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- Acknowledgments We acknowledge funding support from the Ministère de la Recherche and European Space Agency/ESOC. References
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4. Conclusion.
We have demonstrated an 86-km compensated optical link using an urban telecom network with a frequency instability of 1.3×10 -15 at 1 s and below 10 -18 after one day of integration time. These results were obtained due to the use of two slightly different modulation frequencies for the two different propagation directions, the scrambling of the light polarization state and the compensation of the fiber chromatic dispersion. The ultimate limitation of the compensator itself is reached and can not be overcome easily. The stability of the present system enables comparison of the best frequency standards, both in the microwave and optical region, over distances of up to 100 km. For longer distances, attenuation along the fiber is a crucial limitation. Optical amplifiers, which limit the frequency instability at a level slightly below 10 -14 at 1 GHz, have a negligible effect at 10 GHz and can be used to recover a sufficient signal to noise ratio for distances up to about 200 km. 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