CoROA: Algoritmo para Coleta de Dados em Redes de Sensores Aquáticas Óptico-Acústicas

  • Eduardo P. M. Câmara Júnior UFMG
  • Luiz F. M. Vieira UFMG
  • Marcos A. M. Vieira UFMG

Resumo


Redes de sensores aquáticas são utilizadas para coleta de dados de ambientes aquáticos. Os nós dessas redes podem se comunicar utilizando comunicação óptica ou acústica e podem explorar o melhor de cada um dos meios de transmissão. Neste trabalho é proposto CoROA, um algoritmo para realizar coletas de dados com agregação em redes de sensores aquáticas ópticoacústicas. CoROA divide a rede em clusters, monta umaárvore de roteamento entre os líderes e utiliza agregação de dados para entregar os dados coletados ao nó coletor. Experimentos mostram que, comparado a um algoritmo de caminho mínimo, CoROA consegue ter um consumo energético menor, obter menores latências e um número maior de dados coletadas por hora pelo nó coletor.

Referências

Akyildiz, I. F., Pompili, D., and Melodia, T. (2005). Underwater acoustic sensor networks: research challenges. Ad Hoc Networks, 3(3):257 – 279.

Anguita, D., Brizzolara, D., Parodi, G., and Hu, Q. (2011). Optical wireless underwater communication for AUV: Preliminary simulation and experimental results. In OCEANS, 2011 IEEE-Spain, pages 1–5. IEEE.

Campagnaro, F., Favaro, F., Guerra, F., Calzado, V. S., Zorzi, M., and Casari, P. (2015). Simulation of multimodal optical and acoustic communications in underwater networks. In OCEANS 2015-Genova, pages 1–7. IEEE.

Coutinho, R. W., Boukerche, A., Vieira, L. F., and Loureiro, A. A. (2014). GEDAR: geographic and opportunistic routing protocol with depth adjustment for mobile underwater sensor networks. In Communications (ICC), 2014 IEEE International Conference on, pages 251–256. IEEE.

Erol, M., Vieira, L. F., Caruso, A., Paparella, F., Gerla, M., and Oktug, S. (2008). Multi stage underwater sensor localization using mobile beacons. In Sensor Technologies and Applications, 2008. SENSORCOMM’08. Second International Conference on, pages 710–714. IEEE.

Erol, M., Vieira, L. F., and Gerla, M. (2007). Localization with Dive’N’Rise (DNR) beacons for underwater acoustic sensor networks. In Proceedings of the second workshop on Underwater networks, pages 97–100. ACM.

EvoLogics (2014). Evologics S2CR 18/34 product information. Accessed: Nov. 2017 [Online]. Available: http://www.evologics.de/files/DataSheets/EvoLogicsS2CR1834ProductInformation.pdf.

Farr, N., Bowen, A., Ware, J., Pontbriand, C., and Tivey, M. (2010). An integrated, underwater optical/acoustic communications system. In OCEANS 2010 IEEE-Sydney, pages 1–6. IEEE.

Farr, N., Chave, A., Freitag, L., Preisig, J., White, S., Yoerger, D., and Sonnichsen, F. In OCEANS 2006, (2006). Optical modem technology for seaoor observatories. pages 1–6. IEEE.

Farr, N., Chave, A., Freitag, L., Preisig, J., White, S., Yoerger, D., and Titterton, P. (2005). Optical modem technology for seaoor observatories. In OCEANS, 2005. Proceedings of MTS/IEEE, pages 928–934. IEEE.

Goyal, N., Dave, M., and Verma, A. K. (2017). Data aggregation in underwater wireless sensor network: Recent approaches and issues. Journal of King Saud UniversityComputer and Information Sciences.

Han, S., Noh, Y., Liang, R., Chen, R., Cheng, Y.-J., and Gerla, M. (2014). Evaluation of underwater optical-acoustic hybrid network. China Communications, 11(5):49–59.

Hu, T. and Fei, Y. (2012). MURAO: A multi-level routing protocol for acoustic-optical hybrid underwater wireless sensor networks. In Sensor, Mesh and Ad Hoc Communications and Networks (SECON), 2012 9th Annual IEEE Communications Society Conference on, pages 218–226. IEEE.

