Topology and Failure Modeling for Optical Network Resilience Analysis Against Earthquakes - Optical Network Design and Modeling
Conference Papers Year : 2020

Topology and Failure Modeling for Optical Network Resilience Analysis Against Earthquakes

Anuj Agrawal
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  • PersonId : 1096220
Vimal Bhatia
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  • PersonId : 1096222
Shashi Prakash
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  • PersonId : 1096223

Abstract

In this paper, we propose a stochastic failure and optical network topology (SFONT) model that can be used to comprehensively analyze the resilience of optical networks against a large number of possible earthquakes. We study an optical network densification problem, where dense network topologies are generated using the proposed SFONT model. Further, a seismic-risk aware optical network densification (SRA-OND) scheme is proposed with a view to design the future optical networks robust against earthquakes. The proposed SFONT model has been evaluated at various stages of network densification. To validate the capability of the proposed SFONT model to emulate real-world networking and failure scenario, we also perform a similar analysis based on RailTel optical network topology, seismic hazard maps, and real past earthquake data from India. Simulations indicate that the proposed SFONT model can be used to estimate and analyze the impact of network-resilience schemes on optical networks for a large number of possible earthquakes.
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hal-03200664 , version 1 (16-04-2021)

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Anuj Agrawal, Vimal Bhatia, Shashi Prakash. Topology and Failure Modeling for Optical Network Resilience Analysis Against Earthquakes. 23th International IFIP Conference on Optical Network Design and Modeling (ONDM), May 2019, Athens, Greece. pp.584-597, ⟨10.1007/978-3-030-38085-4_50⟩. ⟨hal-03200664⟩
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