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.
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
\Bibitem{KarPod10}
\by M.~F.~Karavai, V.~S.~Podlazov
\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
\mathnet{http://mi.mathnet.ru/at1124}
\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:
V. S. Podlazov, “Samomarshrutiziruemaya neblokiruemaya sistemnaya set s pryamymi kanalami: slozhnost i bystrodeistvie”, Programmnye sistemy: teoriya i prilozheniya, 13:4 (2022), 47–76
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
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
V. S. Podlazov, “Non-blocking fault-tolerant dual photon switches with high scalability”, Control Sciences, 2021, no. 5, 61–76
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
V. S. Podlazov, M. F. Karavai, “Rasshirenie vozmozhnostei sistemnoi seti «Angara»”, Probl. upravl., 2 (2020), 47–56
V. S. Podlazov, “Otkazoustoichivyi neblokiruemyi trekhmernyi razrezhennyi giperkub”, Probl. upravl., 3 (2020), 59–69
M. F. Karavai, V. S. Podlazov, “Optimalnye otkazoustoichivye mnogomernye tory na osnove maloportovykh marshrutizatorov i khabov”, Probl. upravl., 5 (2020), 56–64
V. S. Podlazov, “Conflict-Free Self-Routing for a Three-Dimensional Complete Multiring”, Autom Remote Control, 80:5 (2019), 936
V. S. Podlazov, “Beskonfliktnaya samomarshrutizatsiya dlya trekhmernogo polnogo multikoltsa”, Probl. upravl., 4 (2018), 54–60
V. S. Podlazov, “A Comparison of System Area Networks: Generalized Extended Multiring vs Flattened Butterfly”, Automation and Remote Control, 79:3 (2018), 571–580
M. F. Karavai, V. S. Podlazov, “Topologicheskie rezervy «splyuschennykh» sistemnykh setei”, Vestn. YuUrGU. Ser. Vych. matem. inform., 5:2 (2016), 84–94
V. S. Podlazov, “Extended multiring of diameter 2”, Automation and Remote Control, 78:11 (2017), 2075–2084
M. F. Karavai, V. S. Podlazov, “Small-diametr system area network composed from small-port routers”, Autom. Remote Control, 78:9 (2017), 1674–1679
V. S. Podlazov, “Boosting performance of multidimentional rings”, Autom. Remote Control, 78:1 (2017), 167–179
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
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
M. F. Karavai, V. S. Podlazov, “Raspredelennyi polnyi kommutator kak «idealnaya» sistemnaya set dlya mnogoprotsessornykh vychislitelnykh sistem”, UBS, 34 (2011), 92–116