光残余边带调制码型与光时分复用系统关键技术的研究
|
摘要
目前广泛采用的密集波分复用(DWDM)传输技术与光时分复用(OTDM)传输技术相结合,已逐渐成为现代通信干线网的主体,并正向超高速、超大容量和超长距离的全光通信网络发展。本论文围绕光传输和光交换两方面,结合国家自然科学基金重点项目“高速光通信系统中的偏振模色散补偿及其相关技术与基础研究”和“全光波长交换技术研究”以及国家863项目“160Gbit/s一泵多纤光传输技术的研究”的实施,针对光残余边带(VSB)调制码型的实现与性质研究、提高光时分复用系统光谱利用率技术、光栅滤波器设计算法以及新型分布式光路交换网的组网应用等方面进行了深入的理论分析和实验研究,所取得的主要成果如下:
1.提出基于可调均匀Bragg光纤光栅产生残余边带调制码型的方案,建立了基于光阻带滤波器的VSB-NRZ/RZ码型调制格式的传输系统理论模型,分析了滤波器主要参数对VSB码型时域眼开度及频域边带抑止比的影响。其次在忽略了色散补偿光纤(DCF)与啁啾Bragg光纤光栅(CFBG)非理想特性的基础上,详细地分析了VSB-NRZ/RZ调制码型在基于DCF和CFBG色散补偿系统中的传输特性差异。在此基础上进一步分析了CFBG群时延纹波抖动对残余边带调制码型传输特性的影响。最后利用可调均匀Bragg光纤光栅产生的残余边带调制码型在试验室WDM光路交换试验网平台中做了试验验证。
2.提出一种利用设计光匹配滤波器用以提高OTDM光谱利用率的方案。首先建立了基于皮秒光纤激光器的OTDM系统理论模型,通过对OTDM系统非理想特性的研究,系统地分析了OTDM各支路信号幅度的差异及抖动、时延差异与抖动对OTDM时频特性的影响。首次提出了通过设计解复用开关窗口的匹配光滤波器来提高OTDM信号频带利用率的方案,并利用阵列波导光栅(AWG)对4×10Gbit/sOTDM信号进行了光谱压缩,完成了时钟提取与解复用实验。实验结果表明进行光谱压缩以后的OTDM信号的频带利用率提高了约3倍,在传输100km之后仍可以进行时钟提取与解复用,验证了该方案的可行性。
3.提出了一种插值搜索算法,利用该算法设计了光带通滤波器与低色散型带通滤波器,通过选取合适的插值函数得到了比传统GLM算法更优的结果。其次结合遗传算法对CFBG光栅性能做了优化,减小了CFBG的群时延纹波(GDR),从而验证了非对称切趾抑制带内群时延纹波的有效性。
4.完善了基于光路交换的全光网演示系统的具体功能,优化了突发交换解决方案,减少了突发呼叫竞争。结合全光网组播技术,提出了一种适用于大规模网状光网络的多路分布式链路检测的解决方案。
At present the combination of DWDM with OTDM techniques has gradually become the main part of backbone of modern communication networks,which is regarded as the development of the ultra-high speed,ultra high capacity and ultra long haul optical transmission communication networks.Optical transmission and optical switching are the two key aspects of optical communications.In this paper,supported by the key projects of National Natural Science Fondation "Research on PMD compensation and related infrastructure technologies in high speed optical communication systems","Study on all optical circuit switching technology" and National 863 project "Study on 160Gbit/s one pump multi-fiber optical transmission technology",we conduct a deep investigation into the theoretical and experimental research on the novel optical vestigial sideband(VSB) modulation formats,the increase of spectrum efficiency of OTDM,algorithm of grating fiber design and wavelength routing network applications.
The main results achieved are as follows:
1.The scheme of implimetation of optical vestigial sideband modulation formats with tunable uniform Bragg grating was proposed.The theoretical model of VSB-NRZ/RZ modulation system with optical bandstop filter was build.The main effects of EOP and the suppression ratio of sideband of VSB codes were analyzed induced by the parameters of optical filter.And then by negelecting the nonideal properties of DCF and CFBG,the differences of transmissions were analyzed in detail. A further analysis was made considering the effect of group delay ripple of CFBG in VSB transmission system.At last,an experiment of VSB modulation with tunable Bragg grating in all optical WDM network platforms was made to verify the feasibility of this proposal.
2.For the first time,the scheme of the increase of spectrum efficiency of OTDM was investigated by employing matiching optical filter.The theoretical model of OTDM system based on picosecond pulse laser sources was build.The effects in time and spectrum domain of OTDM signals were discussed induced by these factors such as the difference of amplitude and vibration of amplitude and delay in each channel.The original proposal was made to increase the spectrum efficiency of OTDM by designing the matching filter of demultiplexing switching windows.Related experiments were made for the first time in which the 4×10Gbit/s OTDM signals were compressed by employing Arrey Waveguide Grating(AWG).Furthermore the clock extraction and demultiplexing of OTDM over 100 km transimsion were implemented as well.The experimental results show the increase of almost three times of spectrum efficiency comparing with the original OTDM singals which verified the feasibility of the scheme.
3.A novel interpolation and searching algorithm was proposed,which designed and rebuild the optical bandpass and low dispersion filters.Better results were obtained by selcting proper interpolation functions comparing with that of tranditional GLM algorithm.And then optimization of CFBG was made by employing Genetic Algorithm (GA) to minimize the in-band group delay ripple(GDR) of CFBG,which verified the effectiveness of asymmetrical apodization scheme.
4.Specific functional modules of all optical networks based on optical circuit switching were established and enhanced.The optimal scheme of burst contention was proposed Moreover combining with multicast technology,a novel scheme was investigated which was considered as the distributed and multi-link fault detections used in mesh and large scale optical networks.
1.提出基于可调均匀Bragg光纤光栅产生残余边带调制码型的方案,建立了基于光阻带滤波器的VSB-NRZ/RZ码型调制格式的传输系统理论模型,分析了滤波器主要参数对VSB码型时域眼开度及频域边带抑止比的影响。其次在忽略了色散补偿光纤(DCF)与啁啾Bragg光纤光栅(CFBG)非理想特性的基础上,详细地分析了VSB-NRZ/RZ调制码型在基于DCF和CFBG色散补偿系统中的传输特性差异。在此基础上进一步分析了CFBG群时延纹波抖动对残余边带调制码型传输特性的影响。最后利用可调均匀Bragg光纤光栅产生的残余边带调制码型在试验室WDM光路交换试验网平台中做了试验验证。
2.提出一种利用设计光匹配滤波器用以提高OTDM光谱利用率的方案。首先建立了基于皮秒光纤激光器的OTDM系统理论模型,通过对OTDM系统非理想特性的研究,系统地分析了OTDM各支路信号幅度的差异及抖动、时延差异与抖动对OTDM时频特性的影响。首次提出了通过设计解复用开关窗口的匹配光滤波器来提高OTDM信号频带利用率的方案,并利用阵列波导光栅(AWG)对4×10Gbit/sOTDM信号进行了光谱压缩,完成了时钟提取与解复用实验。实验结果表明进行光谱压缩以后的OTDM信号的频带利用率提高了约3倍,在传输100km之后仍可以进行时钟提取与解复用,验证了该方案的可行性。
3.提出了一种插值搜索算法,利用该算法设计了光带通滤波器与低色散型带通滤波器,通过选取合适的插值函数得到了比传统GLM算法更优的结果。其次结合遗传算法对CFBG光栅性能做了优化,减小了CFBG的群时延纹波(GDR),从而验证了非对称切趾抑制带内群时延纹波的有效性。
4.完善了基于光路交换的全光网演示系统的具体功能,优化了突发交换解决方案,减少了突发呼叫竞争。结合全光网组播技术,提出了一种适用于大规模网状光网络的多路分布式链路检测的解决方案。
At present the combination of DWDM with OTDM techniques has gradually become the main part of backbone of modern communication networks,which is regarded as the development of the ultra-high speed,ultra high capacity and ultra long haul optical transmission communication networks.Optical transmission and optical switching are the two key aspects of optical communications.In this paper,supported by the key projects of National Natural Science Fondation "Research on PMD compensation and related infrastructure technologies in high speed optical communication systems","Study on all optical circuit switching technology" and National 863 project "Study on 160Gbit/s one pump multi-fiber optical transmission technology",we conduct a deep investigation into the theoretical and experimental research on the novel optical vestigial sideband(VSB) modulation formats,the increase of spectrum efficiency of OTDM,algorithm of grating fiber design and wavelength routing network applications.
The main results achieved are as follows:
1.The scheme of implimetation of optical vestigial sideband modulation formats with tunable uniform Bragg grating was proposed.The theoretical model of VSB-NRZ/RZ modulation system with optical bandstop filter was build.The main effects of EOP and the suppression ratio of sideband of VSB codes were analyzed induced by the parameters of optical filter.And then by negelecting the nonideal properties of DCF and CFBG,the differences of transmissions were analyzed in detail. A further analysis was made considering the effect of group delay ripple of CFBG in VSB transmission system.At last,an experiment of VSB modulation with tunable Bragg grating in all optical WDM network platforms was made to verify the feasibility of this proposal.
2.For the first time,the scheme of the increase of spectrum efficiency of OTDM was investigated by employing matiching optical filter.The theoretical model of OTDM system based on picosecond pulse laser sources was build.The effects in time and spectrum domain of OTDM signals were discussed induced by these factors such as the difference of amplitude and vibration of amplitude and delay in each channel.The original proposal was made to increase the spectrum efficiency of OTDM by designing the matching filter of demultiplexing switching windows.Related experiments were made for the first time in which the 4×10Gbit/s OTDM signals were compressed by employing Arrey Waveguide Grating(AWG).Furthermore the clock extraction and demultiplexing of OTDM over 100 km transimsion were implemented as well.The experimental results show the increase of almost three times of spectrum efficiency comparing with the original OTDM singals which verified the feasibility of the scheme.
3.A novel interpolation and searching algorithm was proposed,which designed and rebuild the optical bandpass and low dispersion filters.Better results were obtained by selcting proper interpolation functions comparing with that of tranditional GLM algorithm.And then optimization of CFBG was made by employing Genetic Algorithm (GA) to minimize the in-band group delay ripple(GDR) of CFBG,which verified the effectiveness of asymmetrical apodization scheme.
4.Specific functional modules of all optical networks based on optical circuit switching were established and enhanced.The optimal scheme of burst contention was proposed Moreover combining with multicast technology,a novel scheme was investigated which was considered as the distributed and multi-link fault detections used in mesh and large scale optical networks.
引文
[1]新摩尔定律带动互联网革命,http://tech.sina.com.cn/news/internet/1999-10-16/
[2]http://www.level3.com/
[3]简水生,因特网从空前繁荣到“效率时代”的启示和展望,现代通信 2002,1期,pp.1-4
[4]光通信发展的回顺与展望,http://www.cnii.com.cn/
[5]C.Baack and G.walf,Photonics in future telecommunications,Proceedings of the IEEE,1993,vol.81,pp.1624-1632.
[6]李从奇,陈娟,全光网的发展趋势及其挑战,电信网技术,2006,pp.13-16.
[7]S.C.Chan,L.Minghua,S.S.Udpa,L.Udpa,and D.W.Jacobson,All-optical dense WDM wide-area communication network,IEEE 39th Midwest symposium on circuits and Systems,1996,vol.3,pp.1157-1160.
[8]I.P.Kaminow,C.R.Doerr,C.Dragne,T.Koch,U.Koren,A.A.M.Saleh,A.J.Kirby,C.M.Ozveren,B.Schofield,R.E.Thomas,R.A.Barry,D.M.Castagnozzi,V.W.S.Chan,B.R.Hemenway,Jr.,D.Marquis,S.A.Parikh,M.L.Stevens,E.A.Swanson,S.G.Finn,and R.G.Gallager,A wideband all-optical WDM network,selected Areas in Communications,IEEE Journal on,1996,vol.14,pp.780-799.
[9]吴重阳,光纤光缆技术大展望 江苏亨通光电股份有限公司http://www.gglchina.com/lianjie/guangqian/coverread.asp?cover_id=31/
[10]T.N.Nielsen,A.J.Stentz,K.Rottwitt,D.S.Vengsarkar,Z.J.Chen,3.28 Tb/s(82×40 Gb/s)transmission over 3×100km nonzero-dispersion fiber using dual C- and L-band hybrid Raman/erbium doped inline amplifers,Optical Fiber Communications Conference 2000,2000,vol.4,pp.236-238.
[11]L.D.Garrett,A.H.Gnauck,EForghieri,V.Gusmeroil,and D.Scarano,16×10Gb/s WDM transmission over 840-km SMF using eleven broad-band chirped fiber gratings,photonics Technology Letters,IEEE,1999,voh 11,pp.484-486
[12]AkiraHirano,应用在超高速光传输系统里的新兴调制方式,网络电信,2005,no.1,pp.52-54.
[13]D.Sandel,S.Bhandare,A.F.Abas,B.milivojevic,R.Noe,M.Guy,and M.Lapointe,Automatic tunable chromatic dispersion compensation at 40Gb/s in Ask and DPSK,NRZ,and CSRZ 263-km transmission experiments,Photonics Technology letters,IEEE,2004,voh 16,pp.2568-2570.
[14]顾畹仪,WDM超长距离光传输技术。北京:北京邮电大学出版社,2005.
[15]C.Yong,C.Jihong,C.Ting,and J.Shuisheng,Advanced modulation formats for long-haul optical-transmission systems with dispersion compensation by chirped FBG,Microwave and Optical Technology Letters,2006,vol.48,pp.344.
[16]C.Fuerst,G.Mohs,H.Geiger,and G.Fischer,Performance limts of nonlinear RZ and NRZ coded transmission at 10 and 40 Gb/s on different fibers,Optical Fiber Communications Conference 2000,2000,vol.2,pp.302-304.
[17]霍晓莉,超长距离传输系统应选择成熟技术,北京电子,2006,vol.3,pp.24-24.
[18]DavidZ.Chen,Glenn Wellbrock,Steve J.Penticost,Dilip Patel,Christian Rasmussen,Mark C. Childers,X.Yang,and M.Y.Frankel,World's first 40Gbps overy on a field-deployed,10 Gbps,mixed-fiber,1200km,Ultra long-haul system,Optical Fiber Communication Conference 2005,2005,pp.OTuH4.
[19]D.F.Grosz,A.Agarwal,S.Banerjee,D.N.Maywar,and A.P.Kung,All-Raman ultralong-haul single-wideband DWDM transmission systems with OADM capability,lightwave Technology,Journal of,2004,vol.22,pp.423-432.
[20]G.C.Gupta,L.L.Wang,O.Mizuhara,R.E.Tench,N.N.Dang,P.Tabaddor,and A.Judy,3.2 Tb/s transmission with spectral efficiency of 0.8 b/s/Hz over 21/spl times/ 100km of dispersion-managed high local dispersion fiber using all-Raman amplified spas,Photonics Technology Letters,IEEE,2003,vol.15,pp.996-998.
[21]Xiang Zhou,Jianjun Yu,Mei Du,and Guodong Zhang,2Tb/s (20x107 Gb/s)RZ-DQPSK straight-line transmission over 1005 km of standard single mode fiber (SSMF)without Raman amplification,OFC2008,2008,OMQ3.
[22]C.Rasmussen,T.Fjelde,J.Bennike,F.A.L.F.Liu,S.A.D.S.Dey,B.Mikkelsen,P.Mamyshev,P.Serbe,P.Van der Wagt,YAkasaka,D.Harris,D.Gapontsev,V.Ivshin,and P.Reeves-Hall,DWDM 40G transmission over trans-Pacific distance(10,000km)casing CSRZ-DPSK,enhanced FEC nad all-Raman amplified 100km UltraWave/spl trade/ fiber spans,Optical Fiber Communiactions Conference 2003,2003,OFC2003.
[23]R.C.Lee,H.A.Abdul-Rashid,M.T.Al-Qdah,H.T.Chuah,M.B.Tayahi,and S.Lanka,The effects of phase errors on optical SSB system performance,Microwave and Optical Technology Letters,200,vol.48,pp.1574-1578.
[24]Y.Yamada,S.I.Nakagawa,Y.Kurosawa,T.Kawazawa,H.Taga,and K.Goto,2Tbit/s(200*10 Gbit/s)over 9240 km transmission experiment with 0.15 nm channel spacing using VSB format,Electronics Letters,2002,vol.38,pp.328-330.
