Virtualização em Redes Terrestre-Satélite 5G
Resumo
In order to propose a hybrid terrestrial-satellite architecture for the 5G infrastructure in Brazil, it is sought to discover and understand the resources and tools used in the simulation or emulation of these network architectures for performance analysis purposes when evaluating various technological interoperability scenarios. Based on the main projects of the European Commission H2020 and standardization organizations of the 5G network, such as 3GPP, ETSI, ITU, among others, this article investigates how the standardization and implementation of 5G terrestrial network management and virtualization technologies are being applied. It highlights the use cases and the tools used in their investigations.
Palavras-chave:
5G, Virtualização, Analise de Performance
Referências
3GPP (2015). Telecommunication management; study on network management of virtu-alized networks. In Release 13.
3GPP (2016a). Tr 32.842 study on network management of virtualized networks. In 3GPP.
3GPP (2016b). Tr 38.913 study on scenarios and requirements for next genera-tion access technologies. In Release 14. [Online: 12/12/2015] Disponível em: http://www.3gpp.org/DynaReport/38913.htm Acesso em: 19/07/2018às 13:40.
5G, A. (2016). 5g americas white papers. http://www.5gamericas.org/pt-br/resources/white-papers/, Novembro.
A. Siris, Y. Thomas, G. P. (2016). Supporting the iot over integrated satellite-terrestrial networks using information-centric networking. In 8th IFIP Int. Conf. New Tech. Mobi. Secur. NTMS 2016, volume 16, pages 03-07.
Abdelwahab, S., Hamdaoui, B., Guizani, M., and Znati, T. (2016). Network function virtualization in 5g. IEEE Communications Magazine, 54(4):84-91.
B. Zoran, B. Bakmaz, M. B. (2016). Vision and enabling technologies of tactile internet realization. In Adv. Tech., Sys. and Ser. in Teleco. (TELSIKS), volume 16, pages 01-07.
Ejaz, W., Anpalagan, A., Imran, M. A., Jo, M., Naeem, M., Qaisar, S. B., and Wang, W. (2016). Internet of things (iot) in 5g wireless communications. IEEE Access, 4:10310-10314.
G. Arfaoui, P. Bisson, R. B. R. B. H. E. E. F. F. K. P. K. N. M. N. P. O. J. P. J. S. M. S. J.-P. W. e. A. Z. (2018). A security architecture for 5g networks. In IEEE Access, volume 06, pages 22466-22479.
Jin Liu, S. Sharma, K. S. (2016). Initial access, mobility, and user-centric multi-beam operation in 5g new radio. In IEEE Communications Magazine, volume 18, pages 68-84.
JMeter, A. (2019). In JMeter. [Online]: Disponível em: https://jmeter.apache.org. Acesso em: 26/03/2019às 11:21.
Konstantinos Liolis, Alexander Geurtz, R. S. N. C. (2018). Use cases and scenarios of 5g integrated satellite-terrestrial networks for enhanced mobile broadband: The sat5g approach. International Journal of Satellite Communications and Networking, Maio.
M. De Sanctis, E. Cianca, G. A. I. B. R. P. (2016). Satellite communications supporting internet of remote things. In IEEE Int. of Th. J., volume 03, pages 113-123.
M.C. Parker, G. Koczian, S. W. K. H. V. J. T. R. I. N. M. S. P. K. e. P. J. (2017). Ultra-low latency 5g charisma architecture for secure intelligent transportation verticals. In 2017 19th International Conference on Transparent Optical Networks (ICTON), volume 06.
Naser Al-Falahy, O. Y. A. (2017). Technologies for 5g networks: Challenges and oppor-tunities. In IEEE IT Professional, volume 19.
NGINX (2019). Nginx. [Online]: Disponível em: https://www.nginx.com/resources/wiki/. Acesso em: 29/03/2019às 14:20.
OpenAirInterface, S. A. (2019). In Open Air Interface. [Online]: Disponível em: https://www.openairinterface.org/. Acesso em: 28/03/2019às 17:07.
OpenNebula, P. (2019). In OpenNebula. [Online]: Disponível em: https://opennebula.org/key-features/. Acesso em: 01/04/2019às 13:45.
OvS, L. F. (2019). In OpenvSwitch. [Online]: 01/11/2017 Disponível em: https://www.openvswitch.org/. Acesso em: 25/03/2019às 16:44.
R. Ferrús, H. Koumaras, O. S. e. a. (2015). Sdn/nfv-enabled satellite communications: Ground segment network architecture for 5g integration. Physical Communication.
S. Parkvall, E. Dahlman, A. F. M. F. (2017). Nr: The new 5g radio access technology. In IEEE Communications Standards Magazine, volume 1, pages 68-84.
SaT5G, H. (2018). Sat5g project h2020. http://sat5g-project.eu, Junho.
Szymanski, T. (2017). Strengthening security and privacy in an ultra-dense green 5g radio access network for the industrial and tactile internet of things. Wire. Commun. and Mob. Comp. Conf. (IWCMC), page 01-08.
T. Pasca, S. Dama, V. S. K. K. (2017). A feasible cellular internet of things. In IEEE Consum. Elect. Mag., volume 16, pages 66-72.
Y. Kawamoto, H. Nishiyama, Z. M. F. (2013). Effective data collection via satellite-routed sensor system (srss) to realize global-scaled internet of things. In IEEE Sens. J., volume 13, page 3645-3654.
