Seguridad en redes SDN y sus aplicaciones

Autores/as

  • Robin Tapiero Universidad Distrital Francisco José de Caldas
  • Alejandro Gonzalez Universidad Distrital Francisco José de Caldas
  • Norberto Novoa Universidad Distrital Francisco José de Caldas

DOI:

https://doi.org/10.24054/rcta.v1i37.1262

Palabras clave:

: Software-Defined Networking (SDN), IoT, Network Function Virtualization (NFV), ONF, OpenFlow

Resumen

Las redes SDN (redes definidas por software) son el avance que se estaba esperando desde que las necesidades del mercado empezaron a sobrepasar la capacidad de procesamiento que la infraestructura de las redes tradicionales ha estado ofreciendo. Actualmente las conexiones en la nube y el internet de las cosas requieren más conexiones de dispositivos en la red y un mejor control de tráfico, estimulando la mejora continua de la misma, por este caso, se hizo necesario la implementación de una nueva red que sea escalable y que brinde mejores servicios de los que ofrece actualmente las redes tradicionales, garantizando aspectos como integridad, confiabilidad, disponibilidad de la información y análisis de tráfico. El presente artículo, expone una revisión descriptiva de la arquitectura de las redes SDN, su enfoque en la seguridad y las aplicaciones que ejecutan estas redes en la actualidad.

Descargas

Los datos de descargas todavía no están disponibles.

Citas

Cinco factores que frenan la instalación de redes de los operadores, El financiero, diciembre 2019. [En línea]. Disponible en: https://www.elfinancierocr.com/tecnologia/cinco-factores-que-frenan-la-instalacion-de-redes-de-losoperadores/S6OKPK6YK5DJTPSZK6S74B3DLM/story/

W. Haisang, “From Clean Slate to SDN,” Huawei Corp, octubre 2019. [En línea]. Disponible en: https://www.huawei.com/en/industry-insights/outlook/europe-strengths-encourage-digital-investment.

T. Nadeau and K. Gray, An Auhoritative Review of Network Programmability. Technologies. 2013.

D. Maldonado, “Diseño e implementación de una aplicación bajo una Arquitectura SDN,” Pontif. Univ. Javeriana-Bogotá, pp. 1–80, 2014.

N. McKeown, T. Anderson, H. Balakrishnan, G. Parulkar, L. Peterson, J. Rexford, S. Shenker, and J. Turner, “OpenFlow,” ACM SIGCOMM Comput. Commun. Rev, vol. 38, no. 2, p. 69, Doi:10.1145/1355734.1355746. marzo 2016.

Stanford University, “Ethane: una arquitectura de protección para redes empresariales”. Octubre 2019 [Online]. Disponible en: http://yuba.stanford.edu/ethane/.

Radius Stories at the Edge, “Redes y seguridad” marzo 2018. [Online]. Disponible en: https://www.vmware.com/radius/topic/network-security/.

R. Hernández Sampieri, C. Fernández Collado, and M. D. P. Baptista Lucio,

Metodología de la investigación. Bogotá: MC GRAW HILL. 2014. PP. 92-100.

Open Networking Foundation, “Arquitectura de las redes definidas por software (SDN),” noviembre 2019. [En línea]. Disponible en: www.opennetworking.org.

B. Valencia, S. Santacruz, and L. Y. B. J. J. Padilla, “Mininet: una herramienta versátil para emulación y prototipado de Redes Definidas por Software 1 Mininet”. Entre ciencia e ingeniería, Vol. 17, pp. 62–70, 2015.

M. I. Hamed, B. M. Elhalawany, M. M. Fouda, and A. S. T. Eldien, “A Novel Approach for Resource Utilization and Management in SDN”, International Computer Engineering Conference (ICENCO), 2017, pp. 5–7.

B. Pandya, “Framework for Securing SDN Southbound communication”, International Conference on Innovations in Information, Embedded and Communication Systems (ICIIECS), 2017, pp. 6–9.

A. Jalili, H. Nazari, S. Namvarasl, and M. Keshtgari, “A Comprehensive analysis on Control Plane Deployment in SDN: In-Band versus Out-of-Band solutions” IEEE 4th International Conference on Knowledge-Based Engineering and Innovation (KBEI), 2017, pp. 1025–1031.