[25]Toshihito Fujiwara,Koji Kikushima,140 Carrier,20GHz SCM Signal Transmission across 200km SMF by Two-step Sideband Suppression Scheme in Optical SSB Modulation,Optical Fiber Communiactions Conference 2007,2007,OME2.
[26]Nobuhiko Kikuchi,Kohei Mandai and Shinya Sasaki,Experimental Demonstration of Incoherent Optical Multilevel Staggered-APSK (Amplitude-and Phase-Shift Keying)Signaling,Optical Fiber Communiactions Conference 2008,2008,OMI3.
[27]Chun-Ting Lin,Sheng-Peng Dai,Wen-Jr Jiang,Jason Chen,Yu-Min Lin,Po Tsung Shih,Peng-Chun Peng,and Sien Chi,Experimental Demonstration of Optical Colorless Direct-Detection OFDM Signals with 16-and 64-QAM Formats beyond 15 Gb/s,2008,MO3El.
[28]Greg Raybon and Peter J.Winzer,100 Gb/s Challenges and Solutions,Optical Fiber Communiactions Conference 2008,2008,OTuGl.
[29]甘朝钦,高速传送:40Gbps至100Gbps,通信世界,2007,vol.6,pp.83-84.
[30]D.Z.Chen,TJ.Xia,G.Wellbrock,P.Mamyshev,S.Penticost,GGrosso,A.Puc,P.Perrier,and H.Fevrier,New Field Trial Distance Record of 3040 km on Wide Reach WDM With 10 and 40 Gb/s Transmission including OC-768 Traffic without Regeneration,Lightwave Technology,Journal of,2007,vol.25,pp.28-37.
[31]S.N.knudsen and L.Gruner-Nielsen,New fibers for future telecommunication systems,lasers and Electro-Optics Society 2000 Annual Meeting.LEOS 2000.13th Annual Meeting.IEEE, 2000.
[32]T.Tsuda,Y.Akasaka,S.Sentsui,K.Aiso,Y.Suzuki,and T.Kamiya,Broad band dispersion slope compensation of dispersion shifted fiber using negative sloe fiber,Optical Communication,1998.24th European Conference on,1998.
[33]Liu Yan,Zheng Kai,Tan Zhongwei et al,Good performance of chirped fiber Bragg gratings obtained by asymmetrically one-side exposure apodization,Acta Physica Sinica,2006,vol.55,pp.5859-5865.
[34]Tan Zhongwei,Liu Yan,Ning Tigang,Jian Shuisheng,The generation of group delay ripple of chirped fiber gratings,Chinese Optics Letter,2004,vol.2,pp.18-20.
[35]Ning Tigang,Liu Yan,Tan Zhongwei,Jian Shuisheng,Impact on dispersion compensated system using chirped fiber Bragg grating with delay ripple,Acta Optica Sinica,2003,vol.23,pp.1064-1067
[36]Pei Li,Jian Shuisheng,Xie zenghua,Dispersion compensation optical fiber grating with low ripple coefficient,Acta Optica Sinica,2002,vol.22,pp.336-339
[37]Xie zenghua,Ning Tigang,Pei Li,et al.Fabrication of 13 cm linearly chirped fiber grating,Acta Optica Sinica,2001,vol.21,pp.1381-1383
[38]Julien Poirrier,FEC Operation in Combination With Electronic Dispersion Compensation,Optical Fiber Communications Conference 2008,2008,OTHO4.
[39]John D.Downie,Jason Hurley,Yihong Mauro,and Sergey Lobanov,On the Use of MLSE with Non-Optimal Demodulation Filtering for Optical Duobinary Transmission,Optical Fiber Communications Conference 2008,2008,OTHO5.
[40]陈勇,全光通信网关键技术的研究与实现,北京交通大学博士论文,2006.
[41]Y.Chen,J.H.Cao,Z.W.Tan,Y.Liu,T.Chen,L.N.Ma,D.Y.Chang,T.G.Ning,L.Pei,and S.S.Jian,8×10 Gb/s transmission system over 2015km with dispersion compensation by CFBG,Guangdianzi Jiguang/Journal of Optoelectronics Laser,2005,vol.16,pp.942-946.
[42]D.McGhan,C.Laperle,A.Savchenko,L.Chuandong,G.Mak,and M.O'Sullivan,5120km RZ-DPSK transmission over G.652 fiber at 10 Gb/s without optical dispersion compensation,Photonics Technology Letters,IEEE,1996,vol.18,pp.400-402.
[43]G.Raybon,A.Agarwal,S.Chandrasekhar,and R.J.A.E.R.J.Essiambre,Transmission of 42.7-Gb/s VSB-CSRZ over 1600km and four OADM nodes with a spectral efficiency of 0.8bit/s/Hz,Optical Communication,2005.
[44]R.Ludwig,S.Weisser,C.Schmidt-Langhorst,L.Raddatz,and C.Schubert,Unrepeatered Transmission of 160 Gb/s Rz-DPSKover 240 km Dispersion Managed Fiber,ECOC 2007,2007.
[45]D.van den Borne,S.L.Jansen,E.Gottald,P.M.Krummrich,G.D.Khoe,and H.de Waardt,1.6-b/s/Hz Spectrally Efficient Transmission Over 1700 km of SSMF 40*85.6 Gb/s POLMUX-RZ-DQPSK,Lightwave Technology,Journal of,2007,vol.25,pp.222-232.
[46]吕洪君,胡睿,李子晓,光纤光参量放大器及其应用,2004,vol.17,pp.8-11.
[47]A.S.Omar,FEC techniques in submarine transmission systems,Optical Fiber Communication Conference and Exhibit 2001,2001,vol.2,pp.TuF1.
[48]T.Mizuochi,K.Kubo,H.Yoshida,H.Fujita,H.Tagami,M.Akita,and K.Motoshima,Next generation FEC for optical transmission systems,Optical Fiber Communiactions Conference 2003,2003,vol.2,pp.527-528.
[49]J.X.Cai,M.Nissov,A.N.Pflipetskii,A.J.Lucero,C.R.Davidson,D.Foursa,H.Kidorf,M.A.mills,R.Menges,O.C.Corbett,D.Sutton,and N.S.Bergano,2.4Tb/s transmission over transoceanic distance using optimum FEC overhead and 48%spectral efficiency,Optical Fiber Communications Conference and Exhibit 2001,2001,vol.4,pp.PD24.
[50]T.Mizuochi,K.Ouchi,T.Kobayashi,Y.Miyata,K.Kuni,H.Tagami,K.Kubo,H.Yoshida,M.Akita,and K.Motoshima,Experimental demonstration of net coding gain of 10.1 dB using 12.4 Gb/s block turbo code with 3-bit soft decision,Optical Fiber Communications Conference 2003,2003,vol.3,pp.PD21.
[51]Ouchi,A fully integrated block turbo code FEC for 10 Gb/s optical communication systems,Technical Digest of OFC2006,2006,pp.OTuK4,
[52]Y.Konishi,Block turbo code encoded 24.8Gbps RZ-DQPSK experiment using parallel prefix network based differential precoder,Optical Fiber Communications Conference 2007,2007,pp.13B4.
[53]Takashi Mizuochi,Next Generation FEC for Optical Communication,Optical Fiber Communications Conference 2008,2008,pp.OTuE5.
[54]Wedding B.,Haslach C.N.,Enhanced PMD mitigation by polarization scrambling and forward error correction,Optical Fiber Communication Conference and Exhibit 2001,2001,vol.3,pp.WAA1.
[55]M.F.S.Ferreira and M.H.Sousa,Dispersion-managed solitons in optical fiber systems,Proceedings of 2005 7th International Conference on Transparent Optical Networks,ICTON2005,2005.
[56]Y.H.C.Kwan and P.K.A.Wai,Design of dispersion managed solution systems,Pacific Rim Conference on Laser and Electro-Optics,CLEO- Technical Digest,2001.
[57]W.J.Tomlinson,Technologies for Dynamic Gain and Channel Power Equalization,Conference on Optical Fiber Communication,Technical Digest Series,2003.
[58]Y.Imai,K.Lizuka,and R.T.B.James,Phase-noise-free coherent optical communication system utilizing differential polarization shift keying(DPolSK),Journal of Lightwave Technology,1990,vol.8,pp.691-698.
[59]P.J.Almeida,F.Parmigiani,M.Ibsen,K.Mukasa,P.Petropoulos,and D.J.Richardson,35dB Channel Suppression in OTDM Add-Drop Multiplexing Based on Time-Frequency Signal Processing,Optical Fiber Communication Conference 2006,2006,pp.OWW3.
[60]J.J.Vegas Olmos,J.P.Turkiewicz,M.Garcia Larrode,I.Tafur Monroy,and A.M.J.Koonen,FSK-WDM to IM-OTDM conversion for fiber-to-thepremises access networks,Optical Fiber Communication Conference 2006,2006,pp.OFE6.
[61]M.Shirane,Y.Hashimoto,H.Yamada,A compact optical sampling measurement system using mode21ocked laser2 diode modules,IEEE Photonics Technology Letter,2000,vol.12,pp.1537-1539.
[62]彭璨,姚敏玉,张洪明,徐千帆,张剑锋,高以智,10 GHz Actively Mode-locked Fiber Ring Laser,中国激光,2003,vol.2,pp.17-19.
[63]Ivan Kaminow厉鼎毅主编 余力等译《光纤通信》中文版 北京:北京邮电大学出版社,2006.
[64]Chien-Chung Lee,Yung-Kuang Chen,and Shien-Kuei Liaw,Single-longitudinal-mode fiber laser with a passive multiple-ring cavity and its application for video transmission,Optics Letters,Vol.23,pp.358-360.
[65]Xinhuan Feng,Yange Liu,Shenggui Fu,Shuzhong Yuan,Xiaoyi Dong,Switchable dual-wavelength ytterbium-doped fiber laser based on a few-mode fiber grating,Photonics Technology Letters,IEEE,2004,vol.16,pp.762-764.
[66]Dae Seung Moon,Un-Chul Paek,and Youngjoo Chung,Multi-wavelength lasing oscillations in an erbium-doped fiber laser using few-mode fiber Bragg grating,Optics Express,2004,Vol.12,pp.6147-6152.
[67]Yamamoto T.,Yoshida E.,Tamura K.R.,Yonenaga K.,Nakazawa M.,640-Gbit/s optical TDM transmission over 92 km through adispersion-managed fiber consisting of single-mode fiber and reverse dispersion fiber,Photonics Technology Letters,IEEE,2000,vol.12,pp.353-355.
[68]Alistair J.Poustie,Neil Finlayson,and Paul Harper,Multiwavelength fiber laser using a spatial mode beating filter,Optics Letters,1994,Vol.19,pp.716-718
[69]S.V.Chernikov,Y.Zhu,J.R.Taylor,and V.P.Gapontsev,Supercontinuum self-Q-switched ytterbium fiber laser,Optics Letters,1997,Vol.22,pp.298-300.
[70]Brian R.Washburn,Scott A.Diddams,Nathan R.Newbury,Jeffrey W.Nicholson,Man F.Yan,and Carsten G.Jrgensen,Phase-locked,erbium-fiber-laser-based frequency comb in the near infrared,Optics Letters,2004,Vol.29,pp.250-252.
[71]A.D.Ellis,K.Smith,and D.M.Patrick,All optical clock recovery at bit rates up to 40Gbit/s,Electronics Letters,1993,vol.29,pp.1323-1324.
[72]L.Yuhua,K.Cheolhwan,L.Guifang,Y.Kaneko,R.L.Jungerman,and O.Buccafusca,Wavelength and polarization insensitive all-optical recovery from 96-Gb/s data by using a two-section gain-coupled DFB laser,Photonics Technology Letters,IEEE,2003,vol.15,pp.590-592.
[73]D.H.Kim,S.H.Kim,J.C.Jo,and S.S.Choi,Ultrahigh speed clock recovery with optical phase lock loop based on four-wave-mixing in a semiconductor optical amplifer,Optics Communications,2000,vol.182,pp.329-334.
[74]D.L.Butler,J.S.Wey,M.W.Chbat,G.L.Burdge,and J.Goldhar,Optical recovery from a data stream of an arbitrary bit rate by use of stimulated Brillouin scattering,Optics letters,1995,vol.20,pp.560-562.
[75]王安斌,伍剑,林金桐,基于电吸收调制器的高速时钟信号的提取,2003,光子学报,vol.32,pp.1-7
[76]Seung-Woo Seo,Bergman K.,Prucnal P.R.,Transparent optical networks with time-division multiplexing,Selected Areas in Communications,IEEE Journal on,1996,vol.14,pp.1039-1051.
[77]Klaus Grobe,et al.,Assessment of 40Gb/s Techniques for Metro/Regional Applications,OFC'2006,NThA1.
[78]Wong C.S,Tsang H.K.,Polarization-independent wavelength conversion at 10 Gbit/s using birefringence switching in a semiconductor optical amplifier,IEEE Photonics Technology Letters,2003,vol.15,pp.87-89.
[79]赵伯林,林礼煌,日电研制适用于1 Tbit/s脉冲的超高速半导体全光开关,激光与光子学进展,1995,vol.2,pp.26-27.
[80]友清,用半导体超晶格实现250 fs全光开关,激光与光子学进展,1996,vol.10,pp.28-29.
[81]Sharping Jay E.,Marco Fiorentino,Prem Kumar,All-optical switching based on cross-phase modulation in microstructure fiber,IEEE Photonics Technology Letters,.2002,vol.14,pp.77-79.
[82]刘玉敏,俞重远,张建忠,粒子群优化算法用于光纤布拉格光栅综合问题的研究,激光杂志,2005,26(4):69-70.
[83]文晓燕,余谦,基于差分演化算法的啁啾光纤光栅参数重构方法,仪器仪表学报,2008,vol.29,pp.2216-2219.
[84]张荣佯,郑世杰,夏彦君,张绥远,支持向量回归算法在光纤光栅非均匀应变重构中的应用,光学学报,2008,vol.28,pp.1513-1517.
[85]WinickK.A,Roman J.E,Design of corrugated waveguide filters fourier transform techniques,IEEE J.Quantum Electron.,1990,vol.2,pp.1918-1929.
[86]Peral E,Capmany J,Marti J,Iterative solution to the Gelfan-Levitan-Marchenko coupled equations and application to synthesis of fiber gratings,IEEE J.Quantum Electron.,1996,vol.32,pp.2078-2084.
[87]Muriel M.A.,Azana J.,Carballar A.,Fiber grating synthesis by use of time frequency representation,Optics Letters,1998,vol.23,pp.1526-1528.
[88]Azana J.,Muriel M.A.,Chen LFiber Bragg Grating period reconstruction using time-frequency signal analysis and application to distributed sensing,IEEE/OSA Journal of Lightwave Technology,2001,vol.19,pp.646-654.
[89]Feced R,Zervas M.N.,Muriel M.A.,An efficient inverse scattering algorithm for the design of nonuniform fiber Bragg gratings,Journal of Quantum E lectronics,IEEE,1999,vol.35,pp.1105-1115
[90]Holland J.H.,Adaptation in natural and artificial systems,University of Michigan Press,Ann Arbor,1975.
[91]Fogel L.J.,Owens A.J.,Walsh M J.,Artificial intelligence through simulated evolution,John Wiley,Chichester,UK,1996.
[92]Kirkpatrick S.,Optimization by simulated annealing.Science,1983,vol.220,pp.671-680.
[93]Storn R.,Differential Evolution Design of an IIR-Filter,IEEE International.Conference On Evolutionary Computation,Nagoya,1996,vol.26 pp.8-273.
[94]Dorigo M.,Maniezzo V.,Colormi A.,The ant system:optimization by a colony of cooperating agents,IEEE Transactions on Systems,Man,and Cybernetics-Part B,19 96,vol.26,pp.1-13.
[95]简水生,“光纤网的发展与机遇”,中国电子商情:通信市场,no.11,2001,pp.13-18.
[96]简水生,新一代、高度安全、超大容量、无阻塞全光网是信息社会的基础,光通信,2003,vol.12,pp.14-21.
[97]简水生,建立“新一代、高度安全、超大容量、无阻塞全光网”是我国本世纪初叶重大科学战略工程,网络电信,2003,no.11,pp.16-2I.
[98]A.A.M.Saleh,Overview of the MONET,Multiwavelength Optical Networking program,Photonics Technology Letters,IEEE,1990,vol.2,pp.714-717.
