Hi If you fire up a conventional 1 pps loop with 10 ppb tune range, it's going to take it a while to track out any initial error. The most it can move by is +/-5 ns per second. You probably don't want to wait a year for it to catch up with a 158 ms initial error.
Lots of fun little details to worry about managing.... Bob -----Original Message----- From: [email protected] [mailto:[email protected]] On Behalf Of WarrenS Sent: Thursday, January 14, 2010 4:52 PM To: Discussion of precise time and frequency Subject: [time-nuts] GPSDO Design John ask >Translating nV/sqrt(Hz) to something >practical is basically the assistance I'm looking for here. >I would appreciate anyone being able to teach me a bit more about this. If that is ALL you want to know, That's easy and quick. For this application sounds like you already know ALL you need to know about that, nothing. Putting a 1 sec or so RC filter at the EFC input, takes care of all that AND if you want it even better, and to get the long Control loop time constants needed, JUST reduce the (loop) gain, don't need no BIG caps. That is attenuate the output of the control amp by typically a hundred to a thousand instead of multiplying by 1.6 and add a fixed, adjustable, stable, offset source. (electrical or mechanical) The Buffer amp is not going to be your problem. ws ************ [time-nuts] GPSDO Design John Foege john.foege at gmail.com Hi All, Quick question for the more experienced members here with GPSDO design/operation. Let's assume I'm using a 4096 phase comparator chip followed by some kind of long time constant lowpass loop filter, whether it be analog or digital, is not of concern for the following question. Obviously using a 74HCT4096 would mean that my EFC voltage range would be approx. 0-5V. If I wanted to use an OCXO with say a 0-8V EFC voltage range, then I would be inclined to simply use an op-amp amplifier with a gain of 1.6 to scale the EFC voltage accordingly. But not just any op-amp would do I take it? High-speed would of course be of no concern. Also low-offset would be of little concern, as the PLL would work to correct this, and it therefore seems to be negligible. However, the part that's got me thinking is noise. Obviously any noise at the ouput of the amp would adversely affect the frequency stability of the OCXO. I thought the best way to control this would be to use an extremely low noise op-amp employing a rather large compensation cap to give me a rather small bandwidth, perhaps only a few hundred hertz. Anyone have experience with this? Assuming I have an OXCO with a max. pulling range of 1ppm or 1e-6 over a 10V range, then I effectively can pull 1e-7 per volt. This translates to 1e-10 per millivolt and 1e-13 per microvolt. Assuming that is a logical conclusion, then for a good OCXO, in which I can at best hope for 5e-12 stability for tau=1s (e.g. HP10811A), I would strive to to keep the noise at such a level that it is an order of magnitude better than the best short term stability figure. Accordingly, then I should shoot to keep any noise under 1 microvolt? I don't have much experience with noise calculations. I know it is specified in nV/sqrt(Hz) generally. Translating this to something practical is basically the assistance I'm looking for here. I would appreciate anyone being able to teach me a bit more about this. Thank you in all in advance. Sincerely, John Foege ************** _______________________________________________ time-nuts mailing list -- [email protected] To unsubscribe, go to https://www.febo.com/cgi-bin/mailman/listinfo/time-nuts and follow the instructions there. _______________________________________________ time-nuts mailing list -- [email protected] To unsubscribe, go to https://www.febo.com/cgi-bin/mailman/listinfo/time-nuts and follow the instructions there.
