Utilizing Dark Silicon to Save Energy with Computational Sprinting

Author

Raghavan, Arun ; Emurian, Laurel ; Lei Shao ; Papaefthymiou, Marios ; Pipe, Kevin P. ; Wenisch, Thomas F. ; Martin, Milo M. K.

Volume

33

Issue

5

fYear

2013

fDate

Sept.-Oct. 2013

Firstpage

20

Lastpage

28

Abstract

Computational sprinting activates dark silicon to improve responsiveness by briefly but intensely exceeding a system´s sustainable power limit. This article focuses on the energy implications of sprinting. The authors observe that sprinting can save energy even while improving responsiveness by enabling execution in chip configurations that, though thermally unsustainable, improve energy efficiency. Surprisingly, this energy savings can translate to throughput improvements even for long-running computations. Repeatedly alternating between sprint and idle modes while maintaining sustainable average power can outperform steady-state computation at the platform´s thermal limit.

Keywords

CMOS integrated circuits; elemental semiconductors; energy conservation; silicon; CMOS scaling; Si; chip configurations; computational sprinting; dark silicon; energy efficiency; energy saving; platform thermal limit; system sustainable power limit; Analytical models; Computational modeling; Energy efficiency; Semiconductor device manufacture; Silicon; Temperature measurement; Time-frequency analysis; dark silicon; energy-aware architecture; responsiveness; temperature; thermal-aware architecture;

fLanguage

English

Journal_Title

Micro, IEEE

Publisher

ieee

ISSN

0272-1732

Type

jour

DOI

10.1109/MM.2013.76

Filename

6576750