[99]M.S.Goodman,C.L.Allyn,R.Tkach,D.I.Pompey,m.R.Wilder,K.Goel,and B.Tyrone,The multiwavelength optical networking program(MONET),Military Communications Conference,IEEE,1996,vol.1,pp.121-124.
[100]http://cords.europa.eu/infowin/acts/rus/projects/
[101]L.Jintong and W.Jian,Optical networking testbeds in China,Optical Communications Fiber Conference 2006,2006,vo.1,pp.OWU2.
[102]http://www.gaikuo.com/html/3/2007/0331/17504.html
[103]纪越峰等,光突发交换网络.北京:北京邮电大学出版社,2005.
[104]"GENI:global environment for network innovations," http://www.geni.net/
[105]"FIND:future Internet network design," http://find.isi.edu/
[106]http://www.hudong.com/wiki/暗光纤/
[1]T.N.Nielsen,A.J.Stentz,K.Rottwitt,D.S.Vengsarkar,Z.J.Chen,3.28 Tb/s(82×40 Gb/s)transmission over 3×100km nonzero-dispersion fiber using dual C- and L-band hybrid Raman/erbium doped inline amplifers,Optical Fiber Communications Conference 2000,2000,vol.4,pp.236-238.
[2]F.Heismann,D.A.Fishman,and D.L.wilson,Automatic compensation of first order polarization mode dispersion in a 10 Gb/s transmission system,24th European Conference on Optical Communication,1998,vol.1,pp.529-530.
[3]C.Yong,C.Jihong,C.Ting,and J.Shuisheng,Advanced modulation formats for long-haul optical-transmission systems with dispersion compensation by chirped FBG,Microwave and Optical Technology Letters,2006,vol.48,pp.344.
[4]L.D.Garrett,A.H.Gnauck,F.Forghieri,V.Gusmeroil,and D.Scarano,16×10Gb/s WDM transmission over 840-km SMF using eleven broad-band chirped fiber gratings,photonics Technology Letters,IEEE,1999,vol.11,pp.484-486.
[5]Z.Tan,S.Jian,Y.Liu,and T.Ning,10Gb/s transmission over 1400km of G.652 fiber using chirped fiber Bragg gratings dispersion compensation,APOC2004,2004.
[6]AkiraHirano,应用在超高速光传输系统里的新兴调制方式,网络电信,2005,no.1,pp.52-54.
[7]A.Hirano and Y.Miyamoto,Novel modulation formats in ultra-high-speed transmission systems and their applications,Optical Communications Conference 2004,2004,vol.2,pp.ThM2.
[8]A.Hirano and Y.Miyamoto,Novel modulation formats in ultra-high-speed transmission systems and their applications,Optical Communications Conference 2006,2006,vol.2,pp.OFD3.
[9]W.Xing,L.Xiang,and C.Xu,numerical simulation of the SPM penalty in a 10-Gb/s RZ-DPSK system,Photonics Technology letters,IEEE,2003,vol.15,pp 1636-1638.
[10]H.Keang Po and W.His-Cheng,Comparison of nonlinear phase noise and intrachannel four-wave mixing for RZ-DPSK signals in dispersive transmission systems,Photonics Technology letters,IEEE,2005,vol.17,pp.1426.
[11]D.van den Borne,V.Veljanovski,U.Gaubatz,C.Paquet,Y.Painchaud,E.Gottwald,G.D.Khole,and H.de waardt,42.8 Gb/s RZ-DQPSK Transmission with FBG-Based In-Line Dispersion Compensation,Photonics Technology letters,IEEE,2007,vol.19,pp.1069-1071.
[12]Y.Yano,T.Ono,K.Fukuchi,T.Ito,H.Yamazaki,M.Yamaguchi,and k.Emura,2.6 terabit/s WDM transmission experiment using optical duobinary coding,European Conference on Optical Communication,ECOC,1996.
[13]D.Penninckx,M.Chbat,L.Pierre,and J.P.Thiery,Phase-shaped binary transmission(PSBT):A new technique to transmit far beyond the chromatic dispersion limit,European Conference on Optical Communication,ECOC,1996.
[14]A.matsuura,k.Yonenaga,Y.Miyamoto,A.Sano,H.Toba,and M.Yoneyama,High power tolerant optical duobinary signal transmission,IEICE Transactions on Communications,2001,vol.,E85-B,pp.1173-1178.
[15]R.C.Lee,H.A.Abdul-Rashid,M.T.Al-Qdah,H.T.Chuah,M.B.Tayahi,and S.Lanka,The effects of phase errors on optical SSB system performance,Microwave and Optical Technology Letters,2006,vol.,48,pp.1574-1578.
[16]W.Jin and J.M.Kahn,Accurate bit-error-ratio computation in nonlinear CRZ-OOK and CRZ-DPSK systems,Photonics Technology letters,IEEE,2004,vol.16,pp.2165-2167.
[17]D.Penninckx,M.Chbat,L.Pierre,and J.P.Thiery,Phase-shaped binary transmission (PSBT):A new technique to transmit far beyond the chromatic dispersion limit,European Conference on Optical Communication,ECOC,1996.
[18]X.Wei,X.Liu,S.Chandrasekhar,A.H.Gnauck,G Raybon,J.Leuthold,and P.J.Winzer,40Gb/s Duobinary and modified Duobinary Transmitter based on an Optical Delay Interferometer,28th European Conference on Optical Communication,2002,vol.4,pp.1-4.
[19]A.Hirano and Y.Miyamoto,Novel modulation formats in ultra-high-speed transmission systems,and their applications,Optical Fiber Communications Conference 2006,2006,vol.2,pp.OFD3.
[20]Sebastien R.Blais and Jianping Yao,Optical Single Sideband Modulation Using an Ultranarrow Dual-Transmission-BandFiber Bragg Grating,Photonics Technology letters,IEEE,2006,vol.18,pp.2230-2232.
[21]L.Chen,H.Wen,and S.Wen,A Radio-Over-Fiber System With a Novel Scheme for Millimeter-Wave Generation and Wavelength Reuse for Up-Link Connection,Photonics Technology letters,IEEE,2006,vol.18,pp.2056-2058.
[22]Fei Zheng,Jianping Yao,An approach to ultrawideband pulse generation and distribution over optical fiber,Photonics Technology letters,IEEE,2006,vol.18,pp.823-825.
[23]J Yu,Z Jia,L Xu,L Chen,T Wang,G Chang,DWDM Optical Millimeter-Wave Generation for Radio-Over-Fiber Using an Optical Phase Modulator and an Optical Interleaver,Photonics Technology letters,IEEE,2006,vol.18,pp.913-925.
[24]S.N.Knudsen and L.Gruner-Nielsen,New fiber for future telecommunication systems,laser and Electro-Optics Society 2000 Annual meeting.LEOS 2000.13th Annual Meeting IEEE,2000.
[25]T.Tsuda,Y Akasaka,S.Sentsui,K.Aiso,Y Suzuki,and T.Kamiya,Broad band dispersion slope compensation of dispersion shifted fiber using negative slope fiber,Optical Communication,1998.24th European Conference on,1998.
[26]A.Hidayat,A.F.Abas,D.Sandel,S.Bhandare,H.Zhang,F.Wust,B.Milivoevic,R.Noe,M.Lapointe,YPainchaud,and M.Guy,5.94 tbit/s capacity of a FBG-based multichannel tunable-700 to-1200 ps/nm dispersion compensator,Journal of Optical Communications,2006,vol.,27,pp.17-19.
[27]D.Sandel,S.Bhandare,A.F.Abas,B.milivojevic,R.Noe,M.Guy,and M.Lapointe,Automatic tunable chromatic dispersion compensation at 40Gb/s in Ask and DPSK,NRZ,and CSRZ 263-km transmission experiments,Photonics Technology letters,IEEE,2004,vol.16,pp.2568-2570.
[28]L.Poladian,understanding profile-induced group-delay ripple in Bragg gratings,Applied Optics, 2000,vol.,39,pp.1920-1923.
[29]J.C.Cartledge and H.Chen,Influence of modulator chirp in assessing the performance implications of the group delay ripple of dispersion compensating fiber bragg gratings,Journal of Lightwave Technology,2003,vol.,21,pp.1621-1628.
[30]L.S.Yan,T.luo,Q.Yu,Y Xie,K.M.Feng,R.khosravani,and A.E.Willner,Investigation of performance variations due to the amplitude of group-delay ripple in chirped fiber Bragg gratings,Optical Fiber Technology,2006,vol.,12,pp.238-242.
[31]YH.C.Kwan and P.K.A.Wai,Effects of group delay ripple on solitons in grating compensated dispersion managed systems,Pacific Rim Conference on Lasers and Electro-Optics,CLEO-Technical Digest,2001.
[32]Z.Lin,C.Minghua,Z.Yejin,and X.Shizhong,Impacts of cascaded filters with group delay ripple on 40Gb/s WDM transmission sytem,Photonics Technology Letters,2002,vol.14,pp.1518-1520.
[33]G.H.Smith,D.Novak,and Z.Ahmed,Overcoming chromatic-dispersion effects in fiber-wireless systems incorporating external modulators,Transation.Microwave Theory Technology,IEEE,1997,vol.45,pp.1410-1415.
[34]Takano K.,Hanzawa N.,Tanji S.,Nakagawa K.,Experimental Demonstration of Optically Phase-Shifted SSB Modulation with Fiber-Based Optical Hilbert Transformers,Optical Fiber Communications Conference 2007,2007,pp.1-3.
[35]Y Shen,X.Zhang,and K.Chen,Optical single sideband modulation of 11-GHz RoF system using stimulated Brillouin scattering,Photonics.Technology.Letter,IEEE,2005,vol.17,pp.1277-1279.
[36]Kitayama K.,Kuri T.,Onohara K.,Kamisaka T.,Murashima K.,Dispersion effects of FBG filter and optical SSB filtering in DWDM millimeter-wave fiber-radio systems,Journal of Lightwave Technology,IEEE,2002,vol.20,pp.1397-1407
[37]Capmany J.,Pastor D.,Munoz P.,Ortega B.,Sales S.,Martinez A.,Multiwavelength optical SSB generation for dispersion mitigation in WDM fibre radio systems using AWG multiplexer,Electronics Letters,IEEE,2002,vol.38,pp.1194-1196.
[38]Fei Zheng,Jianping Yao,Optical Single Sideband Modulation Using an Ultranarrow Dual-Transmission-Band Fiber Bragg Grating,Photonics Technology letters,IEEE,2006,vol.18,pp.2230-2232.
[39]C.Marra,A.Nirmalathas,D.Novak,C.Lim,L Reekie,The impact of grating dispersion on transmission performance in a millimeter-wave fiber-radio system,Photonics Technology Letters,IEEE,2002,vol.14,pp.1345-1347.
[40]Z.Xiang,H.H.M.Shalaby,C.Lu,T.H.Cheng,and Y.Peida,A performance analysis of all optical clock extraction circuit based on stimulated Brillouin scattering,Journal of Lightwave Technology,2000,vol.18,pp.1453-1466.
[41]Takano K.,Hanzawa N.,Tanji S.,Nakagawa K.,Experimental Demonstration of Optically Phase-Shifted SSB Modulation with Fiber-Based Optical Hilbert Transformers,Optical Fiber Communication and the National Fiber Optic Engineers Conference,2007.
[42]顾畹仪,WDM超长距离光传输技术。北京:北京邮电大学出版社,2005.
[43]C.Henry,Phase noise in semiconductor lasers,Journal of Lightwave Technology,1986,vol.4, pp.298-311.
[44]G.P.Agrawal,非线性光纤光学原理及应用.北京:电子工业出版社,2002.
[45]R.W.Tkach,A.R.Chraplyvy,F.Forghieri,A.H.Gnauck,and R.M.Derosier,Four-photon mixing and high-speed WDM systems,Journal of Lightwave Technology,1995,vol.13,pp.841-849.
[46]G.keiser著;李玉权等译,光纤通信(第三版).北京:电子工业出版社,2002.
[47]余建军,管克俭,杨伯君,10Gbit/s单通道长距离光通信系统的数值模拟,光通信研究,1999,vol.,91,pp.5-12.
[48]M.Brain and L.Tien-pei,Optical receivers for lightwave communication systems,ElectronDevices,IEEE transactions on,1985,vol.32,pp.2673-2692.
[49]R.I.Laming,P.R.Morkel,D.N.Payne,and L.Reekie,Noise in erbium-doped fiber amplifers,Fourteenth European Conference on Optical Communication,1988,vol.1,pp.54-57.
[50]"The ITU Telecommunication Standardization G.957," http://www.itu.int/ITU-T/.
[51]C.J.Anderson and J.A.Lyle,Technique for evaluating system performance using Q in numerical simulations exhibiting intersymbol interference,Electronics Letters,1994,vol.30,pp.71-72.
[52]I.Eugenio,F.Matera,A.Mecozzi,and M.Settembre,Nonlinear Optical Communication Networks:John Wiley,1998.
[53]R Li,J.Shuisheng,Y.Fengping,N.Tigang,and W.Zhi,Long-haul WDM system through conventional single mode optical fiber with dispersion compensation by chirped fiber Bragg grating,2003,vol.222,pp.169-178.
[54]裴丽,宁提纲,李唐军,董小伟,简水生,高速光通信系统中光纤光栅色散补偿研究,物理学报,2005,vol.54,pp.1630-1635.
[55]谭中伟,郑凯,刘艳,傅永军,陈勇,曹继红,宁提纲,董小伟,马丽娜,简水生,基于啁啾光纤光栅的色散补偿器在超长距离密集波分复用系统中的应用,物理学报,2005,vol.54,pp.5218-5223.
[56]K.Hinton and J.Arkwright,Impact of grating delay and reflectivity tipple in optical systems,Conference Record/IEEE Global Telecommunications Confernece,1998,vol.,2,pp.986-991.
[57]M.Sumetsy,B.Eggleton,C.de sterke.Theory of group delay ripple generated by chirped fiber gratings,Optics Express,2002,vol.10,pp.332-340.
[1]吴重阳,光纤光缆技术大展望 江苏亨通光电股份有限公司http://www.gglchina.com/lianjie/guangqian/coverread.asp?cover_id=31Kuznetsov.
[2]M.Daikoku,et al.,"100Gbit/s DQPSK Transmission Experiment without OTDM for 100G Ethernet Transport",Proc.OFC 2006,PDP36.
[3]Toshihiko Hirooka,Masatada Okazaki,Kou Osawa,and Masataka Nakazawa,160 Gbit/s-900km DPSK Transmission with Time-domain Optical Fourier Transformation,ECOC'2007, Session 1.3-High Speed Transmission
[4]J.J.Vegas Olmos,J.P.Turkiewicz,M.Garcia Larrode,I.Tafur Monroy,and A.M.J.Koonen,FSK-WDM to IM-OTDM conversion for fiber-to-thepremises access networks,OFC2006,Session,OFE6.
[5]刘涛,赵尚弘,谢小平,夏贵进,占生宝,OTDM实用化关键技术分析,电讯技术,2002年,vol.4,pp.28-31
[6]赵永鹏;Baker L;Khoe G D;deWaardt H;A 160 Gbit/s OTDM Demonstrator for LOFAR Networks,光子学报,2007,vol.1,pp.23-26.
[7]M.Shirane,Y.Hashimoto,H.Yamada,A compact optical sampling measurement system using mode2locked laser2 diode modules,IEEE Photon.Technol.Lett.,2000,vol.12,pp.1537-1539.
[8]彭璨,姚敏玉,张洪明,徐千帆,张剑锋,高以智,10 GHz Actively Mode-locked Fiber Ring Laser,中国激光,2003,vol.2,pp.17-19.
[9]Ivan Kaminow厉鼎毅主编 余力等译《光纤通信》中文版北京:北京邮电大学出版社,2006.
[10]Chien-Chung Lee,Yung-Kuang Chen,and Shien-Kuei Liaw,Single-longitudinal-mode fiber laser with a passive multiple-ring cavity and its application for video transmission,Optics Letters,Vol.23,pp.358-360.
[11]Xinhuan Feng,Yange Liu,Shenggui Fu,Shuzhong Yuan,Xiaoyi Dong,Switchable dual-wavelength ytterbium-doped fiber laser based on a few-mode fiber grating,Photonics Technology Letters,IEEE,2004,vol.16,pp.762-764.
[12]Dae Seung Moon,Un-Chul Paek,and Youngjoo Chung,Multi-wavelength lasing oscillations in an erbium-doped fiber laser using few-mode fiber Bragg grating,Optics Express,2004,Vol.12,pp.6147-6152.
