LCoS-Based Wavelength-Selective Switch for Future Finer-Grid Elastic Optical Networks Capable of All-Optical Wavelength Conversion

LCoS-Based Wavelength-Selective Switch for Future Finer-Grid Elastic Optical Networks Capable of All-Optical Wavelength Conversion

A finer-grid wavelength-selective switch (WSS) based on liquid crystal on silicon is proposed, fabricated, and demonstrated. Based on the cost-effective method, namely combined lenses technique, the focal length is increased so that both the bandwidth setting resolution and grid granularity is impro...

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Bibliographic Details
Main Authors: Dequan Xie, Danshi Wang, Min Zhang, Zichen Liu, Quan You, Qi Yang, Shaohua Yu
Format: Article
Language:English
Published: IEEE 2017-01-01
Series:IEEE Photonics Journal
Subjects:
Liquid-crystal devices
optical switching devices
elastic optical network
nonlinear optical signal processing.
Online Access:https://ieeexplore.ieee.org/document/7858653/
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spelling doaj-aad579a9b2cd4cf9bafd9fb8993341f92021-03-29T17:36:42ZengIEEEIEEE Photonics Journal1943-06552017-01-019211210.1109/JPHOT.2017.26714367858653LCoS-Based Wavelength-Selective Switch for Future Finer-Grid Elastic Optical Networks Capable of All-Optical Wavelength ConversionDequan Xie0Danshi Wang1Min Zhang2Zichen Liu3Quan You4Qi Yang5Shaohua Yu6Wuhan National Laboratory for Optoelectronics, School of Optical and Electronic Information, Huazhong University of Science and Technology, Wuhan, ChinaState Key Laboratory of Information Photonics and Optical Communications, Beijing University of Posts and Telecommunications, Beijing, ChinaState Key Laboratory of Information Photonics and Optical Communications, Beijing University of Posts and Telecommunications, Beijing, ChinaState Key Laboratory of Optical Communication Technologies and Networks, Wuhan Research Institute of Posts and Telecommunications, Wuhan, Hubei, ChinaState Key Laboratory of Optical Communication Technologies and Networks, Wuhan Research Institute of Posts and Telecommunications, Wuhan, Hubei, ChinaState Key Laboratory of Optical Communication Technologies and Networks, Wuhan Research Institute of Posts and Telecommunications, Wuhan, Hubei, ChinaState Key Laboratory of Optical Communication Technologies and Networks, Wuhan Research Institute of Posts and Telecommunications, Wuhan, Hubei, ChinaA finer-grid wavelength-selective switch (WSS) based on liquid crystal on silicon is proposed, fabricated, and demonstrated. Based on the cost-effective method, namely combined lenses technique, the focal length is increased so that both the bandwidth setting resolution and grid granularity is improved from 12.5 to 6.25 GHz compared with the conventional WSS. To demonstrate its utility, we apply this finer-grid WSS to a reconfigurable optical add/drop multiplexer structure and an all-optical wavelength conversion (AOWC) module. To enable a finer-grid WSS, the performance of a finer-grid elastic optical network (EON) capable of AOWC is also investigated. Different from the conventional AOWC scheme for fixed-grid WDM networks, we propose and experimentally demonstrate a four-wave-mixing-based AOWC module specifically for EON. In addition to physical experiments, an optical network's control and management scheme corresponding to the designed physical scenario is also investigated. Experimental and simulation results show that the proposed method achieves higher spectrum efficiency, lower blocking probability, finer switching granularity, and higher conversion resolution.https://ieeexplore.ieee.org/document/7858653/Liquid-crystal devicesoptical switching deviceselastic optical networknonlinear optical signal processing.
collection DOAJ
language English
format Article
sources DOAJ
author Dequan Xie
Danshi Wang
Min Zhang
Zichen Liu
Quan You
Qi Yang
Shaohua Yu
spellingShingle Dequan Xie
Danshi Wang
Min Zhang
Zichen Liu
Quan You
Qi Yang
Shaohua Yu
LCoS-Based Wavelength-Selective Switch for Future Finer-Grid Elastic Optical Networks Capable of All-Optical Wavelength Conversion
IEEE Photonics Journal
Liquid-crystal devices
optical switching devices
elastic optical network
nonlinear optical signal processing.
author_facet Dequan Xie
Danshi Wang
Min Zhang
Zichen Liu
Quan You
Qi Yang
Shaohua Yu
author_sort Dequan Xie
title LCoS-Based Wavelength-Selective Switch for Future Finer-Grid Elastic Optical Networks Capable of All-Optical Wavelength Conversion
title_short LCoS-Based Wavelength-Selective Switch for Future Finer-Grid Elastic Optical Networks Capable of All-Optical Wavelength Conversion
title_full LCoS-Based Wavelength-Selective Switch for Future Finer-Grid Elastic Optical Networks Capable of All-Optical Wavelength Conversion
title_fullStr LCoS-Based Wavelength-Selective Switch for Future Finer-Grid Elastic Optical Networks Capable of All-Optical Wavelength Conversion
title_full_unstemmed LCoS-Based Wavelength-Selective Switch for Future Finer-Grid Elastic Optical Networks Capable of All-Optical Wavelength Conversion
title_sort lcos-based wavelength-selective switch for future finer-grid elastic optical networks capable of all-optical wavelength conversion
publisher IEEE
series IEEE Photonics Journal
issn 1943-0655
publishDate 2017-01-01
description A finer-grid wavelength-selective switch (WSS) based on liquid crystal on silicon is proposed, fabricated, and demonstrated. Based on the cost-effective method, namely combined lenses technique, the focal length is increased so that both the bandwidth setting resolution and grid granularity is improved from 12.5 to 6.25 GHz compared with the conventional WSS. To demonstrate its utility, we apply this finer-grid WSS to a reconfigurable optical add/drop multiplexer structure and an all-optical wavelength conversion (AOWC) module. To enable a finer-grid WSS, the performance of a finer-grid elastic optical network (EON) capable of AOWC is also investigated. Different from the conventional AOWC scheme for fixed-grid WDM networks, we propose and experimentally demonstrate a four-wave-mixing-based AOWC module specifically for EON. In addition to physical experiments, an optical network's control and management scheme corresponding to the designed physical scenario is also investigated. Experimental and simulation results show that the proposed method achieves higher spectrum efficiency, lower blocking probability, finer switching granularity, and higher conversion resolution.
topic Liquid-crystal devices
optical switching devices
elastic optical network
nonlinear optical signal processing.
url https://ieeexplore.ieee.org/document/7858653/
work_keys_str_mv AT dequanxie lcosbasedwavelengthselectiveswitchforfuturefinergridelasticopticalnetworkscapableofallopticalwavelengthconversion
AT danshiwang lcosbasedwavelengthselectiveswitchforfuturefinergridelasticopticalnetworkscapableofallopticalwavelengthconversion
AT minzhang lcosbasedwavelengthselectiveswitchforfuturefinergridelasticopticalnetworkscapableofallopticalwavelengthconversion
AT zichenliu lcosbasedwavelengthselectiveswitchforfuturefinergridelasticopticalnetworkscapableofallopticalwavelengthconversion
AT quanyou lcosbasedwavelengthselectiveswitchforfuturefinergridelasticopticalnetworkscapableofallopticalwavelengthconversion
AT qiyang lcosbasedwavelengthselectiveswitchforfuturefinergridelasticopticalnetworkscapableofallopticalwavelengthconversion
AT shaohuayu lcosbasedwavelengthselectiveswitchforfuturefinergridelasticopticalnetworkscapableofallopticalwavelengthconversion
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