L. Richarson and S. Ruby, “RESTful Web Services”. EEUU: O’REILLY, 2008, PP 94-102.

K. Pentikousis, Y. Wang, and W. Hu, “Mobile Flow: Toward Software-Defined Mobile Networks,” IEEE Commun. Mag, vol. 51, 2013, pp. 44–53.

J. Tourrilhes, P. Sharma, S. Banerjee, and J. Pettit, “SDN and OpenFlow Evolution: A Standards Perspective,” Computer (Long. Beach. Calif), vol. 47. 2014, p. 22–29.

W. Zhou, L. Li, and W. Chou, “SDN Northbound REST API with Efficient Caches”. International Conference on Web Services, 2014, p. 257–264.

W. Zhou, L. Li, M. Luo, and W. Chou, “REST API Design Patterns for SDN Northbound API”. 28th International Conference on Advanced Information Networking and Applications Workshops, 2014, p. 358–365.

SDX Central, “What is VMware NSX and VMware SDN Network Virtualization?”, noviembre 2019. [En línea]. Disponible en: https://www.sdxcentral.com/vmware/definitions/what-is-vmware-nsx/.

P. Morreale and J. Anderson, “Software Defined Networking,” Univ. Politec. Catalunya, noviembre 2014. p. 1–67.

B. Y. Yoon and J.-H. Lee, “Transport SDN Architecture for Distributed Cloud Services”, 12th International Conference on Optical Internet 2014. pp. 14–15

L. Cui, F. R. Yu, and Q. Yan, “When big data meets software-defined networking: SDN for big data and big data for SDN,” IEEE Netw., vol. 30, junio 2016. p. 58–65.

H. Jang and J. Lin, “SDN Based QoS Aware Bandwidth Management Framework of ISP for Smart Homes,” 2017 IEEE SmartWorld, Ubiquitous Intell. Comput. Adv. Trust. Comput. Scalable Comput. Commun. Cloud Big Data Comput. Internet People Smart City Innov. 2017. pp. 1– 6.

A. Mckeown, H. Rashvand, T. Wilcox, and P. Thomas, “Priority SDN Controlled Integrated Wireless and Powerline Wired for Smart-Home Internet of Things”, in 2015 IEEE 12th Intl Conf on Ubiquitous Intelligence and Computing and 2015 IEEE 12th Intl Conf on Autonomic and Trusted Computing and 2015 IEEE 15th Intl Conf on Scalable Computing and Communications and Its Associated Workshops (UIC-ATC-ScalCom), 2015. p. 1825–1830.

T. Theodorou and L. Mamatas, “CORAL-SDN: A software-defined networking solution for the Internet of Things”, 2017 IEEE Conference on Network Function Virtualization and Software Defined Networks (NFV-SDN), 2017, p. 1–2.

P. Bosshart, D. Daly, M. Izzard, N. McKeown, J. Rexford, C. Schlesinger, D. Talayco, A. Vahdat, G. Varghese, and D. Walker, “Programming Protocol- Independent Packet Processors”, ACM DIGITAL LIBRARY. 2013. vol. 44, p. 88–95

“Open Source Mano – ETSI”, OSM, noviembre 2019, [En línea]. Disponible en: https://osm.etsi.org/.

R. Bifulco and R. Canonico, “Analysis of the handover procedure in Follow-Me Cloud,” 2012 1st IEEE Int. Conf. Cloud Networking, CLOUDNET 2012, 2012. PP 185–187.

M. B. Al-Somaidai, “Survey of Software Components to Emulate OpenFlow Protocol as an SDN Implementation,” Am. J. Softw. Eng. Appl, 2014, vol. 3, no. 6, p. 74.

S. Ali and M. Ghazal, “Real-time Heart Attack Mobile Detection Service (RHAMDS): An IoT use case for Software Defined Networks” in 2017 IEEE 30th Canadian Conference on Electrical and Computer Engineering (CCECE), 2017, p. 1–6.

P. Demestichas, A. Georgakopoulos, D. Karvounas, K. Tsagkaris, V. Stavroulaki, J. Lu, C. Xiong, and J. Yao, “5G on the Horizon: Key Challenges for the Radio-Access Network” IEEE Veh Technol Mag, 2013. vol. 8, p. 47–53.

A. De La Oliva, X. C. Perez, A. Azcorra, A. Di Giglio, F. Cavaliere, D. Tiegelbekkers, J. Lessmann, T. Haustein, A. Mourad, and P. Iovanna, “Xhaul: toward an integrated fronthaul/backhaul architecture in 5G networks” IEEE Wirel. Commun, 2015, vol. 22, PP 32–40.

A. Sutton, “5G network architecture,” J. Inst. Telecommun. Prof, 2018, vol. 12, pp. 8–15, 2018.

X. Costa Perez, A. Garcia Saavedra, L. XI, T. Deiss, and O. De La Antonio, “5G- Rosshaul: an Sdn / Nfv Integrated Fronthaul / Backhaul Transport Network Architecture” vol. 24, no. February,2017, pp. 38–45.

“Cisco Visual Networking Index: Global Mobile Data Traffic Forecast Update, 2016–2021 White Paper - Cisco”, Cisco, noviembre 2019, [En línea]. Disponible en: https://www.cisco.com/c/dam/m/en_in/innovation/enterprise/assets/mobile-white-paper-c11-520862.pdf.

“P4 Language Consortium”, Git Hub, noviembre 2019, [En línea]. Disponible en: https://p4.org/.

G. Bianchi, E. Biton, N. Blefari-Melazzi, I. Borges, L. Chiaraviglio, P. de la Cruz Ramos, P. Eardley, F. Fontes, M. J. McGrath, L. Natarianni, D. Niculescu, C. Parada, M. Popovici, V. Riccobene, S. Salsano, B. Sayadi, J. Thomson, C. Tselios, and G. Tsolis, “Superfluidity: a flexible functional architecture for 5G networks,” Trans. Emerg. Telecommun. Technol. 2016, vol. 27, p. 1178–1186.

Open Networking Lab (ON. Lab), “ON. Lab Delivers Software for New Open Source SDN Network Operating System - ONOS”, 2017. [En línea]. Disponible en: https://www.prnewswire.com/news-releases/onlab-delivers-software-for-new- open-source-sdn-network-operating-system--onos-300004797.html.

J. Teixeira, G. Antichi, A. Del Chiaro, S. Giordano, and A. Santos, “Datacenter in a Box: Test Your SDN Cloud-Datacenter Controller at Home” in 2013 Second European Workshop on Software Defined Networks, 2013, p. 99–104.

A. Asensio, L. Gifre, M. Ruiz, and L. Velasco, “Carrier SDN for flexgrid-based inter-datacenter connectivity” in 2014 16th International Conference on Transparent Optical Networks (ICTON), 2014, PP 1– 4.

P. Varga, G. Kathareios, A. Mate, R. Clauberg, A. Anghel, P. Orosz, B. Nagy,

T. Tothfalusi, L. Kovacs, and M. Gusat, “Real-time security services for SDN- based datacenters,” in 2017 13th International Conference on Network and Service Management (CNSM), 2017, PP 1–9.

W. Hong, K. Wang, and Y H. Hsu, “Application-Aware Resource Allocation for SDN-based Cloud Datacenters,” in 2013 International Conference on Cloud Computing and Big Data, 2013, p. 106–110.

P. Samadi, D. Calhoun, H. Wang, and K. Bergman, “Accelerating Cast Traffic Delivery in Data Centers Leveraging Physical Layer Optics and SDN” IFIP Int. Conf. Opt. Netw. Des. Model, 2014, PP 73–77.

Y. Han, S. Seo, J. Li, J. Hyun, J. Yoo, and J. Hong, “Software defined networking-based traffic engineering for data center networks” Netw. Oper. Manag. Symp. (APNOMS), 2014 16th Asia-Pacific, 2014, p. 1–6.

I. Elgendi, K Munasinghe, and A. Jamalipour, “A three-tier SDN architecture for DenseNets” in 2015 9th International Conference on Signal Processing and Communication Systems (ICSPCS), 2015, vol. 1, p. 1–7.

I. Monga, E. Pouyoul, and C. Guok, “Software-Defined Networking for Big- Data Science - Architectural Models from Campus to the WAN” in 2012 SC Companion: High Performance Computing, Networking Storage and Analysis, 2012, p. 1629–1635.