[13]Yamamoto T.,Yoshida E.,Tamura K.R.,Yonenaga K.,Nakazawa M.,640-Gbit/s optical TDM transmission over 92 km through adispersion-managed fiber consisting of single-mode fiber and reverse dispersion fiber,Photonics Technology Letters,IEEE,2000,vol.12,pp.353-355
[14]Alistair J.Poustie,Neil Finlayson,and Paul Harper,Multiwavelength fiber laser using a spatial mode beating filter,Optics Letters,1994,Vol.19,pp.716-718
[15]S.V.Chernikov,Y.Zhu,J.R.Taylor,and V.P.Gapontsev,Supercontinuum self-Q-switched ytterbium fiber laser,Optics Letters,1997,Vol.22,pp.298-300.
[16]Brian R.Washburn,Scott A.Diddams,Nathan R.Newbury,Jeffrey W.Nicholson,Man F.Yan,and Carsten G.Jrgensen,Phase-locked,erbium-fiber-laser-based frequency comb in the near infrared,Optics Letters,2004,Vol.29,pp.250-252.
[17]李唐军,160Gb/s光时分复用系统关键技术的研究.北京交通大学博士论文,2008
[18]C.Boerner,,et al.,160 Gb/s Clock Recovery and Demultiplexing Using One Single EAM,ECOC 2003,Th2.5.1
[19]尹丽娜 曹灼等,非等幅OTDM信号的全光时钟提取,光子学报,2005,vol.34,pp.1-4.
[20]W.Tong,L.Caiyun,H.Li,A.Z.W.Zhaoxin Wang,and A.Y.G.YizhiGao,Combination of comb-like filter and SOA for preprocessing to reduce the pattern effect in the clock recovery,Photonics Technology Letters,IEEE,2004,vol.1,pp.614-616.
[21]D.M.Patrick and R.J.Manning,20 Gbit/s all-optical clock recovery using semiconductor nonlinearity,Electronics Letters,1994,vol.30,pp.151-152.
[22]K.Vlachos,G.Theophilopoulos,A.Hatziefremidis,and H.A.A.H.Avramopoulos,30Gb/s all-optical clock recovery circuit,Photonics Technology Letters,IEEE,2000,vol.12, pp.705-707.
[23]战莹,邵钟浩,OTDM中时钟提取技术的发展及前景,现代传输,2006,vol.31,pp.1-4.
[24]王安斌,伍剑,拱伟,林金桐,基于LiNbO3调制器的高速时钟信号的提取,半导体光电,2003,vol.5
[25]A.D.Ellis,K.Smith,and D.M.Patrick,All optical clock recovery at bit rates up to 40Gbit/s,Electronics Letters,1993,vol.29,pp.1323-1324.
[26]L.Yuhua,K.Cheolhwan,L.Guifang,Y.Kaneko,R.L.Jungerman,and O.Buccafusca,Wavelength and polarization insensitive all-optical recovery from 96-Gb/s data by using a two-section gain-coupled DFB laser,Photonics Technology Letters,IEEE,2003,vol.15,pp.590-592.
[27]D.H.Kim,S.H.Kim,J.C.Jo,and S.S.Choi,Ultrahigh speed clock recovery with optical phase lock loop based on four-wave-mixing in a semiconductor optical amplifer,Optics Communications,2000,vol.182,pp:329-334.
[28]D.L.Butler,J.S.Wey,M.W.Chbat,G.L.Burdge,and J.Goldhar,Optical recovery from a data stream of an arbitrary bit rate by use of stimulated Brillouin scattering,Optics letters,1995,vol.20,pp.560-562.
[29]王安斌,伍剑,林金桐,基于电吸收调制器的高速时钟信号的提取,2003,光子学报,vol.32,pp.1-7
[30]Seung-Woo Seo,Bergman K.,Prucnal P.R.,Transparent optical networks with time-division multiplexing,Selected Areas in Communications,IEEE Journal on,1996,vol.14,pp.1039-1051.
[31]Klaus Grobe,et al.,Assessment of 40Gb/s Techniques for Metro/Regional Applications,OFC'2006,NThA1.
[32]M.J.Ablowitz,T.Hirooka,Interchannel pulse interactions in dispersion-managed transmission systems:Timing shifts,Optics letters,2001,vol.26,pp.1846-1848.
[33]王目光,光纤偏振特性及其测量与补偿技术的研究.北京交通大学博士论文,2004.
[34]解奕鹏,光纤激光器的发展现状,世界宽带网络,2004,vol.11,pp.12-15.
[35]G.P.Agrawal,非线性光纤光学原理及应用.北京:电子工业出版社,2002.
[36]C.X.Yu,H.A.Haus,E.P.Ippen,W.S.Wong,and A.Sysoliatin,Gigahertz-repetition-rate mode-locked fiber laser for continuum generation,Optics Letters,2000,vol.25,1418-1420.
[37]王林,利用拍频反馈控制调制频率实现再生锁模的光纤激光器,半导体光电,2002,vol.23,pp.5-7
[38]Yin lina,Cao Zhuo,Liu Guoming,Wu Jian,Lin Jintong,All optical recovery from unequal amplitude multiplexed OTDM signals,ACTA PHOTONICA SINICA,2005,vol.34,pp.1-4.
[39]戴居丰,于普龙,马晓红,从非均匀分布的信号脉冲中提取基频时钟脉冲,中国激光,2001,A28,pp.67-70
[40]C.Johnson,K.Demarest,C.Allen,R.Hui,K.V.Peddanarapagari,B.Zhu,and R.K.Butler,Multiwavelength all-optical clock recovery,Conference Proceedings-lasers and Electro-Optics Society Annual Metting-LEOS,1998.
[41]左鹏,伍剑,张帆,林金桐,4×10Gbit/s OTDM系统中10GHz帧时钟提取技术,电子学报,2002,vol.30,pp.1-3.
[42]T.Wang,C.Lou,L.Huo,Z.Wang,andY.Gao,Combination of Comb-LikeFilter and SOA for Preprocessing to Reduce the Patten Effect in the Clock Recovery,Photonics Technology Letters,IEEE,2004,vol.16,PP.614-616.
[43]http://www.cip.com/
[44]Feng Xu,Jiansheng Liu,Ruxin Li,and Zhizhan Xu,Pulse compression and supercontinuum at different powers of femtosecond pulses in water,Chinese Optics Letters,2007,vol.5,pp.490-492.
[45]S.W.Chan,K.K.Chow,C.Shu,Nonlinear Pulse Compression and Reshaping Using Cross-Phase Modulation in a Dispersion-Shifted Fiber,ACTA OPTICA SINICA,2003,vol.23,pp.1-2.
[46]S.V.Chernikov,E.M.Dianov,D.J.Richardson and D.N.Payne,Soliton pulse compression in dispersion-decreasing fiber,Optics Letters,1993,vol.18,pp.476-479.
[47]K.Shiraki.M.Ohashi and M.Tateda,Suppression of stimulated Brillouin scattering in a fibre by changing the core radius,Electronics Letters,1995,vol.31,pp.668.
[48]K.Shiraki,M.Ohashi,and M.Tateda,SBS Threshold of a Fiber with a brillouin Frequency Shift Distribution,Journal of Lightwave Technology,1996,vol.14,pp.50-53.
[49]N.Yoshizawa,and T.Imai,Stimulated Brillouin Scattering Suppression by Means of Applying Strain Distribution to Fiber with Cabling,Journal of Lightwave Technology,1993,vol.11,pp.1518-1520.
[50]Y.Imai,and N.Shimada,Dependence of Stimulated Brillouin Scattering on Temperature Distribution in Polarization-Maintaining Fibers,Photonics Technology Letters,vol.5,1993,pp.1335-1146.
[51]N.A.Olsson,and J.P.Van Der Ziel,Characteristics of a Semiconductor Laser Pumped Brillouin Amplifier with Electronically Controlled Bandwidthjournal of Lightwave Technology,1987,vol.3,pp.147-151.
[52]Y.Aoki,K.Tajima,and I.Mito,Input Power Limits of Single-Mode Optical Fibers due to Stimulated Brillouin Scattering in Optical Communication Systems,Journal Lightwave Technology,1988,vol.6,pp.710-715
[1]T.G.Ning,L.Pei,Y.Liu,Z.W.Tan,Z.Tong,F.P.Yan an S.S.Jian,Optimization of electron-beam-written step-chirped phase masks to improve quality of the chirped FBG,Guangdianzi Jiguang/Journal of Optoelectronics Laser,2006,vol.17,pp.1409-1412.
[2]Z.W.Tan,B.Li,Y.H.Wang,W.H.Ren,Y.Liu,T.G.Ning,and S.S.Jian,Background loss of the fiber induced by the ultraviolet light exposure,Zhongguo Jiguang/Chinese Journal of Laser,2007,vol.34,pp.239-242.
[3]Y.Liu,B.Li,K.Zheng,Z.W.Tan,Y.Chen,Y.H.Wang,W.H.Ren,and S.S.Jian,Temperature or strain induced adjustable-chirped characteristics of uniform fibre grating with tapered coating,Chinese physics,2007,vol.16,pp.1694-1699.
[4]Z.W.Tan,T.G.Ning,Y.Liu,Z.Tong,and S.S.Jian,Suppression of the interactions between fiber gratings used as dispersion compensators in dense wavelength-division multiplexing systems,Chinese physics,2006,vol.15,pp.1819-1823.
[5]刘玉敏,俞重远,张建忠,粒子群优化算法用于光纤布拉格光栅综合问题的研究闭,激光杂志,2005,26(4):69-70.
[6]文晓燕,余谦,基于差分演化算法的啁啾光纤光栅参数重构方法,仪器仪表学报,2008,vol.29,pp.2216-2219.
[7]张荣祥,郑世杰,夏彦君,张绥远,支持向量回归算法在光纤光栅非均匀应变重构中的应用,光学学报,2008,vol.28,pp.1513-1517.
[8]WinickK.A,Roman J.E,Design of corrugated waveguide filters fourier transform techniques,IEEE J.Quantum Electron.,1990,vol.2,pp.1918-1929.
[9]Peral E,Capmany J,Marti J,Iterative solution to the Gelfan-Levitan-Marchenko coupled equations and application to synthesis of fiber gratings,IEEE J.Quantum Electron.,1996,vol.32,pp.2078-2084.
[10]Muriel M.A.,Azana J.,Carballar A.,Fiber grating synthesis by use of time frequency representation,Optics Letters,1998,vol.23,pp.1526-1528.
[11]Azana J.,Muriel M.A.,Chen LFiber Bragg Grating period reconstruction using time-frequency signal analysis and application to distributed sensing,IEEE/OSA Journal of Lightwave Technology,2001,vol.19,pp.646-654.
[12]Feced R,Zervas M.N.,Muriel M.A.,An efficient inverse scattering algorithm for the design of nonuniform fiber Bragg gratings,Journal of Quantum E lectronics,IEEE,1999,vol.35,pp.l 105-1115
[13]T.Erdogan.Fiber Grating Spectra,IEEE Journal of Lightwave Technology,1997,vol.15,pp.1277-1294.
[14]SKAAR Johannes,LIGANG WANQERDOGAN Turan,On the synthesis of fiber Bragg gratings by layer peeling,Journal of quantum electronics,IEEE,2001,vol.37,pp.165-173
[15]Jian Shuisheng,Zhao Yucheng,Wei Daoping,Dispersion compensation experimental on 19ps pulse width over 133km single mode fiber with tunable chirp and wavelength gratings,Science in China,1999,vol.42,pp.165-170.
[16]L.Xiang,W.Xing,A.H.Gnauck et al..Analysis of loss ripple and its application to the mitigation of optical filtering penalty,IEEE Photonics Technology Letters,2005,vol.17,pp.82-84.
[17]Z.Lin,C.Minghua,Z.Yejin et al..Impacts of cascaded filters with group delay ripples on 40Gb/s WDM transmission system,IEEE Photonics Technology Letters,2002,voU4,pp.1518-1520
[18]J.A.Dobrowolski,D.Lowe.Optical thin film synthesis program based on the use of Fourier transforms,Applied Optics,1978,vol.17,pp.3039-3050
[19]E.Peral,J.Capmany,J.Marti.Design of fiber grating dispersion compensators using a novel iterative solution to the Gel'fan-Levitan-Marchenko coupled equations,Electronics Letter.,1996,vol.32,pp.918-919
[20]R.Feced,M.N.Zervas,M.A.Muriel.An efficient Inverse scattering algorithm for the design of nonuniform fiber Bragg gratings,IEEE Journal of Quantum Electronics,1999,vol.35,pp.l 105-1115
[21]J.Skaar,K.M.Risvik.A genetic algorithm for the inverse problem in synthesis of fiber gratings,Journal of Lightwave Technology,1998,vol.16,pp.1928-1932
[22]Mu Kejun,Zhou Xiaojun,Ren Guorong,Reconstruction of Parameters of Fiber Gratings from Time-Delay,Chinese J.Lasers,2007,vol.34,pp.688-693
[23]Guan Baiou,Yu Youlong,Ge Chunfeng,Theoretical studies on transmission charicteristics of fiber grating Fabry-perot cavity,Acta Optica Sinica,2000,vol.20,pp.34-38
[24]Jin Xiaofeng,Zhang ZhongXian,Non-uniform optical fiber grating response,Acta Optica Sinica,1999,vol.19,pp.721-727
[25]Xie zenghua,Ning Tigang,Pei Li,et al.Fabrication of 13 cm linearly chirped fiber grating,Acta Optica Sinica,2001,vol.21,pp.13 81-13 83
[26]T.Erdogan.Fiber Grating Spectra.IEEE Journal of Lightwave Technology,1997,vol.15,pp.1277-1294.
[27]D.Paster,J.Capmany,D.Ortega et al.,Design of apodized linearly chirped fiber gratings for dispersion compensation,Journal of Lightwave Technology.1996,vol.14,pp.2581-2588.
[28]Liu Yan,Zheng Kai,Tan Zhongwei et al,Good performance of chirped fiber Bragg gratings obtained by asymmetrically one-side exposure apodization,Acta Physica Sinica,2006,vol.55,pp.5859-5865
[29]M.Sumetsy,B.Eggleton,C.de sterke.Theory of group delay ripple generated by chirped fiber gratings,Optics Express,2002,vol.10,pp.332-340.
[30]Tan Zhongwei,Liu Yan,Ning Tigang,Jian Shuisheng,The generation of group delay ripple of chirped fiber gratings,Chinese Optics Letter,2004,vol.2,pp.18-20.
[31]Ning Tigang,Liu Yan,Tan Zhongwei,Jian Shuisheng,Impact on dispersion compensated system using chirped fiber Bragg grating with delay ripple,Acta Optica Sinica,2003,vol.23,pp.1064-1067
[32]Pei Li,Jian Shuisheng,Xie zenghua,Dispersion compensation optical fiber grating with low ripple coefficient,Acta Optica Sinica,2002,vol.22,pp.336-339
[33]张峰,40Gb/s 长距离传输及信号处理关键技术的研究,北京交通大学博士论文,2008.
[1]简水生,数字信息安全网是人类进一步改变生活方式,工作方式,学习方式的根本保证,数字通信世界,2005,vol.1,pp10-10.
[2]简水生,“光纤网的发展与机遇”,中国电子商情:通信市场,no.11,2001,pp.13-18.
[3]简水生,新一代、高度安全、超大容量、无阻塞全光网是信息社会的基础,光通信,2003,vol.12,pp.14-21.
[4]"GENI:global environment for network innovations," http://www.geni.net/
[5]"FIND:future Internet network design," http://find.isi.edu/
[6]Feng Zhang,Yong Chen,Jihong Cao,Xi Qin,Shuisheng Jian.Novel Optical Fiber Self-healing Network Based on Wavelength Routing of Fiber Gratings.APOC2006.
[7]C.Ming,Z.Feng,Q.Xi,C.Yong,C.Jihong,L.Bo,,L.Dan,and J.Shuisheng,The implementation of multicast in wavelength routing optical network based on chirped fiber gratings,Journal of Optoelectronics.laser,2008,vol.19,pp.331-334.
[8]Bo Lv,Xiangqiao Mao,Feng Zhang,Optimization of multicast optical networks with genetic algorithm,APOC2007,2007.
[9]卢丹,曹继红,秦曦,张峰,吕博,陈明,简水生,支持全光组播OXC的研究与实现,光通信技术,2007,vol.31,pp.41-44.
[10]陈勇,全光通信网关键技术的研究与实现,博士学位论文.北京:北京交通大学,2006.
