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Avtomatika i Telemekhanika, 2010, Issue 12, Pages 166–177 (Mi at1124)  

This article is cited in 18 scientific papers (total in 18 papers)

Technical Diagnostics

An invariant extension method for system area networks of multicore computational systems. An ideal system network

M. F. Karavai, V. S. Podlazov

Trapeznikov Institute of Control Sciences, Russian Academy of Sciences, Moscow, Russia
References:
Abstract: We present a method of extending non-blocking self-routing uniform system area networks that preserves the specified properties. The method is based on the mathematical theory of complete balanced block designs, studied in combinatorics.
Presented by the member of Editorial Board: P. P. Parkhomenko

Received: 11.01.2010
English version:
Automation and Remote Control, 2010, Volume 71, Issue 12, Pages 2644–2654
DOI: https://doi.org/10.1134/S0005117910120131
Bibliographic databases:
Document Type: Article
Language: Russian
Citation: M. F. Karavai, V. S. Podlazov, “An invariant extension method for system area networks of multicore computational systems. An ideal system network”, Avtomat. i Telemekh., 2010, no. 12, 166–177; Autom. Remote Control, 71:12 (2010), 2644–2654
Citation in format AMSBIB
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\paper An invariant extension method for system area networks of multicore computational systems. An ideal system network
\jour Avtomat. i Telemekh.
\yr 2010
\issue 12
\pages 166--177
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\mathscinet{http://mathscinet.ams.org/mathscinet-getitem?mr=2791089}
\zmath{https://zbmath.org/?q=an:1225.05036}
\transl
\jour Autom. Remote Control
\yr 2010
\vol 71
\issue 12
\pages 2644--2654
\crossref{https://doi.org/10.1134/S0005117910120131}
\isi{https://gateway.webofknowledge.com/gateway/Gateway.cgi?GWVersion=2&SrcApp=Publons&SrcAuth=Publons_CEL&DestLinkType=FullRecord&DestApp=WOS_CPL&KeyUT=000286602200013}
Linking options:
  • https://www.mathnet.ru/eng/at1124
  • https://www.mathnet.ru/eng/at/y2010/i12/p166
  • This publication is cited in the following 18 articles:
    1. V. S. Podlazov, “Samomarshrutiziruemaya neblokiruemaya sistemnaya set s pryamymi kanalami: slozhnost i bystrodeistvie”, Programmnye sistemy: teoriya i prilozheniya, 13:4 (2022), 47–76  mathnet  crossref
    2. E. A. Barabanova, K. A. Vytovtov, V. S. Podlazov, “Two-stage dual photon switches in an extended scheme basis”, Control Sciences, 1 (2021), 60–69  mathnet  crossref  crossref
    3. E. A. Barabanova, K. A. Vytovtov, V. S. Podlazov, “Non-blocking fault-tolerant two-stage dual photon switches”, Control Sciences, 2021, no. 4, 67–76  mathnet  crossref  crossref
    4. V. S. Podlazov, “Non-blocking fault-tolerant dual photon switches with high scalability”, Control Sciences, 2021, no. 5, 61–76  mathnet  crossref  crossref
    5. E A Barabanova, K A Vytovtov, V M Vishnevsky, V S Podlazov, “The method for constructing fault-tolerant photonic switches for high-performance computing systems”, J. Phys.: Conf. Ser., 2091:1 (2021), 012032  crossref
    6. V. S. Podlazov, M. F. Karavai, “Rasshirenie vozmozhnostei sistemnoi seti «Angara»”, Probl. upravl., 2 (2020), 47–56  mathnet  crossref
    7. V. S. Podlazov, “Otkazoustoichivyi neblokiruemyi trekhmernyi razrezhennyi giperkub”, Probl. upravl., 3 (2020), 59–69  mathnet  crossref
    8. M. F. Karavai, V. S. Podlazov, “Optimalnye otkazoustoichivye mnogomernye tory na osnove maloportovykh marshrutizatorov i khabov”, Probl. upravl., 5 (2020), 56–64  mathnet  crossref
    9. V. S. Podlazov, “Conflict-Free Self-Routing for a Three-Dimensional Complete Multiring”, Autom Remote Control, 80:5 (2019), 936  crossref
    10. V. S. Podlazov, “Beskonfliktnaya samomarshrutizatsiya dlya trekhmernogo polnogo multikoltsa”, Probl. upravl., 4 (2018), 54–60  mathnet  crossref
    11. V. S. Podlazov, “A Comparison of System Area Networks: Generalized Extended Multiring vs Flattened Butterfly”, Automation and Remote Control, 79:3 (2018), 571–580  mathnet  crossref
    12. M. F. Karavai, V. S. Podlazov, “Topologicheskie rezervy «splyuschennykh» sistemnykh setei”, Vestn. YuUrGU. Ser. Vych. matem. inform., 5:2 (2016), 84–94  mathnet  crossref  elib
    13. V. S. Podlazov, “Extended multiring of diameter 2”, Automation and Remote Control, 78:11 (2017), 2075–2084  mathnet  crossref
    14. M. F. Karavai, V. S. Podlazov, “Small-diametr system area network composed from small-port routers”, Autom. Remote Control, 78:9 (2017), 1674–1679  mathnet  mathnet  crossref
    15. V. S. Podlazov, “Boosting performance of multidimentional rings”, Autom. Remote Control, 78:1 (2017), 167–179  mathnet  mathnet  crossref  isi
    16. M. F. Karavai, V. S. Podlazov, “Extended generaized hypercube as fail-safe system network for multiprocessor systems”, Autom. Remote Control, 76:2 (2015), 336–352  mathnet  crossref  isi
    17. M. F. Karavai, V. S. Podlazov, “Distributed full switch as an ideal system area network for multiprocessor computers”, Autom Remote Control, 74:4 (2013), 710  crossref
    18. M. F. Karavai, V. S. Podlazov, “Raspredelennyi polnyi kommutator kak «idealnaya» sistemnaya set dlya mnogoprotsessornykh vychislitelnykh sistem”, UBS, 34 (2011), 92–116  mathnet
    Citing articles in Google Scholar: Russian citations, English citations
    Related articles in Google Scholar: Russian articles, English articles
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