3GPP (2016a). Tr 32.842 study on network management of virtualized networks. In 3GPP.
3GPP (2016b). Tr 38.913 study on scenarios and requirements for next genera-tion access technologies. In Release 14. [Online: 12/12/2015] Disponível em: http://www.3gpp.org/DynaReport/38913.htm Acesso em: 19/07/2018às 13:40.
5G, A. (2016). 5g americas white papers. http://www.5gamericas.org/pt-br/resources/white-papers/, Novembro.
A. Siris, Y. Thomas, G. P. (2016). Supporting the iot over integrated satellite-terrestrial networks using information-centric networking. In 8th IFIP Int. Conf. New Tech. Mobi. Secur. NTMS 2016, volume 16, pages 03-07.
Abdelwahab, S., Hamdaoui, B., Guizani, M., and Znati, T. (2016). Network function virtualization in 5g. IEEE Communications Magazine, 54(4):84-91.
B. Zoran, B. Bakmaz, M. B. (2016). Vision and enabling technologies of tactile internet realization. In Adv. Tech., Sys. and Ser. in Teleco. (TELSIKS), volume 16, pages 01-07.
Ejaz, W., Anpalagan, A., Imran, M. A., Jo, M., Naeem, M., Qaisar, S. B., and Wang, W. (2016). Internet of things (iot) in 5g wireless communications. IEEE Access, 4:10310-10314.
G. Arfaoui, P. Bisson, R. B. R. B. H. E. E. F. F. K. P. K. N. M. N. P. O. J. P. J. S. M. S. J.-P. W. e. A. Z. (2018). A security architecture for 5g networks. In IEEE Access, volume 06, pages 22466-22479.
Jin Liu, S. Sharma, K. S. (2016). Initial access, mobility, and user-centric multi-beam operation in 5g new radio. In IEEE Communications Magazine, volume 18, pages 68-84.
JMeter, A. (2019). In JMeter. [Online]: Disponível em: https://jmeter.apache.org. Acesso em: 26/03/2019às 11:21.
Konstantinos Liolis, Alexander Geurtz, R. S. N. C. (2018). Use cases and scenarios of 5g integrated satellite-terrestrial networks for enhanced mobile broadband: The sat5g approach. International Journal of Satellite Communications and Networking, Maio.
M. De Sanctis, E. Cianca, G. A. I. B. R. P. (2016). Satellite communications supporting internet of remote things. In IEEE Int. of Th. J., volume 03, pages 113-123.
M.C. Parker, G. Koczian, S. W. K. H. V. J. T. R. I. N. M. S. P. K. e. P. J. (2017). Ultra-low latency 5g charisma architecture for secure intelligent transportation verticals. In 2017 19th International Conference on Transparent Optical Networks (ICTON), volume 06.
Naser Al-Falahy, O. Y. A. (2017). Technologies for 5g networks: Challenges and oppor-tunities. In IEEE IT Professional, volume 19.
NGINX (2019). Nginx. [Online]: Disponível em: https://www.nginx.com/resources/wiki/. Acesso em: 29/03/2019às 14:20.
OpenAirInterface, S. A. (2019). In Open Air Interface. [Online]: Disponível em: https://www.openairinterface.org/. Acesso em: 28/03/2019às 17:07.
OpenNebula, P. (2019). In OpenNebula. [Online]: Disponível em: https://opennebula.org/key-features/. Acesso em: 01/04/2019às 13:45.
OvS, L. F. (2019). In OpenvSwitch. [Online]: 01/11/2017 Disponível em: https://www.openvswitch.org/. Acesso em: 25/03/2019às 16:44.
R. Ferrús, H. Koumaras, O. S. e. a. (2015). Sdn/nfv-enabled satellite communications: Ground segment network architecture for 5g integration. Physical Communication.
S. Parkvall, E. Dahlman, A. F. M. F. (2017). Nr: The new 5g radio access technology. In IEEE Communications Standards Magazine, volume 1, pages 68-84.
SaT5G, H. (2018). Sat5g project h2020. http://sat5g-project.eu, Junho.
Szymanski, T. (2017). Strengthening security and privacy in an ultra-dense green 5g radio access network for the industrial and tactile internet of things. Wire. Commun. and Mob. Comp. Conf. (IWCMC), page 01-08.
T. Pasca, S. Dama, V. S. K. K. (2017). A feasible cellular internet of things. In IEEE Consum. Elect. Mag., volume 16, pages 66-72.
Y. Kawamoto, H. Nishiyama, Z. M. F. (2013). Effective data collection via satellite-routed sensor system (srss) to realize global-scaled internet of things. In IEEE Sens. J., volume 13, page 3645-3654.
Publicado
25/09/2019
Como Citar
ALBERTI, Antonio Marcos ; COSTA, Karine ; TAVARES REZENDE, Tibério Tavares.
Virtualização em Redes Terrestre-Satélite 5G. In: WORKSHOP DE TEORIA, TECNOLOGIAS E APLICAÇÕES DE SLICING PARA INFRAESTRUTURAS SOFTWARIZADAS (WSLICE), 1. , 2019, Gramado.
Anais [...].
Porto Alegre: Sociedade Brasileira de Computação,
2019
.
p. 69-82.
DOI: https://doi.org/10.5753/wslice.2019.7723.