[11]“关于下一代网络体系结构”,http://sj.media.edu.cn/
[12]Chen Yong,Chen Genxiang,Cao Jihong,Jian Shuisheng,Novel wavelength-routing All-Fiber WDMNetwork:Implementation and Optimization,Proceedings of SPIE,2004,vol.5626,pp.1382-1389.
[13]张峰,陈勇,曹继红,秦曦,简水生.一种基于光纤光栅实现波长路由的光纤自愈网,光学技术,2007,vol.33,pp.173-176.
[14]曹继红,高速超长距离传输系统及新型光路交换网的研究,博士学位论文.北京:北京交通大学,2007.
[15]简水生,建立“新一代、高度安全、超大容量、无阻塞全光网”是我国本世纪初叶重大科学战略工程,网络电信,2003,no.11,pp.16-21.
[16]Liu Yan,Chen Yong,Tan Zhongwei,Cao Jihong,Zheng Kai,Ning Tigang,Chen Ting,Dong Xiaowei,Jian Shuisheng,Performance of a 10Gbit/s Transmission system over 1500km G.652Fiber Compensated by Cascaded narrow-Band Chirped Fiber Bragg Gratings,Chinese Physics Letters,2005,vol.22,pp.1944-1947.
[17]曹继红,陈勇,简水生,基于线性啁啾光纤光栅色散补偿的2500km 10Gb/s无电中继传输系统,光电工程,2006,vol.33,pp.101-105.
[18]张杰等,自动交换光网络ASON.北京:人民邮电出版社,2004.
[19]颀畹仪等编,光传送网.北京:机械工业出版社,2003.
[20]Feng Zhang,Yong Chen,Jihong Cao,Xi Qin,Shuisheng Jian.Novel Optical Fiber Self-healing Network Based on Wavelength Routing of Fiber Gratings.APOC2006.
[21]龚倩,光网络的组网与优化设计.北京:北京邮电大学出版社,2002.
[22]简水生,通信由电到光的革命兼论绿色能源革命(节选),光通信,2006,vol.12,pp.22-24.
[23]T.H.Noh,End-to-end self-healing SDH/ATM networks,Global Telecommunications Conference 1996,vol.4,pp.1877-1881.
[24]W.Xing,L.Xiang,and C.Xu,numerical simulation of the SPM penalty in a 10-Gb/s RZ-DPSK system,Photonics Technology letters,IEEE,2003,vol.15,pp 1636-1638.
[25]H.Keang Po and W.His-Cheng,Comparison of nonlinear phase noise and intrachannel four-wave mixing for RZ-DPSK signals in dispersive transmission systems,Photonics Technology letters,IEEE,2005,vol.17,pp.1426.
[26]D.van den Borne,V.Veljanovski,U.Gaubatz,C.Paquet,Y.Painchaud,E.Gottwald,G.D.Khole,and H.de waardt,42.8 Gb/s RZ-DQPSK Transmission with FBG-Based In-Line Dispersion Compensation,Photonics Technology letters,IEEE,2007,vol.19,pp.1069-1071.
[27]Y.Yano,T.Ono,K.Fukuchi,T.Ito,H.Yamazaki,M.Yamaguchi,and k.Emura,2.6 terabit/s WDM transmission experiment using optical duobinary coding,European Conference on Optical Communication,ECOC,1996.
[28]D.Penninckx,M.Chbat,L.Pierre,and J.P.Thiery,Phase-shaped binary transmission(PSBT):A new technique to transmit far beyond the chromatic dispersion limit,European Conference on Optical Communication,ECOC,1996.
[29]A.matsuura,k.Yonenaga,Y.Miyamoto,A.Sano,H.Toba,and M.Yoneyama,High power tolerant optical duobinary signal transmission,IEICE Transactions on Communications,2001,vol.,E85-B,pp.1173-1178.
[30]张铭等,OPNET Modeler与网络仿真.北京:人民邮电出版社,2007.
[31]F.Tillerot,E.Didelet,A.Daviaud,and G.Claveau,Efficient network upgrade based on a WDM optical layer with automatic protection switching,Optical Fiber Communications Conference,1998,pp.296-297.
[32]黄照祥,黄永清,张阳安,李玲,任晓敏,智能光网络中的光通道性能监测技术及其应用,现代有线传输,2005,no.1,pp.59-62.
[33]Frigo N.J.,Iannone P.P.,Reichmann K.C.,Xiang Zhou,Stodden,M.W.,Centralized In-Service OTDR Testing in a CWDM Business Access Network,Journal of Lightwave Technology,,IEEE,2004,vol.22,pp.2641-2652.
[34]Tsong-Ho Wu,Emerging technologies for fiber network survivability,Communication Magazine,1995,vol.33,pp.62-74.
[35]Luby J.F,Survivability of the public switched network integration of market,switching,transmission and OA&M considerations in network design,Switching Sympsion.1990,vol.4,pp.169-172.
[36]Satoru Okumato,Photonic Transport Network Architectureand OA&M Technologies to Create Large-Scale Robust Networks,Journal of Selected Areas Communication,IEEE,1998,vol.16,pp.995-1007.
[37]Singhal N.K,Sahasrabuddhe L.H.,Mukherje B,Optimal Multicasting of Multiple Light-Trees of Different Bandwidth Granularities in a WDM Mesh Network With Sparse Splitting Capabilities,IEEE/ACM Transcation Network,2006,vol.14,pp.1104-1117.
[2]http://www.level3.com/
[3]简水生,因特网从空前繁荣到“效率时代”的启示和展望,现代通信 2002,1期,pp.1-4
[4]光通信发展的回顺与展望,http://www.cnii.com.cn/
[5]C.Baack and G.walf,Photonics in future telecommunications,Proceedings of the IEEE,1993,vol.81,pp.1624-1632.
[6]李从奇,陈娟,全光网的发展趋势及其挑战,电信网技术,2006,pp.13-16.
[7]S.C.Chan,L.Minghua,S.S.Udpa,L.Udpa,and D.W.Jacobson,All-optical dense WDM wide-area communication network,IEEE 39th Midwest symposium on circuits and Systems,1996,vol.3,pp.1157-1160.
[8]I.P.Kaminow,C.R.Doerr,C.Dragne,T.Koch,U.Koren,A.A.M.Saleh,A.J.Kirby,C.M.Ozveren,B.Schofield,R.E.Thomas,R.A.Barry,D.M.Castagnozzi,V.W.S.Chan,B.R.Hemenway,Jr.,D.Marquis,S.A.Parikh,M.L.Stevens,E.A.Swanson,S.G.Finn,and R.G.Gallager,A wideband all-optical WDM network,selected Areas in Communications,IEEE Journal on,1996,vol.14,pp.780-799.
[9]吴重阳,光纤光缆技术大展望 江苏亨通光电股份有限公司http://www.gglchina.com/lianjie/guangqian/coverread.asp?cover_id=31/
[10]T.N.Nielsen,A.J.Stentz,K.Rottwitt,D.S.Vengsarkar,Z.J.Chen,3.28 Tb/s(82×40 Gb/s)transmission over 3×100km nonzero-dispersion fiber using dual C- and L-band hybrid Raman/erbium doped inline amplifers,Optical Fiber Communications Conference 2000,2000,vol.4,pp.236-238.
[11]L.D.Garrett,A.H.Gnauck,EForghieri,V.Gusmeroil,and D.Scarano,16×10Gb/s WDM transmission over 840-km SMF using eleven broad-band chirped fiber gratings,photonics Technology Letters,IEEE,1999,voh 11,pp.484-486
[12]AkiraHirano,应用在超高速光传输系统里的新兴调制方式,网络电信,2005,no.1,pp.52-54.
[13]D.Sandel,S.Bhandare,A.F.Abas,B.milivojevic,R.Noe,M.Guy,and M.Lapointe,Automatic tunable chromatic dispersion compensation at 40Gb/s in Ask and DPSK,NRZ,and CSRZ 263-km transmission experiments,Photonics Technology letters,IEEE,2004,voh 16,pp.2568-2570.
[14]顾畹仪,WDM超长距离光传输技术。北京:北京邮电大学出版社,2005.
[15]C.Yong,C.Jihong,C.Ting,and J.Shuisheng,Advanced modulation formats for long-haul optical-transmission systems with dispersion compensation by chirped FBG,Microwave and Optical Technology Letters,2006,vol.48,pp.344.
[16]C.Fuerst,G.Mohs,H.Geiger,and G.Fischer,Performance limts of nonlinear RZ and NRZ coded transmission at 10 and 40 Gb/s on different fibers,Optical Fiber Communications Conference 2000,2000,vol.2,pp.302-304.
[17]霍晓莉,超长距离传输系统应选择成熟技术,北京电子,2006,vol.3,pp.24-24.
[18]DavidZ.Chen,Glenn Wellbrock,Steve J.Penticost,Dilip Patel,Christian Rasmussen,Mark C. Childers,X.Yang,and M.Y.Frankel,World's first 40Gbps overy on a field-deployed,10 Gbps,mixed-fiber,1200km,Ultra long-haul system,Optical Fiber Communication Conference 2005,2005,pp.OTuH4.
[19]D.F.Grosz,A.Agarwal,S.Banerjee,D.N.Maywar,and A.P.Kung,All-Raman ultralong-haul single-wideband DWDM transmission systems with OADM capability,lightwave Technology,Journal of,2004,vol.22,pp.423-432.
[20]G.C.Gupta,L.L.Wang,O.Mizuhara,R.E.Tench,N.N.Dang,P.Tabaddor,and A.Judy,3.2 Tb/s transmission with spectral efficiency of 0.8 b/s/Hz over 21/spl times/ 100km of dispersion-managed high local dispersion fiber using all-Raman amplified spas,Photonics Technology Letters,IEEE,2003,vol.15,pp.996-998.
[21]Xiang Zhou,Jianjun Yu,Mei Du,and Guodong Zhang,2Tb/s (20x107 Gb/s)RZ-DQPSK straight-line transmission over 1005 km of standard single mode fiber (SSMF)without Raman amplification,OFC2008,2008,OMQ3.
[22]C.Rasmussen,T.Fjelde,J.Bennike,F.A.L.F.Liu,S.A.D.S.Dey,B.Mikkelsen,P.Mamyshev,P.Serbe,P.Van der Wagt,YAkasaka,D.Harris,D.Gapontsev,V.Ivshin,and P.Reeves-Hall,DWDM 40G transmission over trans-Pacific distance(10,000km)casing CSRZ-DPSK,enhanced FEC nad all-Raman amplified 100km UltraWave/spl trade/ fiber spans,Optical Fiber Communiactions Conference 2003,2003,OFC2003.
[23]R.C.Lee,H.A.Abdul-Rashid,M.T.Al-Qdah,H.T.Chuah,M.B.Tayahi,and S.Lanka,The effects of phase errors on optical SSB system performance,Microwave and Optical Technology Letters,200,vol.48,pp.1574-1578.
[24]Y.Yamada,S.I.Nakagawa,Y.Kurosawa,T.Kawazawa,H.Taga,and K.Goto,2Tbit/s(200*10 Gbit/s)over 9240 km transmission experiment with 0.15 nm channel spacing using VSB format,Electronics Letters,2002,vol.38,pp.328-330.
[25]Toshihito Fujiwara,Koji Kikushima,140 Carrier,20GHz SCM Signal Transmission across 200km SMF by Two-step Sideband Suppression Scheme in Optical SSB Modulation,Optical Fiber Communiactions Conference 2007,2007,OME2.
[26]Nobuhiko Kikuchi,Kohei Mandai and Shinya Sasaki,Experimental Demonstration of Incoherent Optical Multilevel Staggered-APSK (Amplitude-and Phase-Shift Keying)Signaling,Optical Fiber Communiactions Conference 2008,2008,OMI3.
[27]Chun-Ting Lin,Sheng-Peng Dai,Wen-Jr Jiang,Jason Chen,Yu-Min Lin,Po Tsung Shih,Peng-Chun Peng,and Sien Chi,Experimental Demonstration of Optical Colorless Direct-Detection OFDM Signals with 16-and 64-QAM Formats beyond 15 Gb/s,2008,MO3El.
[28]Greg Raybon and Peter J.Winzer,100 Gb/s Challenges and Solutions,Optical Fiber Communiactions Conference 2008,2008,OTuGl.
[29]甘朝钦,高速传送:40Gbps至100Gbps,通信世界,2007,vol.6,pp.83-84.
[30]D.Z.Chen,TJ.Xia,G.Wellbrock,P.Mamyshev,S.Penticost,GGrosso,A.Puc,P.Perrier,and H.Fevrier,New Field Trial Distance Record of 3040 km on Wide Reach WDM With 10 and 40 Gb/s Transmission including OC-768 Traffic without Regeneration,Lightwave Technology,Journal of,2007,vol.25,pp.28-37.
[31]S.N.knudsen and L.Gruner-Nielsen,New fibers for future telecommunication systems,lasers and Electro-Optics Society 2000 Annual Meeting.LEOS 2000.13th Annual Meeting.IEEE, 2000.
[32]T.Tsuda,Y.Akasaka,S.Sentsui,K.Aiso,Y.Suzuki,and T.Kamiya,Broad band dispersion slope compensation of dispersion shifted fiber using negative sloe fiber,Optical Communication,1998.24th European Conference on,1998.
[33]Liu Yan,Zheng Kai,Tan Zhongwei et al,Good performance of chirped fiber Bragg gratings obtained by asymmetrically one-side exposure apodization,Acta Physica Sinica,2006,vol.55,pp.5859-5865.
[34]Tan Zhongwei,Liu Yan,Ning Tigang,Jian Shuisheng,The generation of group delay ripple of chirped fiber gratings,Chinese Optics Letter,2004,vol.2,pp.18-20.
[35]Ning Tigang,Liu Yan,Tan Zhongwei,Jian Shuisheng,Impact on dispersion compensated system using chirped fiber Bragg grating with delay ripple,Acta Optica Sinica,2003,vol.23,pp.1064-1067
[36]Pei Li,Jian Shuisheng,Xie zenghua,Dispersion compensation optical fiber grating with low ripple coefficient,Acta Optica Sinica,2002,vol.22,pp.336-339
[37]Xie zenghua,Ning Tigang,Pei Li,et al.Fabrication of 13 cm linearly chirped fiber grating,Acta Optica Sinica,2001,vol.21,pp.1381-1383
[38]Julien Poirrier,FEC Operation in Combination With Electronic Dispersion Compensation,Optical Fiber Communications Conference 2008,2008,OTHO4.
[39]John D.Downie,Jason Hurley,Yihong Mauro,and Sergey Lobanov,On the Use of MLSE with Non-Optimal Demodulation Filtering for Optical Duobinary Transmission,Optical Fiber Communications Conference 2008,2008,OTHO5.
[40]陈勇,全光通信网关键技术的研究与实现,北京交通大学博士论文,2006.
[41]Y.Chen,J.H.Cao,Z.W.Tan,Y.Liu,T.Chen,L.N.Ma,D.Y.Chang,T.G.Ning,L.Pei,and S.S.Jian,8×10 Gb/s transmission system over 2015km with dispersion compensation by CFBG,Guangdianzi Jiguang/Journal of Optoelectronics Laser,2005,vol.16,pp.942-946.
[42]D.McGhan,C.Laperle,A.Savchenko,L.Chuandong,G.Mak,and M.O'Sullivan,5120km RZ-DPSK transmission over G.652 fiber at 10 Gb/s without optical dispersion compensation,Photonics Technology Letters,IEEE,1996,vol.18,pp.400-402.
[43]G.Raybon,A.Agarwal,S.Chandrasekhar,and R.J.A.E.R.J.Essiambre,Transmission of 42.7-Gb/s VSB-CSRZ over 1600km and four OADM nodes with a spectral efficiency of 0.8bit/s/Hz,Optical Communication,2005.
[44]R.Ludwig,S.Weisser,C.Schmidt-Langhorst,L.Raddatz,and C.Schubert,Unrepeatered Transmission of 160 Gb/s Rz-DPSKover 240 km Dispersion Managed Fiber,ECOC 2007,2007.
[45]D.van den Borne,S.L.Jansen,E.Gottald,P.M.Krummrich,G.D.Khoe,and H.de Waardt,1.6-b/s/Hz Spectrally Efficient Transmission Over 1700 km of SSMF 40*85.6 Gb/s POLMUX-RZ-DQPSK,Lightwave Technology,Journal of,2007,vol.25,pp.222-232.
[46]吕洪君,胡睿,李子晓,光纤光参量放大器及其应用,2004,vol.17,pp.8-11.
