MPLS technology in quality of service of the WAN network at the National University of Huancavelica.

Authors

DOI:

https://doi.org/10.47796/ves.v11i1.602

Keywords:

: quality of service, multiprotocol label switching, virtual private networks

Abstract

The interconnection data network, between the headquarters and its branches of the National University of Huancavelica, is carried out through the Internet network, which causes the low quality of communication between the branches. The objective of the research was to evaluate the influence of the network model with MPLS technology in improving the quality of service in the WAN network. An explanatory experimental pre-test and post-test study was carried out in a simulation laboratory using the GNS3 and D-ITG software. The population and the sample consisted of the ten WAN networks, and the sampling was non-probabilistic, in each network the quality of service tests were carried out, with the three types of traffic: data, VoIP and Streaming, being the indicators delay, jitter and packet loss for each type of service. The results obtained with IP technology (Delay: 78ms to 292ms and Jitter: 68ms to 13.3ms) and in MPLS (Delay: 13ms to 157.3ms and Jitter: 5.9ms to 12.2ms). It is concluded that the MPLS technology significantly influences the improvement of the quality of communication service between the branches of the university.

Downloads

Download data is not yet available.

Author Biographies

William Danty Ramos Paucar, Universidad Nacional de Huancavelica. Huancavelica, Perú.

Ingeniero Electrónico, Magister en Planeación estratégica y Gestión en Ingeniería de Proyectos, Magíster en Ing. de Telecomunicaciones. william.ramos@unh.edu.pe.  

Celso Ramos Paucar, Universidad Nacional Autónoma de Huanta. Ayacucho, Perú.

Mtro. en Ciencias de la Educación en la USIL. Ingeniero Electrónico en la UNH. Ingeniero Civil en la UAP. Lic. Matemática y Física UNFV-Perú. cramos@unah.edu.pe.

Deniece Cynthia Delgado Pino, Universidad Nacional de Huancavelica, Perú.

Bachiller en Ingeniería de Sistemas, con experiencia en modelos de redes para instituciones públicas y privadas. deniece.delgado@unh.edu.pe.

References

Ariganello, E., y Enrique, B. (2013). REDES CISCO. CCNP a Fondo. Guía de estudio para Profesionales (1ra ed.). Alfaomega Grupo Editor, S.A. de C.V. https://bit.ly/35JJLzV.

Mushtaq, A. y Patterh, M. S. (2018). QOS parameter comparison of DiffServ-aware MPLS network using IPv4 and IPv6. 2017 International Conference on Recent Innovations in Signal processing and Embedded Systems (RISE), 113-118. doi: 10.1109/RISE.2017.8378136.

Bahnasse, A.; Talea, M.; Badri, A. y Louhab, F. E. (2018). New smart platform for automating MPLS virtual private network simulation. 2018 International Conference on Advanced Communication Technologies and Networking (CommNet), 1-8. doi: 10.1109/COMMNET.2018.8360268.

Castro, E. (2015). Diseño y Simulación de una red MPLS para interconectar estaciones remotas utilizando el emulador GNS3. [Tesis de grado, Universidad Politécnica Salesiana]. Repositorio institucional de la UPS. https://bit.ly/3oXsXgk.

Cisco. (2020). Cisco System. https://bit.ly/3wwP3eO.

Cisco. (2015). Cisco Systems. Cisco Virtual Managed Services. https://bit.ly/3qXrQ0c.

IBM. (s.f.). IBM AIX documentation. https://ibm.co/3sv5SFK.

Graphical Network Simulator-3. (s.f.). Documentation. https://bit.ly/3yAmS16.

Hernández Sampieri, R., Fernández Collado, C., y Baptista Lucio, M. (2018). Metodología de la investigación. México: McGraw-Hill Interamericana.

Hucková, I. y Hrubý, M. (2015). QoS-based optimization of data flow in MPLS networks. 2015 IEEE 13th International Symposium on Applied Machine Intelligence and Informatics (SAMI), 83-88. doi: 10.1109/SAMI.2015.7061851.

Internet Engineering Task Force (Ed.) (2020). Estándares de Internet: RFC https://bit.ly/3qYSTJh.

Mehraban, S.; Vora K. B. y Upadhyay, D. (2018). Deploy Multi Protocol Label Switching (MPLS) Using Virtual Routing and Forwarding (VRF). 2018 2nd International Conference on Trends in Electronics and Informatics (ICOEI), 543-548. doi: 10.1109/ICOEI.2018.8553949.

Menedez, R. (2012). Estudio del desempeño e implementación de una solución MPLS-VPN sobre múltiples sistemas autónomos. [Tesis de grado, Pontificia Universidad Católica del Perú]. Repositorio PUCP. https://bit.ly/3oSSO8Z.

Oña, G. D. (2016). Diseño y comparación de redes de acceso MPLS y metro Ethernet integradas a un backbone MPLS para un proveedor de servicio y realización de un prototipo base. [Tesis de grado, Escuela Politécnica Nacional]. Repositorio digital EPN. https://bit.ly/2XLoFwA.

RFC. (Ed.) (2001) RFC-3021. Architecture for Multiprotocol Label Switching. https://bit.ly/3LcYyVD.

Stallings, W. (2012). Comunicaciones y Redes de computadores. Madrid, España: Pearson Educación, S. A.

Unión Internacional de Telecomunicaciones (Ed.) (2020). Rec. UIT-R V.662-2. https://bit.ly/3bBMO0F.

Unión Internacional de Telecomunicaciones (Ed.) (2018). Recomendación G.1010. https://bit.ly/39ZPOSg.

Unión Internacional de Telecomunicaciones (Ed.) (2019). Recomendación Y.1541. https://bit.ly/3sRbwjW.

Yadav S. y Jeyakumar A. (2016). Design of traffic engineered MPLS VPN for protected traffic using GNS simulator. 2016 International Conference on Wireless Communications, Signal Processing and Networking (WiSPNET), 405-409. doi: 10.1109/WiSPNET.2016.7566165.

Yosra, M.; Mohamed A. y Sami, T. (2016). QOS for cognitive radio Ad Hoc Networks. 2016 International Symposium on Signal, Image, Video and Communications (ISIVC), 374-378. doi: 10.1109/ISIVC.2016.7894018.

Zapata, M. (2016). Evaluación de parámetros de calidad de servicio (QOS) para el diseño de una red VPN con MPLS. [Tesis de postgrado, Pontificia Universidad Católica del Ecuador]. Repositorio PUCE. https://bit.ly/2XPMRhi.

Published

2022-05-24

How to Cite

Ramos Paucar, W. D., Ramos Paucar, C., & Delgado Pino, D. C. (2022). MPLS technology in quality of service of the WAN network at the National University of Huancavelica. REVISTA VERITAS ET SCIENTIA - UPT, 11(1), 99–111. https://doi.org/10.47796/ves.v11i1.602