Comparison of switching policies in terms of switching cost and network performance in static SDM-EONs

Abstract In this paper, we concentrate on the comparison of different switching policies, as well as their corresponding spatially-spectrally flexible super-channel transmission technologies, in static SDM-EONs. These switching policies are different due to their different spatial switching granularities and/or whether the space lane change (SLC) is supported. According to our simulation results, the switching policy with a finer switching granularity can achieve better network performance in terms of required frequency slices in the networks but meanwhile results in higher device cost. Moreover, we find that the application of SLC can only provide negligible improvements (0.1% ~ 3.1%) on network performance. SLC is encouraged only when the spectrum resource is highly valued by network operators compared to the additional device cost it brings. Moreover, in some previous works, the application of SLC can achieve a 7% ~ 14% improvement on the network throughput in dynamic network scenarios, especially when a finer spatial switching granularity is applied. Consequently, the results in this paper suggest that such an improvement is likely to be achieved by the means of network planning, such as the design of an efficient algorithm considering spectrum defragmentation, because if the re-routing/re-assignment of spectrum is allowed, the dynamic scenario can be treated as a sequence of static scenarios that change with time.

[1]  Liangjia Zong,et al.  Survey of photonic switching architectures and technologies in support of spatially and spectrally flexible optical networking [invited] , 2017, IEEE/OSA Journal of Optical Communications and Networking.

[2]  Krzysztof Walkowiak,et al.  Survey of resource allocation schemes and algorithms in spectrally-spatially flexible optical networking , 2018, Opt. Switch. Netw..

[3]  Ioannis Tomkos,et al.  Cost and power consumption model for flexible super-channel transmission with all-optical sub-channel add/drop capability , 2015, 2015 17th International Conference on Transparent Optical Networks (ICTON).

[4]  Jose A. Lazaro,et al.  Flex-grid/SDM backbone network design with inter-core XT-limited transmission reach , 2016, IEEE/OSA Journal of Optical Communications and Networking.

[5]  Elio Salvadori,et al.  Resource allocation policies in SDM optical networks (Invited paper) , 2015, 2015 International Conference on Optical Network Design and Modeling (ONDM).

[6]  Peter J. Winzer,et al.  From Scaling Disparities to Integrated Parallelism: A Decathlon for a Decade , 2017, Journal of Lightwave Technology.

[7]  Peter J. Winzer,et al.  Complexity analysis of adaptive frequency-domain equalization for MIMO-SDM transmission , 2013 .

[8]  G. Bosco,et al.  Modeling of the Impact of Nonlinear Propagation Effects in Uncompensated Optical Coherent Transmission Links , 2012, Journal of Lightwave Technology.

[9]  Ioannis Tomkos,et al.  Investigation of Spectrum Granularity for Performance Optimization of Flexible Nyquist-WDM-Based Optical Networks , 2015, Journal of Lightwave Technology.

[10]  Hideki Tode,et al.  Routing, Spectrum, and core and/or mode assignment on space-division multiplexing optical networks [invited] , 2017, IEEE/OSA Journal of Optical Communications and Networking.

[11]  Qian Wu,et al.  Joint Assignment of Spatial Granularity, Routing, Modulation, and Spectrum in SDM-EONs: Minimizing the Network CAPEX Considering Spectrum, WSS, and Laser Resources , 2018, Journal of Lightwave Technology.

[12]  Yongli Zhao,et al.  Crosstalk-aware cross-core virtual concatenation in spatial division multiplexing elastic optical networks , 2016 .

[13]  Peter J. Winzer,et al.  Scaling Optical Fiber Networks: Challenges and Solutions , 2015 .

[14]  Toshio Morioka,et al.  1.01-Pb/s (12 SDM/222 WDM/456 Gb/s) Crosstalk-managed Transmission with 91.4-b/s/Hz Aggregate Spectral Efficiency , 2012 .

[15]  Yongli Zhao,et al.  Distance Adaptive Routing, Core and Spectrum Allocation in Space Division Multiplexing Optical Networks with Multi-Core Fibers , 2016, 2016 Asia Communications and Photonics Conference (ACP).

[16]  Jordi Perelló,et al.  On the scalability of dynamic Flex-Grid/SDM optical core networks , 2018, Comput. Networks.

