Hi cdev,
I've been preoccupied with my latest addition, an Efratom LPRO-101, this past week so only spotted your post just now. That article on testing unknown OCXOs by Bob offers good advice but there is one worrying aspect of it concerning the choice of Vcc/Vdd voltage where he suggests you just blunder in directly with a 12v Vdd voltage. If he's talking about an OCXO for which there's seemingly no published datasheet to provide any firm guidance on the required voltage (and this seems to be the case), you could land up applying 12v to a 5v part which is guaranteed to make said 5v part instantly emit its 'magic smoke'.
This was exactly the situation I was facing just over 18 months ago with my very first (one and only) 13MHz CQE OCXO. Although it was a dead ringer for a 13MHz Vectron (the only datasheet I could download for any guidance), I was still unsure about risking 12v on what may have possibly been a 5v part (it looked like NOS rather than a carefully extracted OCXO removed from a decades old PCB where 12v was the most common Vdd specification).
I wasn't prepared to take any risk of 'smoking my 4 quid radioham rally bargain' with a 12v jolt so tested it on a 5v supply which proved sufficient for it to start outputting a 3v p-p square wave after about 10 to 20 seconds delay (it turned out that the voltage regulation with load of the humble 1117-5 is rather crap - I was actually only getting 4.82v at the 280mA (current limited) warm up loading upon the cheap LDO used on the solder-less breadboard power adaptor board).
After an 8 minute warm up time, the frequency settled down to 13MHz exactly and the current had dropped to 180mA. Using a potentiometer across the Vcc to supply a tuning voltage to the EFC pin proved it could be electrically tuned and thus a candidate for my GPSDO experiments (I'd already figured out a way to generate a 10MHz output locked precisely to a 13MHz square wave).
I tried powering it from a 6.9v rail (half of the 13.8v smpsu made up with a pair of 5v 10A Farnell switchers in series modified to output 6.9v each), monitoring the square wave output voltage which had shot up to 6v p-p. I decided to risk another volt's worth using a charged up NiCad in series (I didn't possess a 32V 10A max variable bench supply back then - I do now
) and saw the output had risen by yet another volt strongly hinting that the oscillator/buffer was seeing the full Vdd voltage rather than the 5v of an internal LDO which would be mandated by a 12v design.
I'd spotted a trend whereby I could expect to see a 10 or 11 volt p-p output off a 12v Vdd, assuming no loss of magic smoke, an output voltage I'd never ever seen specced by any of the many OCXO datasheets I'd perused so decided it was best to play safe and assume for the time being that it actually was a 5v part (after all, on a 5.2v supply, it was outputting a 4v p-p square wave within seconds of applying power and functioned exactly as an OCXO would be expected to behave. The only hint that it may have been a 12v part - the now slightly less protracted 7.5 minutes warm up time, wasn't strong enough evidence at the time to risk destroying my one and only OCXO to date.
One advantage in assuming a Vcc of 5v being the simplification of the power rails in my MK I GPSDO down to just a single 5.17v. The protracted 7 minutes or so warmup was no impediment since it meant less overshoot when it finally did get up to temperature - you really need at least half an hour either way for an OCXO to be reasonably settled down before the GPS stops chasing a moving target.
By the time I had more evidence of it being a 12v part ( a bunch of 10MHz sine output CQE OCXOs of exactly the same form factor and pin out I'd fortuitously chanced upon as a result of a continued fruitless search for a datasheet) by virtue of having enough spare 10MHz CQE OCXOs to risk blowing one up for just a modest 6 quid investment which revealed the exact same 280mA warm up current which, at 12v, dropped to just 90mA to give an identical warmed up power consumption of around 900mW, I'd already settled on a single 5.2v rail design, devoid of the need of another DC boost converter or the need to tie the power supply to a 12v only option in place of the 7 to 24 v requirement allowed by the buck converter I was using for the single 5.2v rail.
Apart from the protracted warm up time, that 13MHz OCXO worked just fine in my MK I GPSDO (essentially a variant of the excellent James Miller design). I only retested that OCXO with a 12v rail less than a fortnight ago after I had successfully commissioned and proved my MK II variant as its replacement, proving what I had long suspected that it had been a 12v OCXO all along - still, better safe than sorry.
It had served me well as an ersatz 5v OCXO these past 6 months or so. Now it can serve as a memento of my first experimental efforts at designing and building a GPSDO - I doubt I'll find another use for it.
Anyhow, for anyone checking out their very first and only OCXO for which they have no absolute and incontrovertible evidence as to its actual voltage requirement, rather than plunge straight in with a 12v supply as Bob suggested (not a problem if you've bought a job lot dirt cheap), try a 5 or 6 volt supply to start with and monitor the Vref pin to check whether it stabilises at either 3.3 or 5 volts (the more ancient 12v OCXOs may have oddball 6 or 7 volt reference voltages). A 3,3v reference would strongly hint at a 5v OCXO whereas a 5v reference would suggest a 12v unit (that 13MHz CQE didn't stabilise at its 5.1xx volt set point until Vdd had hit the 11 volt mark).
Unfortunately, checking the Vref pin (if it has one - why would you even bother with an OCXO if it doesn't have a Vref pin?) isn't a reliable indicator - some OCXO's with a "Vref pin" are no better than those without by virtue of it not being connected to anything, hence the advice to monitor the output pin to look for it reaching a fixed p-p limit as the test voltage is ramped up.
Also, though I didn't appreciate it at the time, if the output takes 15 to 20 seconds or more to stabilise into a recognisable waveform on a 5v supply but appears much quicker off a 6v supply (2 or 3 seconds), that's a pretty good indicator that it's more likely a 12 rather than a 5 volt part. This was a more obvious indicator that the 10MHz units weren't 5 volt parts - they did eventually stabilise at a 3v p-p sine output after a 20 or so seconds delay on a 5.2v supply (slower than the 13MHz unit had done on a 4.82 volt supply - hence my doubt as to it being a 12v part).
A variable bench supply (which I didn't have when I was first trying to determine that 13MHz OCXO's voltage requirement) is a very useful tool in this case. Although the accuracy of their built in voltage and current meters (particularly the current meter) leave something to be desired in the cheaper (affordable) Chinese models, they're still good enough to indicate unexpected behaviour perhaps just in time to terminate the test before lasting damage has occurred.
However, a better strategy is to monitor the current demand at a 5.5 or 6 volt setting and wait for the warm up current to drop to a lower steady reading after maybe as long as 10 minutes if the part is a 12v one. The heater current is normally a constant current during the warm up phase so you can reconfigure the current limit setting on your bench supply to somewhere between the heating up current and the settled at temperature current and restart the test, allowing the current to stabilise at its set point temperature before increasing the voltage in small increments, looking for any departures from the expected small reductions in heater current demand to compensate for the voltage increase to maintain the steady energy consumption required to hold a constant oven temperature, not forgetting to monitor the clues provided by the Vref pin and the p-p output voltage level.
If you keep in mind that the absolute maximum allowed supply voltage stress of 7 volts typically quoted in datasheets for 5v parts, if you reach the 8v mark with no obvious symptoms of distress being shown, then it's almost certain you're dealing with a 12v OCXO where you can use one volt increments to reach a 12v target. Once you're confident you're testing a 12v part, you can 'ice the cake' with a 13.2v test to definitely confirm this (standard voltage tolerance for 12v parts being +/-10% - I took the test voltage on my 13MHz OCXO right up to 14v for good measure: I was curious and had no foreseeable use for it so wasn't concerned as to whether this would prove to be 800mV too many).
JBG
Home
Help
Search
Login
Register
