; SEU-tolerant latch design; SPICE simulation; deep submicron technologies; feature size; feedback redundancy; redundant feedback lines; reliability; single event upsets; system flip flops; CMOS technology; Circuits; Feedback; Latches; Power dissipation; Power system reliability; Propagation delay; Redundancy; SPICE; Single event upset;

fLanguage

English

Publisher

ieee

Conference_Titel

Dependable Systems and Networks, 2007. DSN '07. 37th Annual IEEE/IFIP International Conference on

Conference_Location

Edinburgh

Print_ISBN

0-7695-2855-4

Type

conf

DOI

10.1109/DSN.2007.51

Filename

4272979