Modelo para Análise e Otimização de Backbone para Tráfego IPv6 utilizando MPLS-TE
Resumo
A necessidade atual de maior utilização de serviços de redes e internet faz com que haja uma exigência para consolidação e convergência dos serviços, facilitanto assim a administração e a entrega dos serviços, bem como uma maior economicidade dos recursos públicos na prestação dos serviços. Neste contexto, este artigo apresenta um modelo para implementação de redes de nova geração IPv6 sobre MPLS (Multi Protocol Label Switching) permitindo maior gerência e otimização dos recursos de rede disponíveis e com isso, permitir a disponibilização de mais serviços com os recursos existentes.
Palavras-chave:
governo eletrônico
Referências
Akkari Sallum, E. E., dos Santos, G., Alves, M., e Santos,M.M. (2018). Performance analysis and comparison of the DSDV, AODV and OLSR-routing protocols under VANETS. In 2018 16th International Conference on Intelligent Transportation Systems Telecommunications (ITST).
Alam, M., Sher, M., e Husain, A. (2009). Integrated mobility model (IMM) for vanets simulation and its impact. In 2009 International Conference on Emerging Technologies.
Aliesawi, Salah e Mubarek, F., Ali Alheeti, K. M., e M. ALfahad, N. (2018). Urban-AODV: An improved AODV protocol for vehicular Ad-Hoc networks in urban environment. Int. Journal of Engineering e Technology(UAE), 7.
Almohammedi, Akram e Noordin, N. e. S. S. (2016). Evaluating the impact of transmission range on the performance of VANET. Int. Journal of Electrical e Computer Engineering (IJECE).
Alves Jr, J. e Wille, E. (2015). Improving VANETs connectivity with a totally Ad Hoc living mobile backbone. Journal of Computer Networks eCommunications, 2015.
Alves Jr, J. e Wille, E. (2016). P-AOMDV: An improved routing protocol for V2V communication based on public transport backbones. Transactions on Emerging Telecommunications Technologies.
Bettstetter, C. (2002). On the minimum node degree and connectivity of a wireless multihop network. In Proceedings of the 3rd ACM International Symposium on Mobile Ad Hoc Networking and Computing, New York, NY, USA. ACM.
Greis, M. (2019). The Network Simulator - (NS-2).
Härri, J., Filali, F., Bonnet, C., e Fiore, M. (2006). VanetMobiSim: Generating realistic mobility patterns for vanets. In Proceedings of the 3rd International Workshop on Vehicular Ad Hoc Networks, New York, NY, USA. ACM.
Hussain, S., Wu, D., Memon, S., e Khuda Bux, N. (2019). Vehicular Ad Hoc network (VANET) connectivity analysis of a highway toll plaza. Data.
Jiang, D. e Delgrossi, L. (2008). IEEE 802.11p: Towards an international standard for wireless access in vehicular environments. In VTC Spring, pgs 2036-2040. IEEE.
Li, C., Zhen, A., Sun, J., Zhang, M., e Hu, X. (2016). Analysis of connectivity probability in VANETSs considering minimum safety distance. In 2016 8th International Conference on Wireless Communications Signal Processing (WCSP).
Liu, S., Yang, Y., e Wang, W. (2013). Research of AODV routing protocol for ad hoc networks. AASRI Procedia, 5:21 — 31. 2013 AASRI Conference on Parallel and Distributed Computing and Systems.
Liu, T., Xia, Z., Shi, S., e Gu, X. (2018). A modified AODV protocol based on nodes velocity. In Gu, X., Liu, G., e Li, B., editors, Machine Learning and Intelligent Communications, Cham. Springer International Publishing.
Mahajan, A., Potnis, N., Gopalan, K., e Wang, A.-I. (2010). Urban mobility models for VANETS.
Manel, K. e Lamia, C. (2017). SODV speed based Ad Hoc on demand vector link routing protocol: A routing protocol for VANET networks. In 2017 Sixth International Conference on Communications and Networking (ComNet).
Mir, Z. e Filali, F. (2014). LTE and IEEE 802.11p for vehicular networking: A performance evaluation. EURASIP Journal on Wireless Communications and Networking, 2014.
Muhammed Ajeer, V. K., Neelakantan, P. C., e Babu,A. V. (2011). Network connectivity of one-dimensional vehicular Ad Hoc network. In 2011 International Conference on Communications and Signal Processing.
Nazar, R. e Alsabbagh, H. (2016). Analysis of path duration in VANETS using B-MFR forwarding method.
Purnomo, A., Widyawan, Najib, W., Hartono, R., e Hartatik(2018). Effect of variation in active route timeout and my route timeout on the performance of AODV-ETX protocol in mobile adhoc network. IOP Conference Series: Materials Science and Engineering.
Raw, R., Kumar Soni, S., Singh, N., e Kaiwartya, O. (2014). A probabilistic analysis of path duration using routing protocol in VANETS. Int. Journal of Vehicular Technology, 2014.
Sarkar, D., Choudhury, S., e Majumder, A. (2018). Enhanced-ant-AODV for optimal route selection in mobile Ad-Hoc network. Journal of King Saud University - Computer e Information Sciences.
Spaho, E., Ikeda, M., Barolli, L., Xhafa, F., Kolici, V., e Iwashige, J. (2013). Performance evaluation of AODV Routing Protocol in VANETS considering multi-flows traffic. In 2013 Eighth International Conference on Broadband and Wireless Computing, Communication and Applications.
