CMP network-on-chip overlaid with multi-band RF-interconnect

Author

Chang, M. Frank ; Cong, Jason ; Kaplan, Adam ; Naik, Mishali ; Reinman, Glenn ; Socher, Eran ; Tam, Sai-Wang

Author_Institution

Electr. Eng. Dept., UCLA, Los Angeles, CA

fYear

2008

fDate

16-20 Feb. 2008

Firstpage

191

Lastpage

202

Abstract

In this paper, we explore the use of multi-band radio frequency interconnect (or RF-I) with signal propagation at the speed of light to provide shortcuts in a many core network-on-chip (NoC) mesh topology. We investigate the costs associated with this technology, and examine the latency and bandwidth benefits that it can provide. Assuming a 400 mm² die, we demonstrate that in exchange for 0.13% of area overhead on the active layer, RF-I can provide an average 13% (max 18%) boost in application performance, corresponding to an average 22% (max 24%) reduction in packet latency. We observe that RF access points may become traffic bottlenecks when many packets try to use the RF at once, and conclude by proposing strategies that adapt RF-I utilization at runtime to actively combat this congestion.

Keywords

integrated circuit interconnections; microprocessor chips; network-on-chip; radiofrequency integrated circuits; CMP; RF access points; chip multiprocessor; mesh topology; multiband RF-interconnect; network-on-chip; packet latency; radio frequency interconnect; signal propagation; traffic bottlenecks; Aggregates; Bandwidth; CMOS technology; Costs; Delay; Integrated circuit interconnections; Network-on-a-chip; RF signals; Radio frequency; System recovery;

fLanguage

English

Publisher

ieee

Conference_Titel

High Performance Computer Architecture, 2008. HPCA 2008. IEEE 14th International Symposium on

Conference_Location

Salt Lake City, UT

ISSN

1530-0897

Print_ISBN

978-1-4244-2070-4

Type

conf

DOI

10.1109/HPCA.2008.4658639

Filename

4658639