DocumentCode
3498408
Title
GreenDroid: An architecture for the Dark Silicon Age
Author
Goulding-Hotta, Nathan ; Sampson, Jack ; Zheng, Qiaoshi ; Bhatt, Vikram ; Auricchio, Joe ; Swanson, Steven ; Taylor, Michael Bedford
Author_Institution
Dept. of Comput. Sci. & Eng., Univ. of California, San Diego, La Jolla, CA, USA
fYear
2012
fDate
Jan. 30 2012-Feb. 2 2012
Firstpage
100
Lastpage
105
Abstract
The Dark Silicon Age kicked off with the transition to multicore and will be characterized by a wild chase for seemingly ever-more insane architectural designs. At the heart of this transformation is the Utilization Wall, which states that, with each new process generation, the percentage of transistors that a chip can switch at full frequency is dropping exponentially due to power constraints. This has led to increasingly larger and larger fractions of a chip´s silicon area that must remain passive, or dark. Since Dark Silicon is an exponentially-worsening phenomenon, getting worse at the same rate that Moore´s Law is ostensibly making process technology better, we need to seek out fundamentally new approaches to designing processors for the Dark Silicon Age. Simply tweaking existing designs is not enough. Our research attacks the Dark Silicon problem directly through a set of energy-saving accelerators, called Conservation Cores, or c-cores. C-cores are a post-multicore approach that constructively uses dark silicon to reduce the energy consumption of an application by 10× or more. To examine the utility of c-cores, we are developing GreenDroid, a multicore chip that targets the Android mobile software stack. Our mobile application processor prototype targets a 32-nm process and is comprised of hundreds of automatically generated, specialized, patchable c-cores. These cores target specific Android hotspots, including the kernel. Our preliminary results suggest that we can attain up to 11× improvement in energy efficiency using a modest amount of silicon.
Keywords
multiprocessing systems; Android hotspots; Android mobile software stack; GreenDroid; Moore law; chip silicon area; dark silicon age; energy consumption; energy efficiency; energy-saving accelerator; insane architectural design; mobile application processor prototype; multicore chip; patchable c-cores; post-multicore approach; utilization wall; Hardware; Mobile communication; Multicore processing; Program processors; Silicon; Transistors;
fLanguage
English
Publisher
ieee
Conference_Titel
Design Automation Conference (ASP-DAC), 2012 17th Asia and South Pacific
Conference_Location
Sydney, NSW
ISSN
2153-6961
Print_ISBN
978-1-4673-0770-3
Type
conf
DOI
10.1109/ASPDAC.2012.6164926
Filename
6164926
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