Abstract
This paper suggests a novel structure of a system area network for high-performance multiprocessor computers. The authors consider a system area network in the form of an extended generalized hypercube, where complete graph topology links in rows are replaced by quasicomplete graph topology links with an appreciably smaller number of edges.
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Karavay, M.F. and Podlazov, V.S., Topological Reserve of Supercomputer Interconnect, Upravlen. Bol’shimi Sist., 2013, no. 41, pp. 395–423.
Karavay, M.F. and Podlazov, V.S., An Invariant Extension Method for System Area Networks of Multicore Computational Systems. An Ideal System Network, Autom. Remote Control, 2010, vol. 71, no. 12, pp. 2644–2654.
Karavay, M.F. and Podlazov, V.S., Distributed Full Switch as an Ideal System Area Network for Multiprocessor Computers, Autom. Remote Control, 2013, vol. 74, no. 4, pp. 710–724.
Karavay, M.F., Podlazov, V.S., and Sokolov, V.V., Method to Build Non-Blocked Self-Routed Expanded Commutator, RF Patent RU 2 435 295, Byull. Izobret., 2011, no. 33.
Karavay, M.F. and Podlazov, V.S., Extended Block Designs for Ideal System Area Networks, Autom. Remote Control, 2013, vol. 74, no. 12, pp. 2180–2188.
Karavay, M.F. and Podlazov, V.S., The Network-centric Approach to Fault-Tolerance in Real-Time Multiprocessor Systems, Tr. IV konf. po problemam upravleniya (Proc. IV Conf. on Control Problems), Divnomorskoe, 2011, vol. 1, pp. 305–308.
Karavay, M.F. and Podlazov, V.S., System Area Networks with Direct Channels for Multiprocessor Computational Systems-Ideal System Area Networks, Palmarium Academic Publishing, 2012, URL: http://www.ipu.ru/sites/default/files/publications/18125/3747-18125.pdf (cited September 14, 2013).
Alverson, R., Roweth, D., and Kaplan, L., The Gemini System Interconnect, The 18th IEEE Symp. on High Performance Interconnects, 2009, pp. 83–87.
Arimili, B., Arimili, R., Chung, V., et al., The PERCS High-Performance Interconnect, The 18th IEEE Symp. on High Performance Interconnects, 2009, pp. 75–82.
Bhuyan, L.N. and Agrawal, D.P., Generalized Hypercube and Hyperbus Structures for a Computer Network, IEEE Trans. Comput., 1984, vol. C-33, no. 4, pp. 323–333.
Graph 500 List, June, 2012, URL: http://www.graph500.org/results june 2012 (cited September 14, 2013).
Hruska, J., After Years of Work IBM, NCSA Cancel “BlueWaters” Supercomputer, August, 2011, URL: http://hothardware.com/News/After-Years-of-Work-IBM-NCSA-Cancel-Blue-Waters-Supercomputer (cited September 14, 2013).
Ziavras, S.G. and Krishnamurthy, S., Evaluating the Communications Capabilities of the Generalized Hypercube Interconnection Network, Concurrency: Pract. Experience, 1999, vol. 11, no. 6, pp. 281–300.
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Original Russian Text © M.F. Karavay, V.S. Podlazov, 2013, published in Upravlenie Bol’shimi Sistemami, 2013, No. 45, pp. 344–371.
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Karavay, M.F., Podlazov, V.S. An extended generalized hypercube as a fault-tolerant system area network for multiprocessor systems. Autom Remote Control 76, 336–352 (2015). https://doi.org/10.1134/S0005117915020137
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DOI: https://doi.org/10.1134/S0005117915020137