2016 - Engineeringhttp://dr.lib.sjp.ac.lk/handle/123456789/54972026-04-23T10:08:04Z2026-04-23T10:08:04ZNonlinear-Impairments- and Crosstalk-Aware Resource Allocation Schemes for Multicore-Fiber-based Flexgrid NetworksDharmaweera, M.N.Yan, L.Zhao, J.Wymeersch, H.Agrell, E.http://dr.lib.sjp.ac.lk/handle/123456789/55692017-09-28T09:28:16Z2016-01-01T00:00:00ZNonlinear-Impairments- and Crosstalk-Aware Resource Allocation Schemes for Multicore-Fiber-based Flexgrid Networks
Dharmaweera, M.N.; Yan, L.; Zhao, J.; Wymeersch, H.; Agrell, E.
Abstract:
In this study, we propose a novel spectrum and core allocation scheme that incorporates both intra-core physical layer impairments and inter-core crosstalk. We demonstrate that accounting for the latter increases spectral efficiency by at least 50% when crosstalk is significant.
2016-01-01T00:00:00ZAn impairment-aware resource allocation scheme for dynamic elastic optical networksDharmaweera, M.N.Yan, L.Zhao, J.Wymeersch, H.Agrell, E.http://dr.lib.sjp.ac.lk/handle/123456789/55682017-09-28T09:24:18Z2017-01-01T00:00:00ZAn impairment-aware resource allocation scheme for dynamic elastic optical networks
Dharmaweera, M.N.; Yan, L.; Zhao, J.; Wymeersch, H.; Agrell, E.
By using impairment-driven variable guardbands, our proposed dynamic resource allocation scheme accommodates 50% more traffic in comparison to existing fixed transmission-reach- and guardband-based algorithms.
2017-01-01T00:00:00ZJoint Assignment of Power, Routing, and Spectrum in Static Flexible-Grid NetworksDharmaweera, M. N.Yen, L.Zhao, J.Wymeersch, H.Agrell, E.http://dr.lib.sjp.ac.lk/handle/123456789/55672017-09-28T09:21:32Z2016-01-01T00:00:00ZJoint Assignment of Power, Routing, and Spectrum in Static Flexible-Grid Networks
Dharmaweera, M. N.; Yen, L.; Zhao, J.; Wymeersch, H.; Agrell, E.
This paper proposes a novel network planning strategy to jointly allocate physical layer resources together with the routing and spectrum assignment in transparent nonlinear flexible-grid optical networks with static traffic demands. The physical layer resources, such as power spectral density, modulation format, and carrier frequency, are optimized for each connection. By linearizing the Gaussian noise model, both an optimal formulation and a low complexity decomposition heuristic are proposed. Our methods minimize the spectrum usage of networks, while satisfying requirements on the throughput and quality of transmission. Compared with existing schemes that allocate a uniform power spectral density to all connections, our proposed methods relax this constraint and, thus, utilize network resources more efficiently. Numerical results show that by optimizing the power spectral density per connection, the spectrum usage can be reduced by around 20% over uniform power spectral density schemes.
2016-01-01T00:00:00ZRegenerator site selection in impairment-aware elastic optical networksDharmaweera, M. N.Yan, L.Zhao, J.Karlsson, M.Agrell, E.http://dr.lib.sjp.ac.lk/handle/123456789/55662017-09-28T09:17:42Z2016-01-01T00:00:00ZRegenerator site selection in impairment-aware elastic optical networks
Dharmaweera, M. N.; Yan, L.; Zhao, J.; Karlsson, M.; Agrell, E.
We propose a novel regenerator site selection scheme for nonlinear impairment-aware elastic optical networks. The proposed scheme reduces bandwidth use by up to 40% in a realistic network by employing only 6 regenerator sites.
2016-01-01T00:00:00Z