波分复用光纤通信技术

294Vol.29No.420008JournalofUESTofChinaAug.20002000524***36***(610054)WDMWDM(EDFA)WDM.TN913[1,2](TDM)(WDM)TDM(PCM)TDM10Gbit/sTDM(Chromaticdispersion)(PMDPolarizationModeDispersion)25THz[3]1991WDM(EDFA)ITU-TWDM1995WDM[2~6]WDM8×2.5Gb/s16×2.5Gb/s8×10Gb/s16×10Gb/sNEC1996132×20Gb/s(2.64Tb/s)120kmWDMCLWDM128×2.5Gb/sWDM810Gb/sWDMWDM15000km[7]WDM11WDMWDM1)WDM2)WDMWDM33829WDMEDFAWDMWDM1WDM/a/Gbit⋅s-1/km1994BT(UK)WDM20(2×10)1201994WDM80(810)4121994WDM160(1610)1501994AT&TWDM340(1720)1501995NTTWDM20(2×10)27151995NTTWDM50(5×10)9051995NTTWDM100(10×10)6001996WDM160(16×10)5311996AT&TWDM100(20×5)9101996AT&TWDM1000(50×20)551996NTTWDM1100(55×20)1501996NECWDM2640(132×20)1201997MCI(U.S.A)WDM40(4×10)2751997CienaWDM40(16×2.5)6001997NECWDM1280(64×20)1001997KDD(Japan)WDM533(50×10.66)1655EDFA1997KDD(Japan)WDM100(40×2.5)12000980nmEDFA1998Alcatel(France)WDM320(32×10)320EDFA1998Corning(U.S.A)DWDM320(32×10)450LEAFTMsub-LSTM1999NTT(Japan)WDM250(25×10)92881999KDD(Japan)WDM341(32×10.66)6054DSF1999Lucent(U.S.A)WDM1000(25×40)3423)WDM(PDHSDH)()4)WDM()5)()43396)WDM7)WDM8)WDM//WDM/(Rx/Tx)(OADM)(OXC)(OA)9)WDM2WDM2.1WDM(MQW)(DFB)(DBR)10nm1THz()()1.5µm[8]2.2WDM2.3(EDFA)WDM1.5µmEDFA765Gb/s×2000kmEDFA60nm[9]11.7dB3Tb/sEDFA[10]70nm13dBEDFA[11](GEF)EDFAWDM(OADM)2.4EDFA[12]40GHzInPMZ(Mach-zehnder)1.5µm40Gb/s2MZ[13]16dB33.1WDM1996OFC(NZDFNon-zeroDispersionFiber34029G.655)WDM(FWM)G.652[14]3.2WDM()ITU-T193.1THz(1552.5nm)100GHz0.8nm(ZDSF)Pirelli83.3(PMD)FWMPMDPMDPMD3.4[15](SRS)(SBS)(SPM)(XPM)(FWM)LEAFG.652FWM3.5WDMWDMWDMWDM(OADMOXC)4WDMWDMWDMWDMWDM43411AlfernessRodCBonenfantPaulA,Newton,CurtisJ,etal.Apracticalvisionforopticaltransportnetworking.BellLabsTechnicalJournal,1999:3~62GreenPaulE.Opticalnetworkingupdate.IEEEJSelectAreasCommun,1996,14(5):764~7793BrackettCharlesA.IsthereanemergingconsensusonWDMnetworking.JLightwaveTech,1996,14(6):936~9414,..,1998,27(3):256~2605,,.ATM.,1998,27(4):371~3746.ECOC’94.,1994,23():35~407..,1999,(10):1~48ShizuoYamaguchi,MasaoSuzuki.SimultaneousstabilizationofthefrequencyandpowerofanAlGaAssemiconductorlaserbyuseoftheoptogalvaniceffectofkrypton.IEEEJQuantumElectron.1983,QE-19(10):1514~15199MatthewXMa,MortenNissov,HaifengLi,etal.765Gb/sover2000kmtransmissionusingC-bandandL-banderbiumdopedfiberamplifiers.OFC’99,1999,16:1~310KawanishiS,TakaraH,UchiyamaK,etal.3Tbit/s(160Gbit/s×19ch)OTDM-WDMtransmissionexperiment.OFC’99,1999,1:1~311SeokHyunYun,BongWanLee,HyangKyunKim,etal.Dynamicerbiumdopedfiberamplifierwithautomaticgainflattening.OFC’99,1999,28:1~312LeclereO,BrindelP,RouvillainD,etal.40Gbit/spolarization-independent,push-pullInPmach-zehndermodulatorforall-opticalregeneration.OFC’99,1999,35:1~313WolfsonD,HansenPB,KlochA,etal.Alloptical2Rregenerationat40Gbit/sinanSOA-basedmach-zehnderinterferometer.OFC’99,1999,36:1~314LepingWei,YiChen,WongGeraldG.TheevolutionofChina’sopticalfibernetworks.BellLabsTechJ,1999:125~14415ChraplyvyAndrewR.Limitationsonlightwavecommunicationsimposedbyoptical-fibernonlinearities.JLightwaveTech,1990,8(10):1548~1557WDMTechnologyforOpticalFiberCommunicationZhangHongbinQiuKunZhouDong(NationalKeyLabofOpticalFiberTransmissionandCommunicationNetworks,UESTofChinaChengdu610054)AbstractThedevelopmentsituationofWDMtechnologiesisintroducedinthispaper.TheprimarytechnologicalcharacteristicsareanalyzedandthekeyWDMtechnologiessuchaslaserwavelengthdivisionmultiplexerEDFAetc.areaddressed.SomeissuesinWDMsystemarealsodiscussed.Keywordsopticalfibercommunication;transmissionrate;transportcapacity;wavelengthdivisionmultiplexing;transparency;four-wavemixing波分复用光纤通信技术作者：张宏斌，邱昆，周东，ZhangHongbin，QiuKun，ZhouDong作者单位：电子科技大学宽带光纤传输与通信系统技术国家重点实验室,成都,610054刊名：电子科技大学学报英文刊名：JOURNALOFUNIVERSITYOFELECTRONICSCIENCEANDTECHNOLOGYOFCHINA年，卷(期)：2000，29(4)引用次数：13次参考文献(15条)1.AlfernessRodC.BonenfantPaulA.NewtonCurtisJApracticalvisionforopticaltransportnetworking19992.GreenPaulEOpticalnetworkingupdate1996(5)3.BrackettCharlesAIsthereanemergingconsensusonWDMnetworking1996(6)4.胡明.李乐民一种预约式波分复用网信道分配方法1998(3)5.张涛.邱昆.唐明光一种基于波分复用的ATM光交换结构1998(4)6.唐明光从ECOC'94看光纤通信的发展1994(ZK)7.邬贺铨中国光纤传送网的发展[期刊论文]-电信科学1999(10)8.ShizuoYamaguchi.MasaoSuzukiSimultaneousstabilizationofthefrequencyandpowerofanAlGaAssemiconductorlaserbyuseoftheoptogalvaniceffectofkrypton1983(10)9.MatthewXMa.MortenNissov.HaifengLi765Gb/sover2000kmtransmissionusingC-bandandL-banderbiumdopedfiberamplifiers199910.KawanishiS.TakaraH.UchiyamaK3Tbit/s(160Gbit/s×19ch)OTDM-WDMtransmissionexperiment199911.SeokHyunYun.BongWanLee.HyangKyunKimDynamicerbiumdopedfiberamplifierwithautomaticgainflattening199912.LeclereO.BrindelP.RouvillainD40Gbit/spolarization-independent,push-pullInPmach-zehndermodulatorforall-opticalregeneration199913.WolfsonD.HansenPB.KlochAAlloptical2Rregenerationat40Gbit/sinanSOA-basedmach-zehnderinterferometer199914.LepingWei.YiChen.WongGeraldGTheevolutionofChina'sopticalfibernetworks199915.ChraplyvyAndrewRLimitationsonlightwavecommunicationsimposedbyoptical-fibernonlinearities1990(10)相似文献(10条)1.学位论文刘姣姣高速光传输系统调制技术研究2009光纤通信的发展使得光传输系统朝着超大容量、超远距离的方向发展。40Gbit/s高速光传输系统具有更高的传输速率和更强的网络灵活性，是满足信息传输量增长需求的理想选