光纤通信系统技术的发展、挑战与机遇

doi:10.11959/j.issn.1000-0801.2016129

摘要/Abstract

摘要：

光纤通信系统是现代互联网时代的核心支撑系统之一。首先概述了光纤通信系统关键技术的发展，并分析了其在蓬勃发展的云时代中的发展驱动力及在此驱动力下未来光纤通信系统面临的挑战与机遇。结合这些挑战与机遇，分别从光纤通信系统总体网络架构、骨干网络技术、城域网络技术、接入网络技术和基于软件定义网的新型光传送网络技术等多个方面，综合阐述光纤通信系统技术在云时代的演进发展趋势，以更有效地为未来互联网、数据中心互联、物联网、5G移动网络及智慧家居和智慧城市提供强有力的技术支撑。

关键词: 光纤通信, 云时代, 光传送网, 数据中心互联, 5G移动网络, 智慧家庭和智慧城市

Abstract:

Optical fiber communication system is one of the core supporting systems of the modern internet age.Firstly,major recent technological advances in optical fiber communication system were summarized.Then,the driving forces for its future development in the emerging cloud era,the future challenges and opportunities that it faced were analyzed.With the consideration of these challenges and opportunities,the future evolution paths in key areas such as optical fiber communication system overall network architectures,core network technologies,metro network technologies,access network technologiesand novel software-defined optical transport network technologies in the upcoming cloud erawere described,aiming to support future generations of internet,data center interconnect,internet of things and 5G mobile network,as well as the smart home and smart city initiativesmore effectively.

Key words: optical fiber communication, cloud era, optical transport network, data center interconnect, 5G mobile network, smart home and smart city

崔秀国,刘翔,操时宜,周敏. 光纤通信系统技术的发展、挑战与机遇[J]. 电信科学, 2016, 32(5): 34-43.

Xiuguo CUI,Xiang LIU,Shiyi CAO,Min ZHOU. Development,challenge and opportunity of optical fiber communication system technologies[J]. Telecommunications Science, 2016, 32(5): 34-43.