Umer, T. e Afzal, M. K. (2018). A dual ring connectivity model for VANET under heterogeneous traffic flow. Wireless Personal Communications.
Alam, M., Sher, M., e Husain, A. (2009). Integrated mobility model (IMM) for vanets simulation and its impact. In 2009 International Conference on Emerging Technologies.
Aliesawi, Salah e Mubarek, F., Ali Alheeti, K. M., e M. ALfahad, N. (2018). Urban-AODV: An improved AODV protocol for vehicular Ad-Hoc networks in urban environment. Int. Journal of Engineering e Technology(UAE), 7.
Almohammedi, Akram e Noordin, N. e. S. S. (2016). Evaluating the impact of transmission range on the performance of VANET. Int. Journal of Electrical e Computer Engineering (IJECE).
Alves Jr, J. e Wille, E. (2015). Improving VANETs connectivity with a totally Ad Hoc living mobile backbone. Journal of Computer Networks eCommunications, 2015.
Alves Jr, J. e Wille, E. (2016). P-AOMDV: An improved routing protocol for V2V communication based on public transport backbones. Transactions on Emerging Telecommunications Technologies.
Bettstetter, C. (2002). On the minimum node degree and connectivity of a wireless multihop network. In Proceedings of the 3rd ACM International Symposium on Mobile Ad Hoc Networking and Computing, New York, NY, USA. ACM.
Greis, M. (2019). The Network Simulator - (NS-2).
Härri, J., Filali, F., Bonnet, C., e Fiore, M. (2006). VanetMobiSim: Generating realistic mobility patterns for vanets. In Proceedings of the 3rd International Workshop on Vehicular Ad Hoc Networks, New York, NY, USA. ACM.
Hussain, S., Wu, D., Memon, S., e Khuda Bux, N. (2019). Vehicular Ad Hoc network (VANET) connectivity analysis of a highway toll plaza. Data.
Jiang, D. e Delgrossi, L. (2008). IEEE 802.11p: Towards an international standard for wireless access in vehicular environments. In VTC Spring, pgs 2036-2040. IEEE.
Li, C., Zhen, A., Sun, J., Zhang, M., e Hu, X. (2016). Analysis of connectivity probability in VANETSs considering minimum safety distance. In 2016 8th International Conference on Wireless Communications Signal Processing (WCSP).
Liu, S., Yang, Y., e Wang, W. (2013). Research of AODV routing protocol for ad hoc networks. AASRI Procedia, 5:21 — 31. 2013 AASRI Conference on Parallel and Distributed Computing and Systems.
Liu, T., Xia, Z., Shi, S., e Gu, X. (2018). A modified AODV protocol based on nodes velocity. In Gu, X., Liu, G., e Li, B., editors, Machine Learning and Intelligent Communications, Cham. Springer International Publishing.
Mahajan, A., Potnis, N., Gopalan, K., e Wang, A.-I. (2010). Urban mobility models for VANETS.
Manel, K. e Lamia, C. (2017). SODV speed based Ad Hoc on demand vector link routing protocol: A routing protocol for VANET networks. In 2017 Sixth International Conference on Communications and Networking (ComNet).
Mir, Z. e Filali, F. (2014). LTE and IEEE 802.11p for vehicular networking: A performance evaluation. EURASIP Journal on Wireless Communications and Networking, 2014.
Muhammed Ajeer, V. K., Neelakantan, P. C., e Babu,A. V. (2011). Network connectivity of one-dimensional vehicular Ad Hoc network. In 2011 International Conference on Communications and Signal Processing.
Nazar, R. e Alsabbagh, H. (2016). Analysis of path duration in VANETS using B-MFR forwarding method.
Purnomo, A., Widyawan, Najib, W., Hartono, R., e Hartatik(2018). Effect of variation in active route timeout and my route timeout on the performance of AODV-ETX protocol in mobile adhoc network. IOP Conference Series: Materials Science and Engineering.
Raw, R., Kumar Soni, S., Singh, N., e Kaiwartya, O. (2014). A probabilistic analysis of path duration using routing protocol in VANETS. Int. Journal of Vehicular Technology, 2014.
Sarkar, D., Choudhury, S., e Majumder, A. (2018). Enhanced-ant-AODV for optimal route selection in mobile Ad-Hoc network. Journal of King Saud University - Computer e Information Sciences.
Spaho, E., Ikeda, M., Barolli, L., Xhafa, F., Kolici, V., e Iwashige, J. (2013). Performance evaluation of AODV Routing Protocol in VANETS considering multi-flows traffic. In 2013 Eighth International Conference on Broadband and Wireless Computing, Communication and Applications.
Umer, T. e Afzal, M. K. (2018). A dual ring connectivity model for VANET under heterogeneous traffic flow. Wireless Personal Communications.
Publicado
22/05/2013
Como Citar
MENDONÇA, Roberto J. L.; ALMEIDA, Alessandra B.S..
Modelo para Análise e Otimização de Backbone para Tráfego IPv6 utilizando MPLS-TE. In: WORKSHOP DE COMPUTAÇÃO APLICADA EM GOVERNO ELETRÔNICO (WCGE), 5. , 2013, João Pessoa.
Anais [...].
Porto Alegre: Sociedade Brasileira de Computação,
2013
.
p. 57-64.
ISSN 2763-8723.