[17]  Rumipamba Zambrano,et al.  Contributions to network planning and operation of Flex-Grid/SDM optical core networks , 2019 .

[18]  Masahiko Jinno,et al.  Spatial channel network (SCN): Opportunities and challenges of introducing spatial bypass toward the massive SDM era [invited] , 2019, IEEE/OSA Journal of Optical Communications and Networking.

[19]  L. Nelson,et al.  Space-division multiplexing in optical fibres , 2013, Nature Photonics.

[20]  Masahiko Jinno,et al.  Spectrally and spatially flexible optical network planning and operations , 2015, IEEE Communications Magazine.

[21]  S. Tibuleac,et al.  N-degree ROADM architecture comparison: Broadcast-and-select versus route-and-select in 120 Gb/s DP-QPSK transmission systems , 2014, OFC 2014.

[22]  Pablo Pavón-Mariño,et al.  Space continuity constraint in dynamic Flex-Grid/SDM optical core networks: An evaluation with spatial and spectral super-channels , 2018, Comput. Commun..

[23]  Elio Salvadori,et al.  Comparison of Spectral and Spatial Super-Channel Allocation Schemes for SDM Networks , 2016, Journal of Lightwave Technology.

[24]  Masahiko Jinno,et al.  Elastic Optical Networking: Roles and Benefits in Beyond 100-Gb/s Era , 2017, Journal of Lightwave Technology.

[25]  Ioannis Tomkos,et al.  Impact of Spatial and Spectral Granularity on the Performance of SDM Networks Based on Spatial Superchannel Switching , 2017, Journal of Lightwave Technology.

[26]  Ioannis Tomkos,et al.  Comparison of CD(C) ROADM architectures for space division multiplexed networks , 2017, 2017 Optical Fiber Communications Conference and Exhibition (OFC).

[27]  Taiji Sakamoto,et al.  Design of 125 μm cladding multi-core fiber with full-band compatibility to conventional single-mode fiber , 2015, 2015 European Conference on Optical Communication (ECOC).

[28]  Qian Wu,et al.  Evaluation of Device Cost, Power Consumption, and Network Performance in Spatially and Spectrally Flexible SDM Optical Networks , 2019, Journal of Lightwave Technology.

[29]  Roberto Proietti,et al.  3D elastic optical networking in the temporal, spectral, and spatial domains , 2015, IEEE Communications Magazine.

[30]  Georgios Zervas,et al.  Space-division multiplexing in data center networks: on multi-core fiber solutions and crosstalk-suppressed resource allocation , 2018, IEEE/OSA Journal of Optical Communications and Networking.

[31]  J. Elmirghani,et al.  Constraint-Based Anycasting Over Optical Burst Switched Networks , 2009, IEEE/OSA Journal of Optical Communications and Networking.

[32]  Ioannis Tomkos,et al.  Evaluation of the impact of spatial and spectral granularities on the performance of spatial superchannel switching schemes , 2016, 2016 18th International Conference on Transparent Optical Networks (ICTON).

[33]  S. Spadaro,et al.  Evaluation of core-continuity-constrained ROADMs for flex-grid/MCF optical networks , 2017, IEEE/OSA Journal of Optical Communications and Networking.

[34]  Dimitra Simeonidou,et al.  Survey and Evaluation of Space Division Multiplexing: From Technologies to Optical Networks , 2015, IEEE Communications Surveys & Tutorials.

[35]  Marta M. B. Pascoal,et al.  A new implementation of Yen’s ranking loopless paths algorithm , 2003, 4OR.

[36]  I. Tomkos,et al.  Spectral vs. spatial super-channel allocation in SDM networks under independent and joint switching paradigms , 2015, 2015 European Conference on Optical Communication (ECOC).

[37]  Ioannis Tomkos,et al.  Elastic Bandwidth Allocation in Flexible OFDM-Based Optical Networks (vol 29, pg 1354, 2011) , 2011 .

[38]  Ioannis Tomkos,et al.  Evaluation of the impact of different SDM switching strategies in a network planning scenario , 2016, 2016 Optical Fiber Communications Conference and Exhibition (OFC).

[39]  Georgios Zervas,et al.  Resource Allocation for Space-Division Multiplexing: Optical White Box Versus Optical Black Box Networking , 2015, Journal of Lightwave Technology.