[47]A.S.Omar,FEC techniques in submarine transmission systems,Optical Fiber Communication Conference and Exhibit 2001,2001,vol.2,pp.TuF1.
[48]T.Mizuochi,K.Kubo,H.Yoshida,H.Fujita,H.Tagami,M.Akita,and K.Motoshima,Next generation FEC for optical transmission systems,Optical Fiber Communiactions Conference 2003,2003,vol.2,pp.527-528.
[49]J.X.Cai,M.Nissov,A.N.Pflipetskii,A.J.Lucero,C.R.Davidson,D.Foursa,H.Kidorf,M.A.mills,R.Menges,O.C.Corbett,D.Sutton,and N.S.Bergano,2.4Tb/s transmission over transoceanic distance using optimum FEC overhead and 48%spectral efficiency,Optical Fiber Communications Conference and Exhibit 2001,2001,vol.4,pp.PD24.
[50]T.Mizuochi,K.Ouchi,T.Kobayashi,Y.Miyata,K.Kuni,H.Tagami,K.Kubo,H.Yoshida,M.Akita,and K.Motoshima,Experimental demonstration of net coding gain of 10.1 dB using 12.4 Gb/s block turbo code with 3-bit soft decision,Optical Fiber Communications Conference 2003,2003,vol.3,pp.PD21.
[51]Ouchi,A fully integrated block turbo code FEC for 10 Gb/s optical communication systems,Technical Digest of OFC2006,2006,pp.OTuK4,
[52]Y.Konishi,Block turbo code encoded 24.8Gbps RZ-DQPSK experiment using parallel prefix network based differential precoder,Optical Fiber Communications Conference 2007,2007,pp.13B4.
[53]Takashi Mizuochi,Next Generation FEC for Optical Communication,Optical Fiber Communications Conference 2008,2008,pp.OTuE5.
[54]Wedding B.,Haslach C.N.,Enhanced PMD mitigation by polarization scrambling and forward error correction,Optical Fiber Communication Conference and Exhibit 2001,2001,vol.3,pp.WAA1.
[55]M.F.S.Ferreira and M.H.Sousa,Dispersion-managed solitons in optical fiber systems,Proceedings of 2005 7th International Conference on Transparent Optical Networks,ICTON2005,2005.
[56]Y.H.C.Kwan and P.K.A.Wai,Design of dispersion managed solution systems,Pacific Rim Conference on Laser and Electro-Optics,CLEO- Technical Digest,2001.
[57]W.J.Tomlinson,Technologies for Dynamic Gain and Channel Power Equalization,Conference on Optical Fiber Communication,Technical Digest Series,2003.
[58]Y.Imai,K.Lizuka,and R.T.B.James,Phase-noise-free coherent optical communication system utilizing differential polarization shift keying(DPolSK),Journal of Lightwave Technology,1990,vol.8,pp.691-698.
[59]P.J.Almeida,F.Parmigiani,M.Ibsen,K.Mukasa,P.Petropoulos,and D.J.Richardson,35dB Channel Suppression in OTDM Add-Drop Multiplexing Based on Time-Frequency Signal Processing,Optical Fiber Communication Conference 2006,2006,pp.OWW3.
[60]J.J.Vegas Olmos,J.P.Turkiewicz,M.Garcia Larrode,I.Tafur Monroy,and A.M.J.Koonen,FSK-WDM to IM-OTDM conversion for fiber-to-thepremises access networks,Optical Fiber Communication Conference 2006,2006,pp.OFE6.
[61]M.Shirane,Y.Hashimoto,H.Yamada,A compact optical sampling measurement system using mode21ocked laser2 diode modules,IEEE Photonics Technology Letter,2000,vol.12,pp.1537-1539.
[62]彭璨,姚敏玉,张洪明,徐千帆,张剑锋,高以智,10 GHz Actively Mode-locked Fiber Ring Laser,中国激光,2003,vol.2,pp.17-19.
[63]Ivan Kaminow厉鼎毅主编 余力等译《光纤通信》中文版 北京:北京邮电大学出版社,2006.
[64]Chien-Chung Lee,Yung-Kuang Chen,and Shien-Kuei Liaw,Single-longitudinal-mode fiber laser with a passive multiple-ring cavity and its application for video transmission,Optics Letters,Vol.23,pp.358-360.
[65]Xinhuan Feng,Yange Liu,Shenggui Fu,Shuzhong Yuan,Xiaoyi Dong,Switchable dual-wavelength ytterbium-doped fiber laser based on a few-mode fiber grating,Photonics Technology Letters,IEEE,2004,vol.16,pp.762-764.
[66]Dae Seung Moon,Un-Chul Paek,and Youngjoo Chung,Multi-wavelength lasing oscillations in an erbium-doped fiber laser using few-mode fiber Bragg grating,Optics Express,2004,Vol.12,pp.6147-6152.
[67]Yamamoto T.,Yoshida E.,Tamura K.R.,Yonenaga K.,Nakazawa M.,640-Gbit/s optical TDM transmission over 92 km through adispersion-managed fiber consisting of single-mode fiber and reverse dispersion fiber,Photonics Technology Letters,IEEE,2000,vol.12,pp.353-355.
[68]Alistair J.Poustie,Neil Finlayson,and Paul Harper,Multiwavelength fiber laser using a spatial mode beating filter,Optics Letters,1994,Vol.19,pp.716-718
[69]S.V.Chernikov,Y.Zhu,J.R.Taylor,and V.P.Gapontsev,Supercontinuum self-Q-switched ytterbium fiber laser,Optics Letters,1997,Vol.22,pp.298-300.
[70]Brian R.Washburn,Scott A.Diddams,Nathan R.Newbury,Jeffrey W.Nicholson,Man F.Yan,and Carsten G.Jrgensen,Phase-locked,erbium-fiber-laser-based frequency comb in the near infrared,Optics Letters,2004,Vol.29,pp.250-252.
[71]A.D.Ellis,K.Smith,and D.M.Patrick,All optical clock recovery at bit rates up to 40Gbit/s,Electronics Letters,1993,vol.29,pp.1323-1324.
[72]L.Yuhua,K.Cheolhwan,L.Guifang,Y.Kaneko,R.L.Jungerman,and O.Buccafusca,Wavelength and polarization insensitive all-optical recovery from 96-Gb/s data by using a two-section gain-coupled DFB laser,Photonics Technology Letters,IEEE,2003,vol.15,pp.590-592.
[73]D.H.Kim,S.H.Kim,J.C.Jo,and S.S.Choi,Ultrahigh speed clock recovery with optical phase lock loop based on four-wave-mixing in a semiconductor optical amplifer,Optics Communications,2000,vol.182,pp.329-334.
[74]D.L.Butler,J.S.Wey,M.W.Chbat,G.L.Burdge,and J.Goldhar,Optical recovery from a data stream of an arbitrary bit rate by use of stimulated Brillouin scattering,Optics letters,1995,vol.20,pp.560-562.
[75]王安斌,伍剑,林金桐,基于电吸收调制器的高速时钟信号的提取,2003,光子学报,vol.32,pp.1-7
[76]Seung-Woo Seo,Bergman K.,Prucnal P.R.,Transparent optical networks with time-division multiplexing,Selected Areas in Communications,IEEE Journal on,1996,vol.14,pp.1039-1051.
[77]Klaus Grobe,et al.,Assessment of 40Gb/s Techniques for Metro/Regional Applications,OFC'2006,NThA1.
[78]Wong C.S,Tsang H.K.,Polarization-independent wavelength conversion at 10 Gbit/s using birefringence switching in a semiconductor optical amplifier,IEEE Photonics Technology Letters,2003,vol.15,pp.87-89.
[79]赵伯林,林礼煌,日电研制适用于1 Tbit/s脉冲的超高速半导体全光开关,激光与光子学进展,1995,vol.2,pp.26-27.
[80]友清,用半导体超晶格实现250 fs全光开关,激光与光子学进展,1996,vol.10,pp.28-29.
[81]Sharping Jay E.,Marco Fiorentino,Prem Kumar,All-optical switching based on cross-phase modulation in microstructure fiber,IEEE Photonics Technology Letters,.2002,vol.14,pp.77-79.
[82]刘玉敏,俞重远,张建忠,粒子群优化算法用于光纤布拉格光栅综合问题的研究,激光杂志,2005,26(4):69-70.
[83]文晓燕,余谦,基于差分演化算法的啁啾光纤光栅参数重构方法,仪器仪表学报,2008,vol.29,pp.2216-2219.
[84]张荣佯,郑世杰,夏彦君,张绥远,支持向量回归算法在光纤光栅非均匀应变重构中的应用,光学学报,2008,vol.28,pp.1513-1517.
[85]WinickK.A,Roman J.E,Design of corrugated waveguide filters fourier transform techniques,IEEE J.Quantum Electron.,1990,vol.2,pp.1918-1929.
[86]Peral E,Capmany J,Marti J,Iterative solution to the Gelfan-Levitan-Marchenko coupled equations and application to synthesis of fiber gratings,IEEE J.Quantum Electron.,1996,vol.32,pp.2078-2084.
[87]Muriel M.A.,Azana J.,Carballar A.,Fiber grating synthesis by use of time frequency representation,Optics Letters,1998,vol.23,pp.1526-1528.
[88]Azana J.,Muriel M.A.,Chen LFiber Bragg Grating period reconstruction using time-frequency signal analysis and application to distributed sensing,IEEE/OSA Journal of Lightwave Technology,2001,vol.19,pp.646-654.
[89]Feced R,Zervas M.N.,Muriel M.A.,An efficient inverse scattering algorithm for the design of nonuniform fiber Bragg gratings,Journal of Quantum E lectronics,IEEE,1999,vol.35,pp.1105-1115
[90]Holland J.H.,Adaptation in natural and artificial systems,University of Michigan Press,Ann Arbor,1975.
[91]Fogel L.J.,Owens A.J.,Walsh M J.,Artificial intelligence through simulated evolution,John Wiley,Chichester,UK,1996.
[92]Kirkpatrick S.,Optimization by simulated annealing.Science,1983,vol.220,pp.671-680.
[93]Storn R.,Differential Evolution Design of an IIR-Filter,IEEE International.Conference On Evolutionary Computation,Nagoya,1996,vol.26 pp.8-273.
[94]Dorigo M.,Maniezzo V.,Colormi A.,The ant system:optimization by a colony of cooperating agents,IEEE Transactions on Systems,Man,and Cybernetics-Part B,19 96,vol.26,pp.1-13.
[95]简水生,“光纤网的发展与机遇”,中国电子商情:通信市场,no.11,2001,pp.13-18.
[96]简水生,新一代、高度安全、超大容量、无阻塞全光网是信息社会的基础,光通信,2003,vol.12,pp.14-21.
[97]简水生,建立“新一代、高度安全、超大容量、无阻塞全光网”是我国本世纪初叶重大科学战略工程,网络电信,2003,no.11,pp.16-2I.
[98]A.A.M.Saleh,Overview of the MONET,Multiwavelength Optical Networking program,Photonics Technology Letters,IEEE,1990,vol.2,pp.714-717.
[99]M.S.Goodman,C.L.Allyn,R.Tkach,D.I.Pompey,m.R.Wilder,K.Goel,and B.Tyrone,The multiwavelength optical networking program(MONET),Military Communications Conference,IEEE,1996,vol.1,pp.121-124.
[100]http://cords.europa.eu/infowin/acts/rus/projects/
[101]L.Jintong and W.Jian,Optical networking testbeds in China,Optical Communications Fiber Conference 2006,2006,vo.1,pp.OWU2.
[102]http://www.gaikuo.com/html/3/2007/0331/17504.html
[103]纪越峰等,光突发交换网络.北京:北京邮电大学出版社,2005.
[104]"GENI:global environment for network innovations," http://www.geni.net/
[105]"FIND:future Internet network design," http://find.isi.edu/
[106]http://www.hudong.com/wiki/暗光纤/
[1]T.N.Nielsen,A.J.Stentz,K.Rottwitt,D.S.Vengsarkar,Z.J.Chen,3.28 Tb/s(82×40 Gb/s)transmission over 3×100km nonzero-dispersion fiber using dual C- and L-band hybrid Raman/erbium doped inline amplifers,Optical Fiber Communications Conference 2000,2000,vol.4,pp.236-238.
[2]F.Heismann,D.A.Fishman,and D.L.wilson,Automatic compensation of first order polarization mode dispersion in a 10 Gb/s transmission system,24th European Conference on Optical Communication,1998,vol.1,pp.529-530.
[3]C.Yong,C.Jihong,C.Ting,and J.Shuisheng,Advanced modulation formats for long-haul optical-transmission systems with dispersion compensation by chirped FBG,Microwave and Optical Technology Letters,2006,vol.48,pp.344.
[4]L.D.Garrett,A.H.Gnauck,F.Forghieri,V.Gusmeroil,and D.Scarano,16×10Gb/s WDM transmission over 840-km SMF using eleven broad-band chirped fiber gratings,photonics Technology Letters,IEEE,1999,vol.11,pp.484-486.
[5]Z.Tan,S.Jian,Y.Liu,and T.Ning,10Gb/s transmission over 1400km of G.652 fiber using chirped fiber Bragg gratings dispersion compensation,APOC2004,2004.
[6]AkiraHirano,应用在超高速光传输系统里的新兴调制方式,网络电信,2005,no.1,pp.52-54.
[7]A.Hirano and Y.Miyamoto,Novel modulation formats in ultra-high-speed transmission systems and their applications,Optical Communications Conference 2004,2004,vol.2,pp.ThM2.
[8]A.Hirano and Y.Miyamoto,Novel modulation formats in ultra-high-speed transmission systems and their applications,Optical Communications Conference 2006,2006,vol.2,pp.OFD3.
[9]W.Xing,L.Xiang,and C.Xu,numerical simulation of the SPM penalty in a 10-Gb/s RZ-DPSK system,Photonics Technology letters,IEEE,2003,vol.15,pp 1636-1638.
[10]H.Keang Po and W.His-Cheng,Comparison of nonlinear phase noise and intrachannel four-wave mixing for RZ-DPSK signals in dispersive transmission systems,Photonics Technology letters,IEEE,2005,vol.17,pp.1426.
[11]D.van den Borne,V.Veljanovski,U.Gaubatz,C.Paquet,Y.Painchaud,E.Gottwald,G.D.Khole,and H.de waardt,42.8 Gb/s RZ-DQPSK Transmission with FBG-Based In-Line Dispersion Compensation,Photonics Technology letters,IEEE,2007,vol.19,pp.1069-1071.
[12]Y.Yano,T.Ono,K.Fukuchi,T.Ito,H.Yamazaki,M.Yamaguchi,and k.Emura,2.6 terabit/s WDM transmission experiment using optical duobinary coding,European Conference on Optical Communication,ECOC,1996.
[13]D.Penninckx,M.Chbat,L.Pierre,and J.P.Thiery,Phase-shaped binary transmission(PSBT):A new technique to transmit far beyond the chromatic dispersion limit,European Conference on Optical Communication,ECOC,1996.
[14]A.matsuura,k.Yonenaga,Y.Miyamoto,A.Sano,H.Toba,and M.Yoneyama,High power tolerant optical duobinary signal transmission,IEICE Transactions on Communications,2001,vol.,E85-B,pp.1173-1178.
[15]R.C.Lee,H.A.Abdul-Rashid,M.T.Al-Qdah,H.T.Chuah,M.B.Tayahi,and S.Lanka,The effects of phase errors on optical SSB system performance,Microwave and Optical Technology Letters,2006,vol.,48,pp.1574-1578.
[16]W.Jin and J.M.Kahn,Accurate bit-error-ratio computation in nonlinear CRZ-OOK and CRZ-DPSK systems,Photonics Technology letters,IEEE,2004,vol.16,pp.2165-2167.
[17]D.Penninckx,M.Chbat,L.Pierre,and J.P.Thiery,Phase-shaped binary transmission (PSBT):A new technique to transmit far beyond the chromatic dispersion limit,European Conference on Optical Communication,ECOC,1996.
[18]X.Wei,X.Liu,S.Chandrasekhar,A.H.Gnauck,G Raybon,J.Leuthold,and P.J.Winzer,40Gb/s Duobinary and modified Duobinary Transmitter based on an Optical Delay Interferometer,28th European Conference on Optical Communication,2002,vol.4,pp.1-4.
[19]A.Hirano and Y.Miyamoto,Novel modulation formats in ultra-high-speed transmission systems,and their applications,Optical Fiber Communications Conference 2006,2006,vol.2,pp.OFD3.
