Geodesic
Visual web-oriented environment of dynamic control of data flow in campus of software defined networks
Modelirovanie i analiz informacionnyh sistem, Tome 26 (2019) no. 1, pp. 63-74.

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Nowadays new innovative approaches based on the technology of software defined networks (SDN) are gaining popularity in the field of computer networks (CN). SDN provide a flexible approach to the processing and control of data flows in CN by separating the control plane and data plane, as well as centralizing the representation of the entire network. In this paper, we propose a software infrastructure and a visual web-oriented environment (SIVE) for dynamic control of data flows in campus SDN based on OpenFlow protocol. It was proposed to use the SIVE as an integrated segment of the campus network of Ryazan State Radio Engineering University. The aim of the work is the development of the SIVE architecture in the form of UML class diagram description, as well as the creation of software methods for organizing effective network interaction of various software systems in SDN based on OpenFlow protocol. A hardware-software test bench based on HP Aruba 2920-24G equipment was developed to confirm the efficiency and reliability of the proposed SIVE. The offered SIVE is the basis for the development of a large class of software systems and SDN components based on OpenFlow protocol.
Keywords: software defined networks, software infrastructure, visual web-oriented environment, OpenDayLight, SIVE, SDN Topology, network interaction, program component. 
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V. P. Koryachko; D. A. Perepelkin; M. A. Ivanchikova; V. S. Byshov. Visual web-oriented environment of dynamic control of data flow in campus of software defined networks. Modelirovanie i analiz informacionnyh sistem, Tome 26 (2019) no. 1, pp. 63-74. http://geodesic.mathdoc.fr/item/MAIS_2019_26_1_a4/

[1] McKeown N. et al., “Openflow: enabling innovation in campus networks”, ACM SIGCOMM Computer Communication Review, 38:2 (2008), 69–74 | DOI

[2] Kobayashi M. et al., “Maturing of OpenFlow and Software-Defined Networking Through Deployments”, Computer Networks, 61 (2014), 151–175 | DOI

[3] Egilmez H.E., Adaptive Video Streaming over OpenFlow Networks with Quality of Service, Thesis for Degree of Master Science in Electrical and Electronics Engineering, Koc University, 2012

[4] Ongaro F., Enhancing quality of service in software-defined networks, Thesis for Degree of Master Science in Computer Engineering, University of Bologna, 2014

[5] GENI: Exploring Network of the Future, http://www.geni.net

[6] Choumas K. et al., “Testbed Innovations for Experimenting with Wired and Wireless Software Defined Networks”, IEEE 35th International Conference (2015), 87–94

[7] Antonenko V. et al., “Towards SDI-bases Infrastructure for supporting science in Russia”, Proceedings SDN and NFV: Next Generation of Computational Infrastructure - 2014, International Science and Technology Conference MoNeTec 2014, 2014, 1–7

[8] Egorov V.B., “Some issues of the SDN concept practical implementation”, Systems and Means of Informatics, 26:1 (2016), 109–120 (in Russian) | MR

[9] Guzev O.Yu., Chizhov I.V., “SDN load balancing for secure networks”, Systems and Means of Informatics, 28:1 (2018), 123–138 (in Russian)

[10] Guzev O.Yu., Chizhov I.V., “SDN load balancing on L3-VPN gateways in data centers interconnection”, Systems and Means of Informatics, 28:1 (2018), 139–155 (in Russian)

[11] Malakhov S.V., Tarasov V.N., Kartashevsky I.V., “Theoretical and experimental research of packet delays in software defined networks”, Infokommunikacionnye tehnologii, 13:4 (2015), 409–413 (in Russian)

[12] Bakhareva N.F, et al., “Management of enterprise software defined networks”, Vestnik Orenburgskogo gosudarstvennogo universiteta, 2015, no. 13(188), 108–113 (in Russian)

[13] OpenDayLight Controller, https://www.opendaylight.org/

[14] Virtual Network MiniNet, http://mininet.org

[15] Perepelkin D., Byshov V., “Visual design environment of dynamic load balancing in software defined networks”, 2017 27th International Conference Radioelektronika, IEEE, 2017, 183–186

