TY - JOUR
T1 - Technologies for exascale systems
AU - Coteus, P. W.
AU - Knickerbocker, J. U.
AU - Lam, C. H.
AU - Vlasov, Y. A.
PY - 2011/9
Y1 - 2011/9
N2 - To satisfy the economic drive for ever more powerful computers to handle scientific and business applications, new technologies are needed to overcome the limitations of current approaches. New memory technologies will address the need for greater amounts of data in close proximity to the processors. Three-dimensional silicon integration will allow more cache and function to be integrated with the processor while allowing more than 1,000 times higher bandwidth communications at low power per channel using local interconnects between Si die layers and between die stacks. Integrated silicon nanophotonics will provide low-power and high-bandwidth optical interconnections between different parts of the system on a chip, board, and rack levels. Highly efficient power delivery and advanced liquid cooling will reduce the electrical demand and facility costs. A combination of these technologies will likely be required to build exascale systems that meet the combined challenges of a practical power constraint on the order of 20 MW with sufficient reliability and at a reasonable cost.
AB - To satisfy the economic drive for ever more powerful computers to handle scientific and business applications, new technologies are needed to overcome the limitations of current approaches. New memory technologies will address the need for greater amounts of data in close proximity to the processors. Three-dimensional silicon integration will allow more cache and function to be integrated with the processor while allowing more than 1,000 times higher bandwidth communications at low power per channel using local interconnects between Si die layers and between die stacks. Integrated silicon nanophotonics will provide low-power and high-bandwidth optical interconnections between different parts of the system on a chip, board, and rack levels. Highly efficient power delivery and advanced liquid cooling will reduce the electrical demand and facility costs. A combination of these technologies will likely be required to build exascale systems that meet the combined challenges of a practical power constraint on the order of 20 MW with sufficient reliability and at a reasonable cost.
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U2 - 10.1147/JRD.2011.2163967
DO - 10.1147/JRD.2011.2163967
M3 - Article
AN - SCOPUS:81555199698
SN - 0018-8646
VL - 55
JO - IBM Journal of Research and Development
JF - IBM Journal of Research and Development
IS - 5
M1 - 6032767
ER -