Optical RZ signal straight-line transmission experiments with dispersion compensation over 5520 km at 20 Gbit/s and 2160 km at 2 × 20 Gbit/s

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Optical RZ signal straight-line transmission experiments with dispersion compensation over 5520 km at 20 Gbit/s and 2160 km at 2 × 20 Gbit/s

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Through optimisation of a dispersion compensation ratio to balance the effects of timing jitter and waveform distortion, single-channel and two-WDM-channel 20 Gbit/s RZ signals are successfully transmitted over 5520 and 2160 km, respectively, in the anomalous dispersion region.

Inspec keywords: jitter; digital communication; wavelength division multiplexing; compensation; optical fibre dispersion; optical fibre communication

Other keywords: 20 Gbit/s; anomalous dispersion region; optical RZ signal; single-channel transmission; dispersion compensation; 5520 km; 2160 km; waveform distortion; timing jitter; two-WDM-channel transmission; straight-line transmission experiments

Subjects: Optical communication

References

    1. 1)
      • Edagawa, N., Morita, I., Suzuki, M., Yamamoto, S., Taga, H., Akiba, S.: `20 Gbit/s, 8100 km straight line single channel soliton based RZ transmissionexperiment using periodic dispersion compensation', Th.A. 3.5, ECOC'95, 17–21 September 1995, Brussels.
    2. 2)
      • M. Nakazawa , H. Kubota , K. Tamaura . Nonlinear pulse transmission through a optical fibre at zero-averagegroup velocity dispersion. IEEE Photonics Technol. Lett. , 3 , 452 - 454
    3. 3)
      • W. Forysiak , K.J. Blow , N.J. Doran . Reduction of Gordon-Haus jitter by post-transmission dispersion compensation. Electron. Lett. , 13 , 1225 - 1226
    4. 4)
      • Suzuki, K., Iwatsuki, K., Nishi, S.: `Optical filtering technique for suppressing nonlinear pulse distortioncaused by long transmission distance', FB3, OAA '95, 15–17 June 1995, Davos.
    5. 5)
      • K. Sato , I. Kotaka , K. Wakita , Y. Kondo , M. Yamamoto . Strained-InGaAsP MQW electroabsorption modulator integrated DFB laser. Electron. Lett. , 12 , 1087 - 1089
    6. 6)
      • K. Suzuki , K. Iwatsuki , S. Nishi , M. Saruwatari . 160 Gbit/s subpicosecond transform-limited pulse signal generation utilisingadiabatic soliton compression and optical time-division multiplexing. IEEE Photon. Technol. Lett. , 3 , 352 - 354
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