It took me a little while to dig them out (it was about 2 years ago when I bought them).
They are 12V ones (which is stated on the data sheet).
I connected one up as can be seen in the attached pictures - I didn't allow much time for warming up and anyway my counter is in use currently as I'm trying to do some long term ADEV measurements.
The counter on my scope normally reads a little low (it reads 9.99998 MHz at 10MHz) so the frequency is a bit high (reading exactly 13MHz) when it should be a bit low normally with VC not set but as I say, I didn't allow any warm up.
I did check them when I got them.
The control should be between +/-1000 to +/-3000 ppb with the control voltage being between 0 and 10V so it should be changing between 13 and 39 Hz and unfortunately my scope counter is only six digits so doesn't quite extend far enough.
EDIT: I should have added that the voltage is only 2.2V because I'm loading it with 50 ohms - it is above 6V on 10Mohm setting but the waveform is rather ugly. The best load I guess is 600 ohms or so but this was just a quick demo to give you some info.
Thanks JPB.
The data sheet obviously matches those OCXOs of yours but I'm not so sure it's an exact match to mine. It looks like the one I got must be a later 5 volt version - the rest of the info, pin out and dimensions (width typo excepted) matches but not the tuning voltage spec unless my unit is indeed a 12 volt unit that freakishly also manages to work from as low a voltage as 4.79 volts (perilously close to the lower 5% tolerance limit for a 5 volt part).
====snip====
The best I can hope for is for someone who has been running a seemingly identical OCXO off a 12v supply for months or even years, to decide, purely out of curiosity you understand, to test them with a 5 volt supply to see whether they'll display the same or similar behaviour as my particular (peculiar?) example. 
Apropos of those ultra low power (by the conventional standard of OCXOs) 16.384MHz clock OCXOs, nice as that is, ultra low power is at the bottom of my list of priorities in my current GPSDO project. I only mentioned the relatively modest power requirement of that 13MHz bargain buy on account of the possibility of now being able to use a 10MHz example in my Feeltech FY6600 without having to add a second dedicated PSU board as would have been required to power a 12v 3W (warmup demand current rating) OCXO module which complication led me to choose that 0.1ppm 50MHz clock power module as a low power requirement compromise between the existing low quality smd XO chip and the ultimate in OCXO accuracy and stability.
====snip====
Now I'm getting 5.31 to 5.39 volts depending on how hot the regulator chip gets - much better to be on the high side than on the low side - less waste heat in the LDO regulator for a start and I now see a 13MHz output (initially slightly off frequency of course!) within seconds of powering it up. This is more like it!
Almost instant, though slightly off frequency, output followed by the warm up phase onto frequency more typical of normal OCXO startup behaviour. I guess my NOS example must be far less ancient than that 1997 data sheet would imply after all.
JBG
Further developments in my cheap OCXO saga: I've more or less determined that my bargain of the century 13MHz OCXO acquisition last month is in fact a 5 volt part after all. Disappointingly, those 10MHz versions that I was alluding to turned out to be 12 volt parts (they were identical in appearance to my 13MHz example but as everyone knows, looks can be deceiving).
One of the results of my search for a definitive data sheet for that 13MHz OCXO was the discovery of a very cheap source of 10MHz versions of this CQE branded OCXO from a UK supplier who, unbelievably, CBA to test them or track down a data sheet so was selling them off for a mere £4.99 each (plus £2.00 P&P one off or £1.0 per additional unit on a multiple order), claiming them to be unused NOS.
<https://www.ebay.co.uk/itm/CQE-CRYSTAL-OSCILLATOR-10MHz-REDUCED-TO-CLEAR/253081992039?hash=item3aecdcbb67:g:x1gAAOSw~qNZh2rl>
<https://tinyurl.com/y6pl2xvk>
At the time, I'd already ordered a set of three and was waiting on their delivery. I didn't want to mention this source for fear of him being inundated with orders and the stock drying up. Those first three cost me 4 quid in postage but I didn't want to order a "Lifetimes's Supply" in one go just to save a couple of quid in case they turned out to be not such a wise investment after all. As it turned out, all three performed just fine although I was a little suspicious about the claim for them being unused NOS (the pins didn't seem to be quite as pristine looking as my initial 13MHz rally purchase).
Since I now had a 10MHz OCXO plus a couple of spares, after testing them out on a 5.33v supply and discovering after several minutes delay a 10MHz 600mVpp sine wave output finally putting in an appearance, I decided it would be well worth the risk of applying 12 volts to the Vdd pin to prove my, by then, very strong suspicion that these were the more usual 12 volt parts. The risk taken paid off handsomely. I've also been able to ascertain that, apart from an ac coupled 4Vpp sine wave output, the 13MHz Vectron data sheet I posted pretty much applies to these 10MHz CQE branded clones (including the 0 to 10 volt tuning range with positive sense).