Júnior, E. P., Vieira, L. F., and Vieira, M. A. (2017). Escalonamento de nós em redes aquáticas estraticadas utilizando voronoi. XXXV Simpósio Brasileiro de Redes de Computadores e Sistemas Distribuídos, Belém, PA, Brasil.

Kong, J., Cui, J.-h., Wu, D., and Gerla, M. (2005). Building underwater ad-hoc networks and sensor networks for large scale real-time aquatic applications. In Military Communications Conference, 2005. MILCOM 2005. IEEE, pages 1535–1541. IEEE.

Manjula, R. and Manvi, S. S. (2012). Cluster based data aggregation in underwater acoustic sensor networks. In India Conference (INDICON), 2012 Annual IEEE, pages 104– 109. IEEE.

Mhatre, V. and Rosenberg, C. (2004). Homogeneous vs heterogeneous clustered sensor networks: a comparative study. In Communications, 2004 IEEE International Conference on, volume 6, pages 3646–3651. IEEE.

Moriconi, C., Cupertino, G., Betti, S., and Tabacchiera, M. (2015). Hybrid acoustic/optic communications in underwater swarms. In OCEANS 2015-Genova, pages 1–9. IEEE.

Othman, A.-K., Adams, A., and Tsimenidis, C. C. (2006). Node discovery protocol and localization for distributed underwater acoustic networks. In Telecommunications, 2006. AICT-ICIW’06. International Conference on Internet and Web Applications and Services/Advanced International Conference on, pages 93–93. IEEE.

Pompili, D. and Akyildiz, I. F. (2009). Overview of networking protocols for underwater wireless communications. IEEE Communications Magazine, 47(1):97–102.

Shakir, M., Khan, M. A., Malik, S. A., and ul Haq, I. (2012). Design of underwaIn World Applied Sciences Jourter sensor networks for water quality monitoring. nal,vol.17,no.11, page 1441–1444.

Sonardyne (2016). Datasheet BlueComm 200 - optical communications system. Accessed: Nov. 2017 [Online]. Available: http://www.sonardyne.com/app/uploads/2016/06/Sonardyne8361BlueComm200.pdf.

Stojanovic, M. (2007). On the relationship between capacity and distance in an underwater acoustic communication channel. ACM SIGMOBILE Mobile Computing and Communications Review, 11(4):34–43.

Vieira, L., Loureiro, A., Fernandes, A., and Campos, M. (2010). Redes de sensores aquáticas. XXVIII Simpósio Brasileiro de Redes de Computadores e Sistemas Distribuídos, Gramado, RS, Brasil, 24.

Vieira, L. F., Vieira, M. A., Pinto, D., Nacif, J. A. M., Viana, S. S., and Vieira, A. B. (2012). Hydronode: An underwater sensor node prototype for monitoring hydroeIn Proceedings of the Seventh ACM International Conference on lectric reservoirs. Underwater Networks and Systems, page 43. ACM.

Vieira, L. F. M., Lee, U., Noh, Y., and Gerla, M. (2009). LPS: Laser positioning system for underwater networks. In ACM International Workshop on Underwater Networks, WUWNet’09.

Vieira, L. F. M., Vieira, M. A. M., Nacif, J. A., and Vieira, A. B. (Jan. 2018). Autonomous wireless lake monitoring. In Computing in Science & Engineering (Print).

Wang, J., Shi, W., Xu, L., Zhou, L., Niu, Q., et al. (2017). Design of optical-acoustic hybrid underwater wireless sensor network. Journal of Network and Computer Applications.

Zhou, Z., Cui, J.-H., and Zhou, S. (2007). Localization for large-scale underwater sensor networks. Networking 2007. Ad hoc and sensor networks, wireless networks, next generation internet, pages 108–119.
Publicado
10/05/2018
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CÂMARA JÚNIOR, Eduardo P. M.; VIEIRA, Luiz F. M.; VIEIRA, Marcos A. M.. CoROA: Algoritmo para Coleta de Dados em Redes de Sensores Aquáticas Óptico-Acústicas. In: SIMPÓSIO BRASILEIRO DE REDES DE COMPUTADORES E SISTEMAS DISTRIBUÍDOS (SBRC), 36. , 2018, Campos do Jordão. Anais [...]. Porto Alegre: Sociedade Brasileira de Computação, 2018 . p. 379-392. ISSN 2177-9384. DOI: https://doi.org/10.5753/sbrc.2018.2429.

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