“ITU- Software-defined Networking (SDN)”, ITU, noviembre 2019 [En línea]. Disponible en: https://www.itu.int/en/ITU-T/sdn/Pages/default.aspx.

P. Qin, B. Dai, B. Huang, and G. Xu, “Bandwidth-Aware Scheduling With SDN in Hadoop: A New Trend for Big Data,” IEEE Syst, diciembre 2017, vol. 11, PP. 2337– 2344.

A. Khan and B. Ratha, “Time series prediction QoS routing in software defined vehicular ad-hoc network” in 2015 International Conference on Man and Machine Interfacing (MAMI), 2015, PP 1–6.

P. Jayashree and F. Princy, “Leveraging SDN to Conserve Ener in WSN An Analysis” 2015 3rd Int. Conf. Signal Process. Commun. Netw, 2015. PP 6-15.

S. Jain, M. Zhu, J. Zolla, U. Hölzle, S. Stuart, A. Vahdat, A. Kumar, S. Mandal,

J. Ong, L. Poutievski, A. Singh, S. Venkata, J. Wanderer and J. Zhou, “B4,” in Proceedings of the ACM SIGCOMM 2013 conference on SIGCOMM - SIGCOMM 13, 2013, PP 3.

S. Lazar and C. Stefan, “Future vehicular networks: ¿what control technologies?” Commun. (COMM), 2016 Int. Conf, PP 337–340.

E. Ali, M. Manel and Y. Habib, “An Efficient MPLS-Based Source Routing Scheme in Software-Defined Wide Area Networks (SD-WAN)” in 2017 IEEE/ACS 14th International Conference on Computer Systems and Applications (AICCSA), 2017, PP. 1205–1211.

E. Rojas, “From Software-Defined to Human-Defined Networking: Challenges and Opportunities,” IEEE Netw, enero 2018, vol. 32, p. 179–185.

T. Ninikrishna, S. Sarkar, R. Tengshe, M. Jha, L. Sharma, V. Daliya and

S. Routray, “Software defined IoT: Issues and challenges” Proc. Int. Conf. Comput. Methodol. Commun. ICCMC 2017, vol. 2018, PP. 723–726.

M. Ketel, “Enhancing BYOD Security through SDN” SoutheastCon 2018, pp. 1–2.

“IRTF Software-Defined Networking Research Group (SDNRG)”, IRTF, noviembre 2019, [En línea]. Disponible en: https://irtf.org/concluded/sdnrg.

H. Jang, C. Huang and F. Yeh, “Design a bandwidth allocation framework for SDN based smart home” 7th IEEE Annu. Inf. Technol. Electron. Mob. Commun. Conf. IEEE IEMCON 2016, pp 6-12.

Huawei Technologies Inc, “Huawei Agile Campus Network Solution Brochure” noviembre 2019. [En línea]. Disponible en: https://e.huawei.com/ru/related-page/solutions/technical/agile-networking/agile-campus-solutions/agile-campus/brochure/Solutions_Campus_network.

SdxCentral LLC, “Network Virtualization Report” Ind. Rep. pp 1–44, 2017.

J. Rodriguez, “Integración de redes IP utilizando SDN” Inst. Tecnológico Buenos Aires, 2017, PP 27-32.

ON. LAB, “Introducing ONOS - a SDN network operating system for Service Providers”, Technical report, 2014, vol. 1, p. 14.

J. Medve, R. Varga and A. Tkacik, “OpenDaylight: Towards a model-driven SDN controller architecture,” rock. IEEE 15th Int. Symp. World Wireless, Mob. Multimed. Netw,2014, pp. 1–6.

M. Paliwal, D. Shrimankar, and O. Tembhurne, “Controllers in SDN: A Review Report” IEEE Access, vol. 6, p. 36256–36270.

“ETSI - Network Functions Virtualization”, ETSI, noviembre 2019, [En línea]. Disponible en: https://www.etsi.org/technologies-clusters/technologies/nfv.

Descargas

Publicado

2021-03-13 — Actualizado el 2021-03-13

Cómo citar

[1]
R. Tapiero, A. Gonzalez, y N. Novoa, «Seguridad en redes SDN y sus aplicaciones», RCTA, vol. 1, n.º 37, pp. 108–117, mar. 2021.

Número

Sección

Artículos