[20]Sebastien R.Blais and Jianping Yao,Optical Single Sideband Modulation Using an Ultranarrow Dual-Transmission-BandFiber Bragg Grating,Photonics Technology letters,IEEE,2006,vol.18,pp.2230-2232.
[21]L.Chen,H.Wen,and S.Wen,A Radio-Over-Fiber System With a Novel Scheme for Millimeter-Wave Generation and Wavelength Reuse for Up-Link Connection,Photonics Technology letters,IEEE,2006,vol.18,pp.2056-2058.
[22]Fei Zheng,Jianping Yao,An approach to ultrawideband pulse generation and distribution over optical fiber,Photonics Technology letters,IEEE,2006,vol.18,pp.823-825.
[23]J Yu,Z Jia,L Xu,L Chen,T Wang,G Chang,DWDM Optical Millimeter-Wave Generation for Radio-Over-Fiber Using an Optical Phase Modulator and an Optical Interleaver,Photonics Technology letters,IEEE,2006,vol.18,pp.913-925.
[24]S.N.Knudsen and L.Gruner-Nielsen,New fiber for future telecommunication systems,laser and Electro-Optics Society 2000 Annual meeting.LEOS 2000.13th Annual Meeting IEEE,2000.
[25]T.Tsuda,Y Akasaka,S.Sentsui,K.Aiso,Y Suzuki,and T.Kamiya,Broad band dispersion slope compensation of dispersion shifted fiber using negative slope fiber,Optical Communication,1998.24th European Conference on,1998.
[26]A.Hidayat,A.F.Abas,D.Sandel,S.Bhandare,H.Zhang,F.Wust,B.Milivoevic,R.Noe,M.Lapointe,YPainchaud,and M.Guy,5.94 tbit/s capacity of a FBG-based multichannel tunable-700 to-1200 ps/nm dispersion compensator,Journal of Optical Communications,2006,vol.,27,pp.17-19.
[27]D.Sandel,S.Bhandare,A.F.Abas,B.milivojevic,R.Noe,M.Guy,and M.Lapointe,Automatic tunable chromatic dispersion compensation at 40Gb/s in Ask and DPSK,NRZ,and CSRZ 263-km transmission experiments,Photonics Technology letters,IEEE,2004,vol.16,pp.2568-2570.
[28]L.Poladian,understanding profile-induced group-delay ripple in Bragg gratings,Applied Optics, 2000,vol.,39,pp.1920-1923.
[29]J.C.Cartledge and H.Chen,Influence of modulator chirp in assessing the performance implications of the group delay ripple of dispersion compensating fiber bragg gratings,Journal of Lightwave Technology,2003,vol.,21,pp.1621-1628.
[30]L.S.Yan,T.luo,Q.Yu,Y Xie,K.M.Feng,R.khosravani,and A.E.Willner,Investigation of performance variations due to the amplitude of group-delay ripple in chirped fiber Bragg gratings,Optical Fiber Technology,2006,vol.,12,pp.238-242.
[31]YH.C.Kwan and P.K.A.Wai,Effects of group delay ripple on solitons in grating compensated dispersion managed systems,Pacific Rim Conference on Lasers and Electro-Optics,CLEO-Technical Digest,2001.
[32]Z.Lin,C.Minghua,Z.Yejin,and X.Shizhong,Impacts of cascaded filters with group delay ripple on 40Gb/s WDM transmission sytem,Photonics Technology Letters,2002,vol.14,pp.1518-1520.
[33]G.H.Smith,D.Novak,and Z.Ahmed,Overcoming chromatic-dispersion effects in fiber-wireless systems incorporating external modulators,Transation.Microwave Theory Technology,IEEE,1997,vol.45,pp.1410-1415.
[34]Takano K.,Hanzawa N.,Tanji S.,Nakagawa K.,Experimental Demonstration of Optically Phase-Shifted SSB Modulation with Fiber-Based Optical Hilbert Transformers,Optical Fiber Communications Conference 2007,2007,pp.1-3.
[35]Y Shen,X.Zhang,and K.Chen,Optical single sideband modulation of 11-GHz RoF system using stimulated Brillouin scattering,Photonics.Technology.Letter,IEEE,2005,vol.17,pp.1277-1279.
[36]Kitayama K.,Kuri T.,Onohara K.,Kamisaka T.,Murashima K.,Dispersion effects of FBG filter and optical SSB filtering in DWDM millimeter-wave fiber-radio systems,Journal of Lightwave Technology,IEEE,2002,vol.20,pp.1397-1407
[37]Capmany J.,Pastor D.,Munoz P.,Ortega B.,Sales S.,Martinez A.,Multiwavelength optical SSB generation for dispersion mitigation in WDM fibre radio systems using AWG multiplexer,Electronics Letters,IEEE,2002,vol.38,pp.1194-1196.
[38]Fei Zheng,Jianping Yao,Optical Single Sideband Modulation Using an Ultranarrow Dual-Transmission-Band Fiber Bragg Grating,Photonics Technology letters,IEEE,2006,vol.18,pp.2230-2232.
[39]C.Marra,A.Nirmalathas,D.Novak,C.Lim,L Reekie,The impact of grating dispersion on transmission performance in a millimeter-wave fiber-radio system,Photonics Technology Letters,IEEE,2002,vol.14,pp.1345-1347.
[40]Z.Xiang,H.H.M.Shalaby,C.Lu,T.H.Cheng,and Y.Peida,A performance analysis of all optical clock extraction circuit based on stimulated Brillouin scattering,Journal of Lightwave Technology,2000,vol.18,pp.1453-1466.
[41]Takano K.,Hanzawa N.,Tanji S.,Nakagawa K.,Experimental Demonstration of Optically Phase-Shifted SSB Modulation with Fiber-Based Optical Hilbert Transformers,Optical Fiber Communication and the National Fiber Optic Engineers Conference,2007.
[42]顾畹仪,WDM超长距离光传输技术。北京:北京邮电大学出版社,2005.
[43]C.Henry,Phase noise in semiconductor lasers,Journal of Lightwave Technology,1986,vol.4, pp.298-311.
[44]G.P.Agrawal,非线性光纤光学原理及应用.北京:电子工业出版社,2002.
[45]R.W.Tkach,A.R.Chraplyvy,F.Forghieri,A.H.Gnauck,and R.M.Derosier,Four-photon mixing and high-speed WDM systems,Journal of Lightwave Technology,1995,vol.13,pp.841-849.
[46]G.keiser著;李玉权等译,光纤通信(第三版).北京:电子工业出版社,2002.
[47]余建军,管克俭,杨伯君,10Gbit/s单通道长距离光通信系统的数值模拟,光通信研究,1999,vol.,91,pp.5-12.
[48]M.Brain and L.Tien-pei,Optical receivers for lightwave communication systems,ElectronDevices,IEEE transactions on,1985,vol.32,pp.2673-2692.
[49]R.I.Laming,P.R.Morkel,D.N.Payne,and L.Reekie,Noise in erbium-doped fiber amplifers,Fourteenth European Conference on Optical Communication,1988,vol.1,pp.54-57.
[50]"The ITU Telecommunication Standardization G.957," http://www.itu.int/ITU-T/.
[51]C.J.Anderson and J.A.Lyle,Technique for evaluating system performance using Q in numerical simulations exhibiting intersymbol interference,Electronics Letters,1994,vol.30,pp.71-72.
[52]I.Eugenio,F.Matera,A.Mecozzi,and M.Settembre,Nonlinear Optical Communication Networks:John Wiley,1998.
[53]R Li,J.Shuisheng,Y.Fengping,N.Tigang,and W.Zhi,Long-haul WDM system through conventional single mode optical fiber with dispersion compensation by chirped fiber Bragg grating,2003,vol.222,pp.169-178.
[54]裴丽,宁提纲,李唐军,董小伟,简水生,高速光通信系统中光纤光栅色散补偿研究,物理学报,2005,vol.54,pp.1630-1635.
[55]谭中伟,郑凯,刘艳,傅永军,陈勇,曹继红,宁提纲,董小伟,马丽娜,简水生,基于啁啾光纤光栅的色散补偿器在超长距离密集波分复用系统中的应用,物理学报,2005,vol.54,pp.5218-5223.
[56]K.Hinton and J.Arkwright,Impact of grating delay and reflectivity tipple in optical systems,Conference Record/IEEE Global Telecommunications Confernece,1998,vol.,2,pp.986-991.
[57]M.Sumetsy,B.Eggleton,C.de sterke.Theory of group delay ripple generated by chirped fiber gratings,Optics Express,2002,vol.10,pp.332-340.
[1]吴重阳,光纤光缆技术大展望 江苏亨通光电股份有限公司http://www.gglchina.com/lianjie/guangqian/coverread.asp?cover_id=31Kuznetsov.
[2]M.Daikoku,et al.,"100Gbit/s DQPSK Transmission Experiment without OTDM for 100G Ethernet Transport",Proc.OFC 2006,PDP36.
[3]Toshihiko Hirooka,Masatada Okazaki,Kou Osawa,and Masataka Nakazawa,160 Gbit/s-900km DPSK Transmission with Time-domain Optical Fourier Transformation,ECOC'2007, Session 1.3-High Speed Transmission
[4]J.J.Vegas Olmos,J.P.Turkiewicz,M.Garcia Larrode,I.Tafur Monroy,and A.M.J.Koonen,FSK-WDM to IM-OTDM conversion for fiber-to-thepremises access networks,OFC2006,Session,OFE6.
[5]刘涛,赵尚弘,谢小平,夏贵进,占生宝,OTDM实用化关键技术分析,电讯技术,2002年,vol.4,pp.28-31
[6]赵永鹏;Baker L;Khoe G D;deWaardt H;A 160 Gbit/s OTDM Demonstrator for LOFAR Networks,光子学报,2007,vol.1,pp.23-26.
[7]M.Shirane,Y.Hashimoto,H.Yamada,A compact optical sampling measurement system using mode2locked laser2 diode modules,IEEE Photon.Technol.Lett.,2000,vol.12,pp.1537-1539.
[8]彭璨,姚敏玉,张洪明,徐千帆,张剑锋,高以智,10 GHz Actively Mode-locked Fiber Ring Laser,中国激光,2003,vol.2,pp.17-19.
[9]Ivan Kaminow厉鼎毅主编 余力等译《光纤通信》中文版北京:北京邮电大学出版社,2006.
[10]Chien-Chung Lee,Yung-Kuang Chen,and Shien-Kuei Liaw,Single-longitudinal-mode fiber laser with a passive multiple-ring cavity and its application for video transmission,Optics Letters,Vol.23,pp.358-360.
[11]Xinhuan Feng,Yange Liu,Shenggui Fu,Shuzhong Yuan,Xiaoyi Dong,Switchable dual-wavelength ytterbium-doped fiber laser based on a few-mode fiber grating,Photonics Technology Letters,IEEE,2004,vol.16,pp.762-764.
[12]Dae Seung Moon,Un-Chul Paek,and Youngjoo Chung,Multi-wavelength lasing oscillations in an erbium-doped fiber laser using few-mode fiber Bragg grating,Optics Express,2004,Vol.12,pp.6147-6152.
[13]Yamamoto T.,Yoshida E.,Tamura K.R.,Yonenaga K.,Nakazawa M.,640-Gbit/s optical TDM transmission over 92 km through adispersion-managed fiber consisting of single-mode fiber and reverse dispersion fiber,Photonics Technology Letters,IEEE,2000,vol.12,pp.353-355
[14]Alistair J.Poustie,Neil Finlayson,and Paul Harper,Multiwavelength fiber laser using a spatial mode beating filter,Optics Letters,1994,Vol.19,pp.716-718
[15]S.V.Chernikov,Y.Zhu,J.R.Taylor,and V.P.Gapontsev,Supercontinuum self-Q-switched ytterbium fiber laser,Optics Letters,1997,Vol.22,pp.298-300.
[16]Brian R.Washburn,Scott A.Diddams,Nathan R.Newbury,Jeffrey W.Nicholson,Man F.Yan,and Carsten G.Jrgensen,Phase-locked,erbium-fiber-laser-based frequency comb in the near infrared,Optics Letters,2004,Vol.29,pp.250-252.
[17]李唐军,160Gb/s光时分复用系统关键技术的研究.北京交通大学博士论文,2008
[18]C.Boerner,,et al.,160 Gb/s Clock Recovery and Demultiplexing Using One Single EAM,ECOC 2003,Th2.5.1
[19]尹丽娜 曹灼等,非等幅OTDM信号的全光时钟提取,光子学报,2005,vol.34,pp.1-4.
[20]W.Tong,L.Caiyun,H.Li,A.Z.W.Zhaoxin Wang,and A.Y.G.YizhiGao,Combination of comb-like filter and SOA for preprocessing to reduce the pattern effect in the clock recovery,Photonics Technology Letters,IEEE,2004,vol.1,pp.614-616.
[21]D.M.Patrick and R.J.Manning,20 Gbit/s all-optical clock recovery using semiconductor nonlinearity,Electronics Letters,1994,vol.30,pp.151-152.
[22]K.Vlachos,G.Theophilopoulos,A.Hatziefremidis,and H.A.A.H.Avramopoulos,30Gb/s all-optical clock recovery circuit,Photonics Technology Letters,IEEE,2000,vol.12, pp.705-707.
[23]战莹,邵钟浩,OTDM中时钟提取技术的发展及前景,现代传输,2006,vol.31,pp.1-4.
[24]王安斌,伍剑,拱伟,林金桐,基于LiNbO3调制器的高速时钟信号的提取,半导体光电,2003,vol.5
[25]A.D.Ellis,K.Smith,and D.M.Patrick,All optical clock recovery at bit rates up to 40Gbit/s,Electronics Letters,1993,vol.29,pp.1323-1324.
[26]L.Yuhua,K.Cheolhwan,L.Guifang,Y.Kaneko,R.L.Jungerman,and O.Buccafusca,Wavelength and polarization insensitive all-optical recovery from 96-Gb/s data by using a two-section gain-coupled DFB laser,Photonics Technology Letters,IEEE,2003,vol.15,pp.590-592.
[27]D.H.Kim,S.H.Kim,J.C.Jo,and S.S.Choi,Ultrahigh speed clock recovery with optical phase lock loop based on four-wave-mixing in a semiconductor optical amplifer,Optics Communications,2000,vol.182,pp:329-334.
[28]D.L.Butler,J.S.Wey,M.W.Chbat,G.L.Burdge,and J.Goldhar,Optical recovery from a data stream of an arbitrary bit rate by use of stimulated Brillouin scattering,Optics letters,1995,vol.20,pp.560-562.
[29]王安斌,伍剑,林金桐,基于电吸收调制器的高速时钟信号的提取,2003,光子学报,vol.32,pp.1-7
[30]Seung-Woo Seo,Bergman K.,Prucnal P.R.,Transparent optical networks with time-division multiplexing,Selected Areas in Communications,IEEE Journal on,1996,vol.14,pp.1039-1051.
[31]Klaus Grobe,et al.,Assessment of 40Gb/s Techniques for Metro/Regional Applications,OFC'2006,NThA1.
[32]M.J.Ablowitz,T.Hirooka,Interchannel pulse interactions in dispersion-managed transmission systems:Timing shifts,Optics letters,2001,vol.26,pp.1846-1848.
[33]王目光,光纤偏振特性及其测量与补偿技术的研究.北京交通大学博士论文,2004.
[34]解奕鹏,光纤激光器的发展现状,世界宽带网络,2004,vol.11,pp.12-15.
[35]G.P.Agrawal,非线性光纤光学原理及应用.北京:电子工业出版社,2002.
[36]C.X.Yu,H.A.Haus,E.P.Ippen,W.S.Wong,and A.Sysoliatin,Gigahertz-repetition-rate mode-locked fiber laser for continuum generation,Optics Letters,2000,vol.25,1418-1420.
[37]王林,利用拍频反馈控制调制频率实现再生锁模的光纤激光器,半导体光电,2002,vol.23,pp.5-7
[38]Yin lina,Cao Zhuo,Liu Guoming,Wu Jian,Lin Jintong,All optical recovery from unequal amplitude multiplexed OTDM signals,ACTA PHOTONICA SINICA,2005,vol.34,pp.1-4.
