Autoconfiguração de rotas em redes ad-hoc de VANTs
Resumo
As redes FANETs (Flying Ad-Hoc Networks) possuem características que as diferem das demais MANETs (Mobile Ad Hoc Networks), quais sejam, a velocidade, a movimentação 3D e as rápidas mudanças de topologia. A literatura indica que os protocolos de roteamento disponíveis para as FANETs não estão preparados para os desafios de autoconfiguração apresentados por essas características. Este trabalho confirma que a indicação da literatura através da realização de simulações em um cenário proposto utilizando os protocolos B.A.T.M.A.N. (Better Approach To Mobile Ad-hoc Networking) e OLSR (Optimized Link State Routing Protocol). Essa confirmação dá-se através da análise das métricas vazão média, latência média e tempo médio de duração de comutação de rota. Além dessa análise, é proposta uma solução inicial dos problemas encontrados durante a análise dos protocolos analisados.
Referências
3GPP (2021). 3GPP 3rd Generation Partnership Project (3GPP).
Chen, W., Liu, B., Huang, H., Guo, S., and Zheng, Z. (2019). When UAV Swarm Meets Edge-Cloud Computing: The QoS Perspective. IEEE Network, 33(2):36-43.
Committee, L. A. N. M. A. N. (2007). IEEE Std 802.11-2007: IEEE Standard for Information Technology-Telecommunications and Information Exchange between SystemsLocal and Metropolitan Area Networks-Specific Requirements Part 11: Wireless LAN Medium Access Control (MAC) and Physical Layer (PHY, volume 2020.
De Silva, R. (2018). Next Hop Node Selection in Private UAV Networks. In International Conference on Advanced Technologies for Communications, volume 2018-Octob, pages 248-252.
Dearlove, C. and Clausen, T. (2014). RFC 7188 Optimized Link State Routing Protocol Version 2 (OLSRv2) and MANET Neighborhood Discovery Protocol (NHDP) Extension TLVs.
Fan, X., Cai, W., and Lin, J. (2018). A survey of routing protocols for highly dynamic mobile ad hoc networks. In International Conference on Communication Technology Proceedings, ICCT, volume 2017-Octob, pages 1412-1417.
Force), I. I. E. T. (2021). rfc3626.
Gao, A., Hu, Y., Li, L., and Li, X. (2018). BP network control for resource allocation and QoS ensurance in UAV cloud. Journal of Sensors, 2018.
Gupta, L., Jain, R., and Vaszkun, G. (2016). Survey of Important Issues in UAV Communication Networks. IEEE Communications Surveys and Tutorials, 18(2):1123-1152.
Hayat, S., Yanmaz, E., and Muzaffar, R. (2016). Survey on Unmanned Aerial Vehicle Networks for Civil Applications: A Communications Viewpoint.
Heidemann, J. and Isi, U. S. C. (2002). OMNeT++ Discrete Event Simulator. Audio, (March):1-9.
IEEE (2016). IEEE Standard for Information technology-Telecommunications and information exchange between systems Local and metropolitan area networks-Specific requirements Part 11: Wireless LAN Medium Access Control (MAC) and Physical Layer (PHY) Specifications.
Jiang, J. and Han, G. (2018). Routing Protocols for Unmanned Aerial Vehicles. IEEE Communications Magazine, 56(1):58-63.
Kim, D. Y. and Lee, J. W. (2018). Joint Mission Assignment and Location Management for UAVs in Mission-critical Flying Ad Hoc Networks. In 9th International Conference on Information and Communication Technology Convergence: ICT Convergence Powered by Smart Intelligence, ICTC 2018, pages 323-328.
Mohammed, F., Jawhar, I., Mohamed, N., and Idries, A. (2016). Towards Trusted and Efficient UAV-Based Communication. In Proceedings 2nd IEEE International Conference on Big Data Security on Cloud, IEEE BigDataSecurity 2016, 2nd IEEE International Conference on High Performance and Smart Computing, IEEE HPSC 2016 and IEEE International Conference on Intelligent Data and S, pages 388-393.
Mukherjee, A., Keshary, V., Pandya, K., Dey, N., and Satapathy, S. C. (2018). Flying ad hoc networks: A comprehensive survey. In Advances in Intelligent Systems and Computing, volume 701, pages 569-580. Springer Verlag.
Neelavathy Pari, S. and Gangadaran, D. (2018). A Reliable Prognostic Communication Routing for Flying Ad Hoc Networks. In Proceedings of the 2nd International Conference on Trends in Electronics and Informatics, ICOEI 2018, pages 33-38.
Russoniello, A. and Gamess, E. (2018). Evaluation of Different Routing Protocols for Mobile Ad-Hoc Networks in Scenarios with High-Speed Mobility. International Journal of Computer Network and Information Security, 10(10):46-52.
Shumeye Lakew, D., Sa'Ad, U., Dao, N. N., Na, W., and Cho, S. (2020). Routing in Flying Ad Hoc Networks: A Comprehensive Survey. IEEE Communications Surveys and Tutorials, 22(2):1071-1120.
Singh, K. and Verma, A. K. (2015). Applying OLSR routing in FANETs. In Proceedings of 2014 IEEE International Conference on Advanced Communication, Control and Computing Technologies, ICACCCT 2014, pages 1212-1215.
Sliwa, B., Falten, S., and Wietfeld, C. (2019). Performance evaluation and optimization of B.A.T.M.A.N. v routing for aerial and ground-based mobile ad-hoc networks. In IEEE Vehicular Technology Conference, volume 2019-April, pages 1-7. Institute of Electrical and Electronics Engineers Inc.
Website (2021). Visão geral Open-Mesh Open Mesh.
