DocumentCode
2479906
Title
Green flash: Designing an energy efficient climate supercomputer
Author
Oliker, Leonid
Author_Institution
Comput. Res. Div., Lawrence Berkeley Nat. Lab., Berkeley, CA, USA
fYear
2009
fDate
23-29 May 2009
Firstpage
1
Lastpage
1
Abstract
It is clear from both the cooling demands and the electricity costs, that the growth in scientific computing capabilities of the last few decades is not sustainable unless fundamentally new ideas are brought to bear. In this talk we propose a novel approach to supercomputing design that leverages the sophisticated tool chains of the consumer electronics marketplace. We analyze our framework in the context of high-resolution global climate change simulations C an application with multi-trillion dollar ramifications to the world economies. A key aspect of our methodology is hardware-software co-tuning, which utilizes fast and accurate FPGA-based architectural emulation. This enables the design of future exaflop-class supercomputing systems to be defined by scientific requirements instead of constraining science to the machine configurations. Our talk will provide detailed design requirements for a kilometer-scale global cloud system resolving climate models and point the way toward Green Flash: an application-targeted exascale machine that could be efficiently implemented using mainstream embedded design processes. Overall, we believe that our proposed approach can provide a quantum leap in hardware and energy utilization, and may significantly impact the design of the next generation of HPC systems.
Keywords
environmental factors; field programmable gate arrays; mainframes; FPGA-based architectural emulation; application-targeted exascale machine; cooling demands; electricity costs; energy efficient climate supercomputer; global climate change simulations; green flash; hardware-software co-tuning; kilometer-scale global cloud system; scientific computing capabilities; Analytical models; Clouds; Consumer electronics; Context modeling; Costs; Electronics cooling; Emulation; Energy efficiency; Scientific computing; Supercomputers;
fLanguage
English
Publisher
ieee
Conference_Titel
Parallel & Distributed Processing, 2009. IPDPS 2009. IEEE International Symposium on
Conference_Location
Rome
ISSN
1530-2075
Print_ISBN
978-1-4244-3751-1
Electronic_ISBN
1530-2075
Type
conf
DOI
10.1109/IPDPS.2009.5160861
Filename
5160861
Link To Document