Once I had satisfied myself as to the worth of ordering more of these OCXOs, I placed an order for another four to secure myself a bargain basement lifetime supply. I've since used one of them (with a NB3N502 clock multiplier chip) to upgrade the TCXO upgrade to my FY6600's original 50MHz SMD XO chip. Of course, this involved adding a 12v 300mA smpsu (extracted innards from a wallwart) to power the OCXO board - the existing +12v rail has insufficient reserve to handle such abuse.
However, the nice thing about this extra psu complication that I'd initially hoped to avoid is that I can shut the generator off rather than just put it into standby to keep the OCXO up to temperature since its smpsu is wired directly to the IEC C6 mains inlet socket to stay powered up whilst it remains plugged into a mains supply (it only takes 1.3W once up to temperature). Placing the generator into standby only drops the consumption from circa 7 to 9.7 watts down to 5 watts (plus the 1.3W of the OCXO), so I gain an advantage from my pain of adding a second smpsu to the box as well as a very slight reduction in the loading on the original 3 rail smpsu board. What's not to like about a mod like this?
Incidentally, my suspicions about these 10MHz CQE OCXOs being unused NOS were confirmed when I received the last four units. A couple of them had the remnants of a through plated hole on a pin each disproving the 'unused NOS' claim. However, since they tested good with tuning voltage settings for exactly their 10MHz frequency ranging from a low of 2.32 to a high of 4.51 volts out of a 0 to 10 volt tuning range, at a penny shy of a fiver each, I could hardly complain at this modest bit of mendacity on the part of the seller.
However, I can certainly question the need to mislead. The question in this case being why he felt the need to disguise the fact of them being used items at the price he was asking in the first place when such readily evident mendacity could only undermine his credibility. Still, at least you can be on your guard over this aspect of their condition if you decide to take a chance on such a cheap and local (for UK citizens at least) source of 10MHz OCXOs.
I still have to lash my GPS up to one of these OCXOs to create a GPSDO better suited to calibrating the FY6600's OCXO upgrade but I thought it best to apply the OCXO upgrade to the FY6600 first before sorting the GPSDO project out since its enhanced frequency stability over the initial TCXO upgrade makes it an even more useful test tool for the next stages in this project.
Another contributor to the FY6600 thread, 'Arthur Dent', had added a 10MHz OCXO with a NB3N502 clock multiplier chip to his FY6600 over a year ago and included an external 10MHz reference socket with a change over switch. I plan to do almost the same modification but without the complication of a change over switch.
I recently spotted a reference to the use of injection locking a Wien bridge oscillator (very low harmonic distortion and spurious free sine wave oscillator) to a high stability XO and discovered literature on the use of such injection locking being used to synchronise XOs although I couldn't find any examples of the technique being applied to real world OCXOs.
However, as far as I can see, it shouldn't be too difficult to injection lock a free running OCXO to an external reference source that's within 1ppb of its frequency. In my case, I'd expect my OCXO to be well within half a part per billion so quite amenable to this technique of getting it to lock into sync with an external 10MHz GPSDO reference without the need for a change over switch or the risk of any 'hand over glitches' that may crash the FY6600's FPGA logic during such transitions back and forth between its internal and external 10MHz reference sources (and fall back gracefully onto its internal source should the external reference fail unexpectedly for any reason whatsoever).
I started a new thread yesterday called " Injection locking the 10Mhz OCXO to external reference (upgrading a FY6600)" but so far haven't had any takers despite my two attached photos having been viewed 14 and 13 times. It rather looks like I'll have to run my own experiments to find the best method of injection locking the internal TCXO to the 10MHz external source.
Mention of those photos reminds me that it would be worth attaching them here for a bit of light entertainment. The first will be obvious but the second needs an explanation. Basically, out of frustration with having to make do with just the raw 10MHz PPS output as a calibration reference with all the non integer divisor induced jitter as well as the distracting effect of the sawtooth corrections applied by the GPS module to keep synced with GPS time, I made up a crude crystal and resistor filter using a couple of 10MHz crystals I'd bought at that radio ham rally last month to try and filter out the worst of the jitter on the raw PPS output.
Rather surprisingly, it worked better than I'd had any right to expect. The picture shows the setup with just sufficient resolution to reveal the details and the effect on the scope traces. However, the still image can't convey the ever present though very toned down sawtooth effect which is now less of a jitter and more a swaying effect. It makes it just that little bit easier to adjust the OCXO to within 100ppt.
However, since it is a direct output from the GPS's PPS line, it does suffer from variations in phase as reflected by the deviation map plot variations of +/-3 or 4 metres in the u-centre app which equates to some +/- 10 to 12ns phase shifts which makes trying to calibrate an OCXO to within 50ppt rather problematical (also, the sawtooth doesn't help either). As things stand right now, it's largely a matter of luck getting the OCXO tighter than 50ppt. I need a GPSDO source before I can do any better and get a more accurate idea of the ageing drift rate of these OCXOs. Hopefully, it won't be much longer before I finally get my GPSDO project completed sufficiently enough to properly calibrate and check these OCXOs but for now, I'm having to make do with a filtered 10MHz PPS signal.
JBG
Home
Help
Search
Login
Register
