Stephan Sandenbergh wrote: > Hi Bruce, > > > > You mentioned that locking to a crystal at the receiving end as an option. > Does this mean that signal transmission is primarily plagued by short term > noise? > > I have never really touched the topic of optical fibre, but I realise that > it is superior to conventional methods. The superiority of optic fibre is > probably not as pronounced at short distances, is it? > > > > Kind regards, > > Stephan Sandenbergh > > > > _______________________________________________ > time-nuts mailing list > time-nuts@febo.com > https://www.febo.com/cgi-bin/mailman/listinfo/time-nuts > > Stephan
Distribution of clock frequencies via optical fibre (at least at low optical power levels) is indeed limited by white phase noise in the receivers for short averaging times. For long averaging times the instability (white frequency noise etc.) of the clock source will manifest itself. Thus it can be advantageous to phase lock a low noise crystal oscillator to the received signal to cleanup the the received frequency. Optical frequency combs are sometimes used to distribute microwave frequencies via an optical fibre. In this case the photodetector (sensitive to the incident optical power) also acts as a mixer and its output will contain a frequency component at the difference frequency between adjacent comb signal frequency components. For short distances well screened coax is easier to use. Fibre offers a lower propagation delay tempco which may be important if the cable/fibre temperatures varies significantly. However the cost of the fibre transmitter, receiver and fibre may be relatively high compared to the cost of a piece of coax plus a driver and receiver for short distances. Bruce _______________________________________________ time-nuts mailing list time-nuts@febo.com https://www.febo.com/cgi-bin/mailman/listinfo/time-nuts