A Scalable, Timing-Safe, Network-on-Chip Architecture with an Integrated Clock Distribution Method

Author

Bjerregaard, Tobias ; Stensgaard, Mikkel Bystrup ; Sparsø, Jens

Author_Institution

Teklatech, Lyngby

fYear

2007

fDate

16-20 April 2007

Firstpage

1

Lastpage

6

Abstract

Growing system sizes together with increasing performance variability are making globally synchronous operation hard to realize. Mesochronous clocking constitutes a possible solution to the problems faced. The most fundamental of problems faced when communicating between mesochronously clocked regions concerns the possibility of data corruption caused by metastability. This paper presents an integrated communication and mesochronous clocking strategy, which avoids timing related errors while maintaining a globally synchronous system perspective. The architecture is scalable as timing integrity is based purely on local observations. It is demonstrated with a 90 nm CMOS standard cell network-on-chip design which implements completely timing-safe, global communication in a modular system

Keywords

CMOS integrated circuits; clocks; network-on-chip; 90 nm; CMOS standard cell; data corruption; globally synchronous operation; integrated clock distribution; mesochronous clocking; network-on-chip; performance variability; Buildings; Circuits; Clocks; Communication standards; Delay; Frequency synchronization; Global communication; Metastasis; Network-on-a-chip; Timing;

fLanguage

English

Publisher

ieee

Conference_Titel

Design, Automation & Test in Europe Conference & Exhibition, 2007. DATE '07

Conference_Location

Nice

Print_ISBN

978-3-9810801-2-4

Type

conf

DOI

10.1109/DATE.2007.364667

Filename

4211872