Wei, Z., Wu, H., Huang, S., and Feng, Z. (2017). Scaling Laws of Unmanned Aerial Vehicle Network with Mobility Pattern Information. IEEE Communications Letters, 21(6):1389-1392.
Chen, W., Liu, B., Huang, H., Guo, S., and Zheng, Z. (2019). When UAV Swarm Meets Edge-Cloud Computing: The QoS Perspective. IEEE Network, 33(2):36-43.
Committee, L. A. N. M. A. N. (2007). IEEE Std 802.11-2007: IEEE Standard for Information Technology-Telecommunications and Information Exchange between SystemsLocal and Metropolitan Area Networks-Specific Requirements Part 11: Wireless LAN Medium Access Control (MAC) and Physical Layer (PHY, volume 2020.
De Silva, R. (2018). Next Hop Node Selection in Private UAV Networks. In International Conference on Advanced Technologies for Communications, volume 2018-Octob, pages 248-252.
Dearlove, C. and Clausen, T. (2014). RFC 7188 Optimized Link State Routing Protocol Version 2 (OLSRv2) and MANET Neighborhood Discovery Protocol (NHDP) Extension TLVs.
Fan, X., Cai, W., and Lin, J. (2018). A survey of routing protocols for highly dynamic mobile ad hoc networks. In International Conference on Communication Technology Proceedings, ICCT, volume 2017-Octob, pages 1412-1417.
Force), I. I. E. T. (2021). rfc3626.
Gao, A., Hu, Y., Li, L., and Li, X. (2018). BP network control for resource allocation and QoS ensurance in UAV cloud. Journal of Sensors, 2018.
Gupta, L., Jain, R., and Vaszkun, G. (2016). Survey of Important Issues in UAV Communication Networks. IEEE Communications Surveys and Tutorials, 18(2):1123-1152.
Hayat, S., Yanmaz, E., and Muzaffar, R. (2016). Survey on Unmanned Aerial Vehicle Networks for Civil Applications: A Communications Viewpoint.
Heidemann, J. and Isi, U. S. C. (2002). OMNeT++ Discrete Event Simulator. Audio, (March):1-9.
IEEE (2016). IEEE Standard for Information technology-Telecommunications and information exchange between systems Local and metropolitan area networks-Specific requirements Part 11: Wireless LAN Medium Access Control (MAC) and Physical Layer (PHY) Specifications.
Jiang, J. and Han, G. (2018). Routing Protocols for Unmanned Aerial Vehicles. IEEE Communications Magazine, 56(1):58-63.
Kim, D. Y. and Lee, J. W. (2018). Joint Mission Assignment and Location Management for UAVs in Mission-critical Flying Ad Hoc Networks. In 9th International Conference on Information and Communication Technology Convergence: ICT Convergence Powered by Smart Intelligence, ICTC 2018, pages 323-328.
Mohammed, F., Jawhar, I., Mohamed, N., and Idries, A. (2016). Towards Trusted and Efficient UAV-Based Communication. In Proceedings 2nd IEEE International Conference on Big Data Security on Cloud, IEEE BigDataSecurity 2016, 2nd IEEE International Conference on High Performance and Smart Computing, IEEE HPSC 2016 and IEEE International Conference on Intelligent Data and S, pages 388-393.
Mukherjee, A., Keshary, V., Pandya, K., Dey, N., and Satapathy, S. C. (2018). Flying ad hoc networks: A comprehensive survey. In Advances in Intelligent Systems and Computing, volume 701, pages 569-580. Springer Verlag.
Neelavathy Pari, S. and Gangadaran, D. (2018). A Reliable Prognostic Communication Routing for Flying Ad Hoc Networks. In Proceedings of the 2nd International Conference on Trends in Electronics and Informatics, ICOEI 2018, pages 33-38.
Russoniello, A. and Gamess, E. (2018). Evaluation of Different Routing Protocols for Mobile Ad-Hoc Networks in Scenarios with High-Speed Mobility. International Journal of Computer Network and Information Security, 10(10):46-52.
Shumeye Lakew, D., Sa'Ad, U., Dao, N. N., Na, W., and Cho, S. (2020). Routing in Flying Ad Hoc Networks: A Comprehensive Survey. IEEE Communications Surveys and Tutorials, 22(2):1071-1120.
Singh, K. and Verma, A. K. (2015). Applying OLSR routing in FANETs. In Proceedings of 2014 IEEE International Conference on Advanced Communication, Control and Computing Technologies, ICACCCT 2014, pages 1212-1215.
Sliwa, B., Falten, S., and Wietfeld, C. (2019). Performance evaluation and optimization of B.A.T.M.A.N. v routing for aerial and ground-based mobile ad-hoc networks. In IEEE Vehicular Technology Conference, volume 2019-April, pages 1-7. Institute of Electrical and Electronics Engineers Inc.
Website (2021). Visão geral Open-Mesh Open Mesh.
Wei, Z., Wu, H., Huang, S., and Feng, Z. (2017). Scaling Laws of Unmanned Aerial Vehicle Network with Mobility Pattern Information. IEEE Communications Letters, 21(6):1389-1392.
Publicado
23/05/2022
Como Citar
REIS, Luis H. C.; MACEDO, Daniel F.; NOGUEIRA, José Marcos S..
Autoconfiguração de rotas em redes ad-hoc de VANTs. In: WORKSHOP DE GERÊNCIA E OPERAÇÃO DE REDES E SERVIÇOS (WGRS), 27. , 2022, Fortaleza.
Anais [...].
Porto Alegre: Sociedade Brasileira de Computação,
2022
.
p. 99-112.
ISSN 2595-2722.
DOI: https://doi.org/10.5753/wgrs.2022.223504.