[16] Perepelkin D., et al., “Development of architecture of visual program system for distributed data processing in software defined networks”, 2018 28th International Conference Radioelektronika, IEEE, 2018, 281–284

[17] Koryachko V.P., Perepelkin D.A., Analiz i proektirovanie marshrutov peredachi dannyh v korporativnyh setyah, Gorjachaja linija - Telekom, Moscow, 2012 (in Russian)

[18] Perepelkin D.A., Perepelkin A.I., “The Accelerated Algorithm Adaptive Routing in Dynamically Changing Loads on the Lines of Communication in Corporate Network”, Information Technologies, 2011, no. 3, 2–7 (in Russian)

[19] Perepelkin D.A., “Dynamic Corporate Network Structure and Communication Links Loading Formation Based on Routes Pairs Permutations Data”, Information Technologies, 2014, no. 4, 52–60 (in Russian)

[20] Perepelkin D.A., “Conceptual Approach of Dynamic Traffic Formation of Software-Defined Telecommunication Networks with Load Balancing”, Information Technologies, 21:8 (2015), 602–610 (in Russian)

[21] Koryachko V.P., Perepelkin D.A., “Development and research of the mathematical model multipath adaptive routing in telecommunication networks with load balancing”, Electrosvyaz, 2014, no. 12, 27–31 (in Russian)

[22] Perepelkin D.A., “Mathematical model of multipath adaptive routing with heterogeneous load balancing in the course of nodes and communication links dynamic connections in telecommunication networks”, Radioengineering, 2015, no. 5, 46–54 (in Russian)

[23] Perepelkin D.A., “Model of fault-tolerant multipath adaptive routing with load balancing of heterogeneous traffic in communication networks”, Radioengineering, 2015, no. 11, 40–47 (in Russian)

[24] Koryachko V.P., Perepelkin D.A., Byshov V.S., “Improved multipath adaptive routing model in computer networks with load balancing”, Proceedings IEEE 2016 International Siberian Conference on Control and Communications, SIBCON, 2016, 1–4

[25] Koryachko V.P., Perepelkin D.A., Byshov V.S., “Multipath adaptive routing in computer networks with load balancing”, 2016 Mediterranean Conference on Embedded Computing, IEEE, 2016, 281–285 | DOI

[26] Koryachko V.P., Perepelkin D.A., Byshov V.S., “Development and research of improved model of multipath adaptive routing in computer networks with load balancing”, Automatic Control and Computer Sciences, 51:1 (2017), 63–73 | DOI

[27] Perepelkin D.A., Byshov V.S., “Load balancing in software defined networks with quality of services”, Radioengineering, 2016, no. 11, 111–119 (in Russian)

[28] Koryachko V. P., Perepelkin D. A., Byshov V. S., “Enhanced dynamic load balancing algorithm in computer networks with quality of services”, Automatic Control and Computer Sciences, 52:4 (2018), 268–282 | DOI

[29] Perepelkin D.A., “Dynamic traffic formation of corporate networks based on routing method of subnets”, Vestnik of Ryazan State Radio Engineering University, 2015, no. 51, 35–41 (in Russian)

[30] Perepelkin D.A., Tsyganov I.Yu., “Improved algorithm of stuctures segmentation with minimum cost criterion in corporate networks”, Vestnik of Ryazan State Radio Engineering University, 2015, no. 53, 48–57 (in Russian)

[31] Perepelkin D.A., Tsyganov I.Yu., “Proactive backup scheme of routes in distributed computer networks”, Proceedings IEEE 2016 International Siberian Conference on Control and Communications, SIBCON, 2016, 1–4

[32] Perepelkin D.A., Tsyganov I.Yu., “Paired transitions algorithm of communication links in computer networks based on subnet routing method”, 5th Mediterranean Conference on Embedded Computing, IEEE, 2016, 260–263

[33] Perepelkin D., Ivanchikova M., Ivutin A., “Fast rerouting algorithm in distributed computer networks based in subnet routing method”, 2017 27th International Conference Radioelektronika, IEEE, 2017, 187–190

[34] Perepelkin D. et al., “Algorithm and software of virtual slices formation in software defined networks”, 2018 28th International Conference Radioelektronika, IEEE, 2018, 265–268