Política de Roteamento Ciente das Áreas e dos Clusteres em Redes Ópticas Metropolitanas
Abstract
Metropolitan Optical Network (MON) concentrate a large part of the traffic coming from the internet, as well as aggregate all the traffic coming from the access networks. The distribution of this traffic on the MON occurs in different ways and in different types of areas, either due to the population’s activity pattern or the time of day. Thus, a traffic imbalance is perceived along the areas while many resources remain idle, increasing the service blocking rate. This work proposes the use of area-aware and cluster-aware routing and spectrum allocation algorithms. The proposed solution demonstrates twice the improvement of blocking results compared to area-agnostic routing algorithms.
References
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Troia, S., Cibari, A., and Alvizu, R. (2019). Dynamic network slicing based on tidal traffic patterns in metro-core optical networks. In 2019 IEEE 20th International Conference on High Performance Switching and Routing (HPSR), pages 1-7.
Uzunidis, D., Kosmatos, E., Matrakidis, C., Stavdas, A., and Lord, A. (2018). Dufinet: architectural considerations and physical layer studies of an agile and cost-effective metropolitan area network. Journal of Lightwave Technology, 37(3):808-814.
Wang, R. and Mukherjee, B. (2014). Spectrum management in heterogeneous bandwidth optical networks. Optical Switching and Networking, 11:83-91.
Yan, B., Zhao, Y., Chen, W., and Zhang, J. (2020). Area-aware routing and spectrum allocation for the tidal traffic pattern in metro optical networks. IEEE Access, 8:56501-56509.
Yan, B., Zhao, Y., Yu, X., Wang, W., Wu, Y., Wang, Y., and Zhang, J. (2018). Tidal-traffic-aware routing and spectrum allocation in elastic optical networks. Journal of Optical Communications and Networking, 10(11):832-842.
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Brasil, B. N. (2022). Brasília 60 anos: como a realidade transformou a cidade idealizada por lúcio costa e niemeyer.
Cugini, F., Porzi, C., Sambo, N., Bogoni, A., and Castoldi, P. (2016). Receiver architecture with filter for power-efficient drop&waste networks. In 2016 IEEE Optical Fiber Communications Conference and Exhibition (OFC), pages 1-3.
de Sousa, L. S. and Drummond, A. C. (2023). Metropolitan optical networks: A survey on single-layer architectures. Optical Switching and Networking, 47:100719.
Hadi, M. and Agrell, E. (2019). Joint power-efficient traffic shaping and service provisioning for metro elastic optical networks. Journal of Optical Communications and Networking, 11(12):578-587.
Hadi, M., Pakravan, M. R., and Agrell, E. (2019). Dynamic resource allocation in metro elastic optical networks using lyapunov drift optimization. Journal of Optical Communications and Networking, 11(6):250-259.
Kosmatos, E., Matrakidis, C., Uzunidis, D., Stavdas, A., Horlitz, S., Pfeiffer, T., Lord, A., and Riccardi, E. (2023). Real-time orchestration of qos-aware end-to-end slices across a converged metro and access network exploiting burst-mode technology. J. Opt. Commun. Netw., 15(1):1-15.
Pavon-Marino, P., Moreno-Muro, F., Garrich, M., Quagliotti, M., Riccardi, E., Rafel, A., and Lord, A. (2020). Techno-economic impact of filterless data plane and agile control plane in the 5g optical metro. Journal of Lightwave Technology, pages 1-1.
Routray, S. K., Javali, A., Sharma, L., Gupta, J., and Sahoo, A. (2020). The new frontiers of 800g high speed optical communications. In 2020 4th International Conference on Electronics, Communication and Aerospace Technology (ICECA), pages 821-825.
Shen, G., Zhang, Y., Zhou, X., Sheng, Y., Deng, N., Ma, Y., and Lord, A. (2018). Ultra-dense wavelength switched network: A special eon paradigm for metro optical networks. IEEE Communications Magazine, 56(2):189-195.
Sousa, L., Costa, L., and Drummond, A. (2022). Solução ciente da Área para alocação de recursos em redes Ópticas metropolitanas. In Anais do XL Simpósio Brasileiro de Redes de Computadores e Sistemas Distribuídos (SBRC), pages 363-376, Porto Alegre, RS, Brasil.
Streit, A., Ribeiro, M., Leão, R., and e Silva, E. S. (2021). Efeito do confinamento causado pela pandemia covid-19 nos perfis de tráfego residencial. In Anais do XXXIX Simpósio Brasileiro de Redes de Computadores e Sistemas Distribuídos (SBRC), pages 238-251, Porto Alegre, RS, Brasil.
Troia, S., Cibari, A., and Alvizu, R. (2019). Dynamic network slicing based on tidal traffic patterns in metro-core optical networks. In 2019 IEEE 20th International Conference on High Performance Switching and Routing (HPSR), pages 1-7.
Uzunidis, D., Kosmatos, E., Matrakidis, C., Stavdas, A., and Lord, A. (2018). Dufinet: architectural considerations and physical layer studies of an agile and cost-effective metropolitan area network. Journal of Lightwave Technology, 37(3):808-814.
Wang, R. and Mukherjee, B. (2014). Spectrum management in heterogeneous bandwidth optical networks. Optical Switching and Networking, 11:83-91.
Yan, B., Zhao, Y., Chen, W., and Zhang, J. (2020). Area-aware routing and spectrum allocation for the tidal traffic pattern in metro optical networks. IEEE Access, 8:56501-56509.
Yan, B., Zhao, Y., Yu, X., Wang, W., Wu, Y., Wang, Y., and Zhang, J. (2018). Tidal-traffic-aware routing and spectrum allocation in elastic optical networks. Journal of Optical Communications and Networking, 10(11):832-842.
Yen, J. Y. (1971). Finding the k shortest loopless paths in a network. management Science, 17(11):712-716.
Zhong, Z., Hua, N., Tornatore, M., Li, Y., Liu, H., Ma, C., Li, Y., Zheng, X., and Mukherjee, B. (2016). Energy efficiency and blocking reduction for tidal traffic via stateful grooming in ip-over-optical networks. Journal of Optical Communications and Networking, 8(3):175-189.
Published
2023-05-22
How to Cite
SOUSA, Léia S. de; COSTA, Lucas R.; DRUMMOND, André C..
Política de Roteamento Ciente das Áreas e dos Clusteres em Redes Ópticas Metropolitanas. In: BRAZILIAN SYMPOSIUM ON COMPUTER NETWORKS AND DISTRIBUTED SYSTEMS (SBRC), 41. , 2023, Brasília/DF.
Anais [...].
Porto Alegre: Sociedade Brasileira de Computação,
2023
.
p. 309-322.
ISSN 2177-9384.
DOI: https://doi.org/10.5753/sbrc.2023.409.