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参考文献 44

[1]	KAMINOW I P , KOCH T L . Optical fiber telecommunications Ⅳ[M]. Salt Lake: Academic Press, 2002.
[2]	KAMINOW I P . Optical fiber telecommunications Ⅴ[M]. Salt Lake: Academic Press, 2007.
[3]	KAMINOW I P , LI T , WILLNERA E . Optical fiber telecommunications Ⅵ[M]. Salt Lake: Academic Press, 2013.
[4]	WELLBROCK G , WANG T , ISHIDA O . New paradigms in optical communications and networks[J]. IEEE Communications Magazine, 2013,51(51): 22-23.
[5]	TOMKOS I , MUKHERJEE B , KOROTKY S K . The evolution of optical networking[J]. Proceedings of the IEEE, 2012,100(5): 1017-1022.
[6]	XU C , LIU X , WEI X . Differential phase-shift keying for high spectral efficiency optical transmissions[J]. IEEE Journal of Selected Topics in Quantum Electronics, 2004,10(2): 281-293.
[7]	JANSEN S L , VAN D B D , SPINNLER B , et al. Optical phase conjugation for ultra long-haul phase-shift-keyed transmission[J]. Journal of Lightwave Technology, 2006,24(1): 54-64.
[8]	HO K P . Phase-modulated optical communication systems[M]. New York: Springer, 2005.
[9]	LOWERY A J , LIANG D , . ARMSTRONG J.Orthogonal frequency division multiplexing for adaptive dispersion compensation in long haul WDM systems[C]// 2006 National Fiber Optic Engineers Conference， March 5-10， 2006， Anaheim,California. New Jersey： IEEE Press， 2006: 1-3.
[10]	SHIEH W , ATHAUDAGE C . Coherent optical orthogonal frequency division multiplexing[J]. Electronics Letters, 2006,42(10): 587-589.
[11]	SAVORY S J . Digital filters for coherent optical receivers[J]. Optics Express, 2008,16(2): 804-817.
[12]	SHIEH W , DIORDJEVIC I . Orthogonal frequency division multiplexing for optical communications[M]. Salt Lake： Academic Press, 2010.
[13]	WELLBROCK G , WANG T , ISHIDA O , et al. New paradigms in optical communications and networks[J]. IEEE Communications Magazine, 2013,51(51): 22-23.
[14]	WANG , TINGWELLBROCK , GLENNISHIDA . Next generation optical transport beyond 100G[J]. IEEE Communications Magazine, 2012,50(2): s10-s11.
[15]	BOYDEN E S , FENG Z , ERNST B . Millisecond-timescale,genetically targeted optical control of neural activity[J]. Nature Neuroscience, 2005,8(9): 1263-1268.
[16]	CHANDRASEKHAR S , LIU X , ZHU B , et al. Transmission of a 1.2-Tb/s 24-carrier no-guard-interval coherent OFDM superchannel over 7200-km of ultra-large-area fiber[C]// 35th European Conference on Optical Communication， Sept 20-24， 2009， Vienna,Austria. New Jersey： IEEE Press， 2009.
[17]	LIU X , CHANDRSEKHAR S , WINZER P J . Digital signal processing techniques enabling multi-Tb/s superchannel transmission[J]. IEEE Signal Processing Magazine, 2014,31(2): 16-24.
[18]	LIU X , CHANDRSEKHAR S . Superchannel for next-generation optical networks[C]// Optical Fiber Communications Conference and Exhibition（OFC）， March 9-13， 2014， San Francisco,CA,USA. New Jersey： IEEE Press， 2014: 1-33.
[19]	ZHOU Y R , SMITH K , PAYNE R , et al. Field trial demonstration of real-time optical superchannel transport up to 5.6 Tb/s over 359 km and2 Tb/s over a live 727km flexible grid link using 64G[J]. Journal of Lightwave Technology, 2015,34(2): 805-811.
[20]	JINNO M , TAKARA H , KOZICKI B , et al. Spectrum-efficient and scalable elastic optical path network:architecture,benefits,and enabling technologies. IEEE Communications Magazine, 2009,47(11): 66-73.
[21]	Characteristics of multi-degree reconfigurableoptical add/drop multiplexers:ITU-T Recommendation G.672[S]. 2012.
[22]	ANSHENG L , RICHARD J , LING L , et al. A high-speed silicon optical modulator based on a metal-oxide-semiconductor capacitor[J]. Nature, 2004,427(6975): 615.
[23]	YOO S J B . Optical packet and burst switching technologiesfor the future photonic Internet[J]. Journal of Lightwave Technology, 2006,24(12): 4468-4492.
[24]	DENG N , YANG Y , CHAN CK , et al. Intensity-modulated labeling and all-optical label swapping on angle-modulated optical packets[J]. IEEE Photonics Technology Letters, 2004,16(4): 1218-1220.
[25]	GEORGIOS S Z , JOAN T , NORBERTO A , et al. A novel metro architecture for flexible multi-granular services[J]. Optics Express, 2011,19(26): B509-B514.
[26]	XU Q F , SCHMIDT B , PRADHAN S , et al. Micrometre-scale silicon electro-optic modulator[J]. Nature, 2005,435(7040): 325-327.
[27]	SOLOMON A , FENGNIAN X , VLASOV Y A . Reinventing germanium avalanche photodetector for nanophotonic on-chip optical interconnects[J]. Nature, 2010,464(7285): 80-84.
[28]	SUN C , WADE M T , LEE Y , et al. Single-chip microprocessor that communicates directly using light[J]. Nature, 2015,528(7583): 534-538.
[29]	PHARE C T , LEE Y H D , CARDENAS J , et al. Graphene electro-optic modulator with 30 GHz bandwidth[J]. Nature Photonics, 2015,9(8).
[30]	SEOK T J , QUACK N , HAN S , et al. Large-scale broadband digital silicon photonic switches with vertical adiabatic couplers[J]. Optica, 2016,3(1): 64-70.
[31]	TAN D T H , SUN P C , FAINMAN Y , et al. Monolithic nonlinear pulse compressor on a silicon chip[J]. Nature Communications, 2010,1(8): 173-184.
[32]	FERRERA M , PARKAZZARI Y , RAZZARI L , et al. On-chip CMOS-compatible all-optical integrator[J]. Nature Communications, 2010,1(3): 605-629.
[33]	FAN L , WANG J , VARGHESE L T , et al. An all-silicon passive optical diode[J]. Science, 2012,335(6067): 447-450.
[34]	YAN S , DONG J , ZHENG A , et al. Chip-integrated optical power limiter based on an all-passive micro-ring resonator[J]. Scientific Reports, 2014(4): 6676.
[35]	LIU L , DONG J , GAO D , et al. On-chip passive three-port circuit of all-optical ordered-route transmission[J]. Scientific Reports, 2014(5).
[36]	KURAMOCHI E , NOZAKI K , SHINYA A , et al. Large-scale integration of wavelength-addressable all-optical memories on a photonic crystal chip[J]. Nature Photonics, 2014,8(6): 474-481.
[37]	FAKONAS J S , LEE H , KELAITA Y A , et al. Two-plasmon quantum interference[J]. Nature Photonics, 2014,8(4): 317-320.
[1]	SILVERSTONE J W , SANTAGATI R , BONNEAU D , et al. Qubit entanglement between ring-resonator photon-pair sources on a silicon chip[J]. Nature Communications, 2015(6).
[39]	KHAN M H , SHEN H , XUAN Y , et al. Ultrabroad-bandwidth arbitrary radiofrequency waveform generation with a silicon photonic chip-based spectral shaper[J]. Nature Photonics, 2010,4(2): 117-122.
[40]	SUN J , TIMURDOGAN E , YAACOBI A , et al. Large-scale nanophotonic phased array[J]. Nature, 2013,493(7431): 195-199.
[41]	WANG J , SHEN H , FAN L , et al. Reconfigurable radio-frequency arbitrary waveforms synthesized in a silicon photonic chip. Nature Communications, 2015(6): 5957.
[42]	MELIKYAN A , ALLOATTI L , MUSLIJA A , et al. High-speed plasmonic phase modulators[J]. Nature Photonics, 2014,8(8): 229-233.
[43]	ANSELL D , RADKO I P , HAN Z , et al. Hybrid graphene plasmonic waveguide modulators[J]. Nature Photonics, 2015(6).
[44]	HAFFNER C , HENI W , FEDORYSHYN Y , et al. All-plasmonic mach-zehnder modulator enabling optical high-speed communication at the microscale[J]. Nature Photonics, 2015,9(8).