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The Transmission Performance of Non-zero Dispersion Shifted Fiber Communication Systems Using In-line Phase-sensitive Amplifiers 被引量:6

The Transmission Performance of Non-zero Dispersion Shifted Fiber Communication Systems Using In-line Phase-sensitive Amplifiers
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摘要 This paper focuses on the non zero dispersion shifted fiber optical transmission system which employs cascaded in line Phase sensitive Amplifiers ( PSAs ). By computer simulation, we have revealed that the eye penalty of high speed signal pulses increases with the accretion of dispersion and the transmission distance limited by Intersymbol Interference ( ISI ) of signals varies with the spacing and average output power of amplifiers for positive and negative fiber dispersion. The analysis shows that although PSA can compensate for both positive and negative dispersion, it is only valid for small dispersion coefficient fiber. Owing to the effect of Self phase modulation ( SPM ), the ISI limited transmission distance of positive dispersion fiber is much longer than that of negative dispersion fiber. In addition, for positive fiber dispersion, there is an optimum value of average output signal power from PSA leading to the longest ISI limited transmission distance. This paper focuses on the non zero dispersion shifted fiber optical transmission system which employs cascaded in line Phase sensitive Amplifiers ( PSAs ). By computer simulation, we have revealed that the eye penalty of high speed signal pulses increases with the accretion of dispersion and the transmission distance limited by Intersymbol Interference ( ISI ) of signals varies with the spacing and average output power of amplifiers for positive and negative fiber dispersion. The analysis shows that although PSA can compensate for both positive and negative dispersion, it is only valid for small dispersion coefficient fiber. Owing to the effect of Self phase modulation ( SPM ), the ISI limited transmission distance of positive dispersion fiber is much longer than that of negative dispersion fiber. In addition, for positive fiber dispersion, there is an optimum value of average output signal power from PSA leading to the longest ISI limited transmission distance.
作者 LINHong-rong CHENRu-quan
机构地区 DepartmentoifCommunicationEngineering DepartmentoifCommunicationEngineering
出处 《The Journal of China Universities of Posts and Telecommunications》 EI CSCD 2001年第2期5-10,共6页 中国邮电高校学报(英文版)
基金 SupportedbytheNaturalScienceFoundationofJiangsuProvince
关键词 phase sensitive amplifier group velocity dispersion dispersion compensation ISI limited distance phase sensitive amplifier group velocity dispersion dispersion compensation ISI limited distance
分类号 TN929.11 [电子电信—通信与信息系统]
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参考文献11

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同被引文献47

  • 1林洪榕,钱胜,杨爱霞,李跃辉.光纤色散参量对光孤子系统传输性能的影响[J].光学学报,2004,24(9):1274-1278. 被引量:4
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  • 6[5]LI R D, KUMAR P, KATH W L. Dispersion compensation with phase-sensitive optical amplifiers[J]. J Lightwave Technol, 1994, 12(3): 541- 549.
  • 7[6]IMAJUKU W, TAKADA A. Theoretical analysis of system limitation for AM-DD/NRZ optical transmission systems using in-line phase-sensitive amplifiers[J]. J Lightwave Tech:nol, 1998, 16(7): 1158- 1170.
  • 8[8]DEUTSCH I H, ABRAM I. Reduction of quantum noise in soliton propagation by phase-sensitive linear amplifiers[J].J Opt Soc Am B, 1994, 11(3): 2303- 2313.
  • 9[9]MECOZZI A, TOMBESI P. Parametric amplification and signal-to-noise ration in optical transmission lines [J ]. Opt Commum, 1995, 75(3): 256-262.
  • 10[10]YUEN H. Reduction of quantum fluctuation and suppression of the Gordon-Haus effect with phase-sensitive linear amplifiers[J]. Opt Lett, 1992, 17(1): 73-75.

引证文献6

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The Journal of China Universities of Posts and Telecommunications
2001年 第2期

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