210 km repeaterless 10 Gb/s transmission experiment through nondispersion-shifted fiber using partial response scheme
- 1 October 1995
- journal article
- Published by Institute of Electrical and Electronics Engineers (IEEE) in IEEE Photonics Technology Letters
- Vol. 7 (10) , 1219-1221
- https://doi.org/10.1109/68.466596
Abstract
In order to increase the dispersion-limited propagation distance at 10 Gb/s through nondispersion-shifted fiber, a chromatic dispersion tolerant signalling technique is used, based upon a reduced optical signal bandwidth. We have achieved a 210 km repeaterless transmission distance at 10 Gb/s over nondispersion-shifted fiber with a measured bit error ratio lower than 10/sup -12/. At this distance, a receiver penalty of 1.7 dB was obtained at 10/sup -10/ bit-error ratio, while an almost penalty-free transmission has been performed through 189 km. The technique relaxes the bandwidth requirements for the optoelectronic components at the transmitter level and involves a standard 10 Gb/s receiver at the output end of the transmission link.Keywords
This publication has 8 references indexed in Scilit:
- Impact Of Self-phase Modulation On 10-Gb/s Systems Using Conventional Single-mode FiberPublished by Institute of Electrical and Electronics Engineers (IEEE) ,2005
- Reduced bandwidth optical digital intensity modulationwith improvedchromatic dispersion toleranceElectronics Letters, 1995
- 10 Gbit/s, 300 km repeaterless transmissionwith SBS suppression by the use of the RZ formatElectronics Letters, 1994
- Extended 10 Gb/s fiber transmission distance at 1538 nm using a duobinary receiverIEEE Photonics Technology Letters, 1994
- 10 Gbit/s unrepeatered three-level optical transmission over 100 km of standard fibreElectronics Letters, 1993
- Repeaterless optical transmission at 10 Gbit/s via 182 km of standard singlemode fibre using a high power booster amplifierElectronics Letters, 1993
- 252 km repeaterless 10 Gb/s transmission demonstrationIEEE Photonics Technology Letters, 1993
- All-Optical, Fiber-Based 1550 nm Dispersion Compensation in a 10 Gbit/s, 150 km Transmission Experiment over 1310 nm Optimized FiberPublished by Optica Publishing Group ,1992