[39]戴居丰,于普龙,马晓红,从非均匀分布的信号脉冲中提取基频时钟脉冲,中国激光,2001,A28,pp.67-70
[40]C.Johnson,K.Demarest,C.Allen,R.Hui,K.V.Peddanarapagari,B.Zhu,and R.K.Butler,Multiwavelength all-optical clock recovery,Conference Proceedings-lasers and Electro-Optics Society Annual Metting-LEOS,1998.
[41]左鹏,伍剑,张帆,林金桐,4×10Gbit/s OTDM系统中10GHz帧时钟提取技术,电子学报,2002,vol.30,pp.1-3.
[42]T.Wang,C.Lou,L.Huo,Z.Wang,andY.Gao,Combination of Comb-LikeFilter and SOA for Preprocessing to Reduce the Patten Effect in the Clock Recovery,Photonics Technology Letters,IEEE,2004,vol.16,PP.614-616.
[43]http://www.cip.com/
[44]Feng Xu,Jiansheng Liu,Ruxin Li,and Zhizhan Xu,Pulse compression and supercontinuum at different powers of femtosecond pulses in water,Chinese Optics Letters,2007,vol.5,pp.490-492.
[45]S.W.Chan,K.K.Chow,C.Shu,Nonlinear Pulse Compression and Reshaping Using Cross-Phase Modulation in a Dispersion-Shifted Fiber,ACTA OPTICA SINICA,2003,vol.23,pp.1-2.
[46]S.V.Chernikov,E.M.Dianov,D.J.Richardson and D.N.Payne,Soliton pulse compression in dispersion-decreasing fiber,Optics Letters,1993,vol.18,pp.476-479.
[47]K.Shiraki.M.Ohashi and M.Tateda,Suppression of stimulated Brillouin scattering in a fibre by changing the core radius,Electronics Letters,1995,vol.31,pp.668.
[48]K.Shiraki,M.Ohashi,and M.Tateda,SBS Threshold of a Fiber with a brillouin Frequency Shift Distribution,Journal of Lightwave Technology,1996,vol.14,pp.50-53.
[49]N.Yoshizawa,and T.Imai,Stimulated Brillouin Scattering Suppression by Means of Applying Strain Distribution to Fiber with Cabling,Journal of Lightwave Technology,1993,vol.11,pp.1518-1520.
[50]Y.Imai,and N.Shimada,Dependence of Stimulated Brillouin Scattering on Temperature Distribution in Polarization-Maintaining Fibers,Photonics Technology Letters,vol.5,1993,pp.1335-1146.
[51]N.A.Olsson,and J.P.Van Der Ziel,Characteristics of a Semiconductor Laser Pumped Brillouin Amplifier with Electronically Controlled Bandwidthjournal of Lightwave Technology,1987,vol.3,pp.147-151.
[52]Y.Aoki,K.Tajima,and I.Mito,Input Power Limits of Single-Mode Optical Fibers due to Stimulated Brillouin Scattering in Optical Communication Systems,Journal Lightwave Technology,1988,vol.6,pp.710-715
[1]T.G.Ning,L.Pei,Y.Liu,Z.W.Tan,Z.Tong,F.P.Yan an S.S.Jian,Optimization of electron-beam-written step-chirped phase masks to improve quality of the chirped FBG,Guangdianzi Jiguang/Journal of Optoelectronics Laser,2006,vol.17,pp.1409-1412.
[2]Z.W.Tan,B.Li,Y.H.Wang,W.H.Ren,Y.Liu,T.G.Ning,and S.S.Jian,Background loss of the fiber induced by the ultraviolet light exposure,Zhongguo Jiguang/Chinese Journal of Laser,2007,vol.34,pp.239-242.
[3]Y.Liu,B.Li,K.Zheng,Z.W.Tan,Y.Chen,Y.H.Wang,W.H.Ren,and S.S.Jian,Temperature or strain induced adjustable-chirped characteristics of uniform fibre grating with tapered coating,Chinese physics,2007,vol.16,pp.1694-1699.
[4]Z.W.Tan,T.G.Ning,Y.Liu,Z.Tong,and S.S.Jian,Suppression of the interactions between fiber gratings used as dispersion compensators in dense wavelength-division multiplexing systems,Chinese physics,2006,vol.15,pp.1819-1823.
[5]刘玉敏,俞重远,张建忠,粒子群优化算法用于光纤布拉格光栅综合问题的研究闭,激光杂志,2005,26(4):69-70.
[6]文晓燕,余谦,基于差分演化算法的啁啾光纤光栅参数重构方法,仪器仪表学报,2008,vol.29,pp.2216-2219.
[7]张荣祥,郑世杰,夏彦君,张绥远,支持向量回归算法在光纤光栅非均匀应变重构中的应用,光学学报,2008,vol.28,pp.1513-1517.
[8]WinickK.A,Roman J.E,Design of corrugated waveguide filters fourier transform techniques,IEEE J.Quantum Electron.,1990,vol.2,pp.1918-1929.
[9]Peral E,Capmany J,Marti J,Iterative solution to the Gelfan-Levitan-Marchenko coupled equations and application to synthesis of fiber gratings,IEEE J.Quantum Electron.,1996,vol.32,pp.2078-2084.
[10]Muriel M.A.,Azana J.,Carballar A.,Fiber grating synthesis by use of time frequency representation,Optics Letters,1998,vol.23,pp.1526-1528.
[11]Azana J.,Muriel M.A.,Chen LFiber Bragg Grating period reconstruction using time-frequency signal analysis and application to distributed sensing,IEEE/OSA Journal of Lightwave Technology,2001,vol.19,pp.646-654.
[12]Feced R,Zervas M.N.,Muriel M.A.,An efficient inverse scattering algorithm for the design of nonuniform fiber Bragg gratings,Journal of Quantum E lectronics,IEEE,1999,vol.35,pp.l 105-1115
[13]T.Erdogan.Fiber Grating Spectra,IEEE Journal of Lightwave Technology,1997,vol.15,pp.1277-1294.
[14]SKAAR Johannes,LIGANG WANQERDOGAN Turan,On the synthesis of fiber Bragg gratings by layer peeling,Journal of quantum electronics,IEEE,2001,vol.37,pp.165-173
[15]Jian Shuisheng,Zhao Yucheng,Wei Daoping,Dispersion compensation experimental on 19ps pulse width over 133km single mode fiber with tunable chirp and wavelength gratings,Science in China,1999,vol.42,pp.165-170.
[16]L.Xiang,W.Xing,A.H.Gnauck et al..Analysis of loss ripple and its application to the mitigation of optical filtering penalty,IEEE Photonics Technology Letters,2005,vol.17,pp.82-84.
[17]Z.Lin,C.Minghua,Z.Yejin et al..Impacts of cascaded filters with group delay ripples on 40Gb/s WDM transmission system,IEEE Photonics Technology Letters,2002,voU4,pp.1518-1520
[18]J.A.Dobrowolski,D.Lowe.Optical thin film synthesis program based on the use of Fourier transforms,Applied Optics,1978,vol.17,pp.3039-3050
[19]E.Peral,J.Capmany,J.Marti.Design of fiber grating dispersion compensators using a novel iterative solution to the Gel'fan-Levitan-Marchenko coupled equations,Electronics Letter.,1996,vol.32,pp.918-919
[20]R.Feced,M.N.Zervas,M.A.Muriel.An efficient Inverse scattering algorithm for the design of nonuniform fiber Bragg gratings,IEEE Journal of Quantum Electronics,1999,vol.35,pp.l 105-1115
[21]J.Skaar,K.M.Risvik.A genetic algorithm for the inverse problem in synthesis of fiber gratings,Journal of Lightwave Technology,1998,vol.16,pp.1928-1932
[22]Mu Kejun,Zhou Xiaojun,Ren Guorong,Reconstruction of Parameters of Fiber Gratings from Time-Delay,Chinese J.Lasers,2007,vol.34,pp.688-693
[23]Guan Baiou,Yu Youlong,Ge Chunfeng,Theoretical studies on transmission charicteristics of fiber grating Fabry-perot cavity,Acta Optica Sinica,2000,vol.20,pp.34-38
[24]Jin Xiaofeng,Zhang ZhongXian,Non-uniform optical fiber grating response,Acta Optica Sinica,1999,vol.19,pp.721-727
[25]Xie zenghua,Ning Tigang,Pei Li,et al.Fabrication of 13 cm linearly chirped fiber grating,Acta Optica Sinica,2001,vol.21,pp.13 81-13 83
[26]T.Erdogan.Fiber Grating Spectra.IEEE Journal of Lightwave Technology,1997,vol.15,pp.1277-1294.
[27]D.Paster,J.Capmany,D.Ortega et al.,Design of apodized linearly chirped fiber gratings for dispersion compensation,Journal of Lightwave Technology.1996,vol.14,pp.2581-2588.
[28]Liu Yan,Zheng Kai,Tan Zhongwei et al,Good performance of chirped fiber Bragg gratings obtained by asymmetrically one-side exposure apodization,Acta Physica Sinica,2006,vol.55,pp.5859-5865
[29]M.Sumetsy,B.Eggleton,C.de sterke.Theory of group delay ripple generated by chirped fiber gratings,Optics Express,2002,vol.10,pp.332-340.
[30]Tan Zhongwei,Liu Yan,Ning Tigang,Jian Shuisheng,The generation of group delay ripple of chirped fiber gratings,Chinese Optics Letter,2004,vol.2,pp.18-20.
[31]Ning Tigang,Liu Yan,Tan Zhongwei,Jian Shuisheng,Impact on dispersion compensated system using chirped fiber Bragg grating with delay ripple,Acta Optica Sinica,2003,vol.23,pp.1064-1067
[32]Pei Li,Jian Shuisheng,Xie zenghua,Dispersion compensation optical fiber grating with low ripple coefficient,Acta Optica Sinica,2002,vol.22,pp.336-339
[33]张峰,40Gb/s 长距离传输及信号处理关键技术的研究,北京交通大学博士论文,2008.
[1]简水生,数字信息安全网是人类进一步改变生活方式,工作方式,学习方式的根本保证,数字通信世界,2005,vol.1,pp10-10.
[2]简水生,“光纤网的发展与机遇”,中国电子商情:通信市场,no.11,2001,pp.13-18.
[3]简水生,新一代、高度安全、超大容量、无阻塞全光网是信息社会的基础,光通信,2003,vol.12,pp.14-21.
[4]"GENI:global environment for network innovations," http://www.geni.net/
[5]"FIND:future Internet network design," http://find.isi.edu/
[6]Feng Zhang,Yong Chen,Jihong Cao,Xi Qin,Shuisheng Jian.Novel Optical Fiber Self-healing Network Based on Wavelength Routing of Fiber Gratings.APOC2006.
[7]C.Ming,Z.Feng,Q.Xi,C.Yong,C.Jihong,L.Bo,,L.Dan,and J.Shuisheng,The implementation of multicast in wavelength routing optical network based on chirped fiber gratings,Journal of Optoelectronics.laser,2008,vol.19,pp.331-334.
[8]Bo Lv,Xiangqiao Mao,Feng Zhang,Optimization of multicast optical networks with genetic algorithm,APOC2007,2007.
[9]卢丹,曹继红,秦曦,张峰,吕博,陈明,简水生,支持全光组播OXC的研究与实现,光通信技术,2007,vol.31,pp.41-44.
[10]陈勇,全光通信网关键技术的研究与实现,博士学位论文.北京:北京交通大学,2006.
[11]“关于下一代网络体系结构”,http://sj.media.edu.cn/
[12]Chen Yong,Chen Genxiang,Cao Jihong,Jian Shuisheng,Novel wavelength-routing All-Fiber WDMNetwork:Implementation and Optimization,Proceedings of SPIE,2004,vol.5626,pp.1382-1389.
[13]张峰,陈勇,曹继红,秦曦,简水生.一种基于光纤光栅实现波长路由的光纤自愈网,光学技术,2007,vol.33,pp.173-176.
[14]曹继红,高速超长距离传输系统及新型光路交换网的研究,博士学位论文.北京:北京交通大学,2007.
[15]简水生,建立“新一代、高度安全、超大容量、无阻塞全光网”是我国本世纪初叶重大科学战略工程,网络电信,2003,no.11,pp.16-21.
[16]Liu Yan,Chen Yong,Tan Zhongwei,Cao Jihong,Zheng Kai,Ning Tigang,Chen Ting,Dong Xiaowei,Jian Shuisheng,Performance of a 10Gbit/s Transmission system over 1500km G.652Fiber Compensated by Cascaded narrow-Band Chirped Fiber Bragg Gratings,Chinese Physics Letters,2005,vol.22,pp.1944-1947.
[17]曹继红,陈勇,简水生,基于线性啁啾光纤光栅色散补偿的2500km 10Gb/s无电中继传输系统,光电工程,2006,vol.33,pp.101-105.
[18]张杰等,自动交换光网络ASON.北京:人民邮电出版社,2004.
[19]颀畹仪等编,光传送网.北京:机械工业出版社,2003.
[20]Feng Zhang,Yong Chen,Jihong Cao,Xi Qin,Shuisheng Jian.Novel Optical Fiber Self-healing Network Based on Wavelength Routing of Fiber Gratings.APOC2006.
[21]龚倩,光网络的组网与优化设计.北京:北京邮电大学出版社,2002.
[22]简水生,通信由电到光的革命兼论绿色能源革命(节选),光通信,2006,vol.12,pp.22-24.
[23]T.H.Noh,End-to-end self-healing SDH/ATM networks,Global Telecommunications Conference 1996,vol.4,pp.1877-1881.
[24]W.Xing,L.Xiang,and C.Xu,numerical simulation of the SPM penalty in a 10-Gb/s RZ-DPSK system,Photonics Technology letters,IEEE,2003,vol.15,pp 1636-1638.
[25]H.Keang Po and W.His-Cheng,Comparison of nonlinear phase noise and intrachannel four-wave mixing for RZ-DPSK signals in dispersive transmission systems,Photonics Technology letters,IEEE,2005,vol.17,pp.1426.
[26]D.van den Borne,V.Veljanovski,U.Gaubatz,C.Paquet,Y.Painchaud,E.Gottwald,G.D.Khole,and H.de waardt,42.8 Gb/s RZ-DQPSK Transmission with FBG-Based In-Line Dispersion Compensation,Photonics Technology letters,IEEE,2007,vol.19,pp.1069-1071.
[27]Y.Yano,T.Ono,K.Fukuchi,T.Ito,H.Yamazaki,M.Yamaguchi,and k.Emura,2.6 terabit/s WDM transmission experiment using optical duobinary coding,European Conference on Optical Communication,ECOC,1996.
[28]D.Penninckx,M.Chbat,L.Pierre,and J.P.Thiery,Phase-shaped binary transmission(PSBT):A new technique to transmit far beyond the chromatic dispersion limit,European Conference on Optical Communication,ECOC,1996.
[29]A.matsuura,k.Yonenaga,Y.Miyamoto,A.Sano,H.Toba,and M.Yoneyama,High power tolerant optical duobinary signal transmission,IEICE Transactions on Communications,2001,vol.,E85-B,pp.1173-1178.
[30]张铭等,OPNET Modeler与网络仿真.北京:人民邮电出版社,2007.
[31]F.Tillerot,E.Didelet,A.Daviaud,and G.Claveau,Efficient network upgrade based on a WDM optical layer with automatic protection switching,Optical Fiber Communications Conference,1998,pp.296-297.
[32]黄照祥,黄永清,张阳安,李玲,任晓敏,智能光网络中的光通道性能监测技术及其应用,现代有线传输,2005,no.1,pp.59-62.
[33]Frigo N.J.,Iannone P.P.,Reichmann K.C.,Xiang Zhou,Stodden,M.W.,Centralized In-Service OTDR Testing in a CWDM Business Access Network,Journal of Lightwave Technology,,IEEE,2004,vol.22,pp.2641-2652.
[34]Tsong-Ho Wu,Emerging technologies for fiber network survivability,Communication Magazine,1995,vol.33,pp.62-74.
[35]Luby J.F,Survivability of the public switched network integration of market,switching,transmission and OA&M considerations in network design,Switching Sympsion.1990,vol.4,pp.169-172.
[36]Satoru Okumato,Photonic Transport Network Architectureand OA&M Technologies to Create Large-Scale Robust Networks,Journal of Selected Areas Communication,IEEE,1998,vol.16,pp.995-1007.
[37]Singhal N.K,Sahasrabuddhe L.H.,Mukherje B,Optimal Multicasting of Multiple Light-Trees of Different Bandwidth Granularities in a WDM Mesh Network With Sparse Splitting Capabilities,IEEE/ACM Transcation Network,2006,vol.14,pp.1104-1117.