In trying to put together more references in my lab, I've also been looking at these.
How much stability is to be expected from these? I am assuming one positive aspect is those available on the marketplaces out there are probably well aged.
That said, the PCB design is very vanilla, with no cutouts, etc.
In case these are worthy to chase, there's then the issue of cleanly supplying them, putting them in an optimal case, etc. Has anyone taken on a project like this before?
Thank you.
Hello Rax,
to my knowledge, nobody has used these expensive HP3458A boards as an external, standalone reference.
That makes no sense at all, as these have many disadvantages, and even design flaws.
First, the LTZ1000A is misused by hp engineers, as it's running on about 90..95°C oven temperature. That's necessary because the 3458A is intended as an industry environment DMM, not as a metrology instrument, i.e. it is specified to run up to 55°C.
As a proper reference, the oven temperature must not be higher than 60°C; the Datron / Wavetek / Fluke 7001 (designed by John R. Pickering) uses 45..50°C instead, like all other oven based references from Fluke, i.e. the 732's. I also have designed my references like this, i.e. @ 45 ... 55°C.
That gives a drift rate from scratch (w/o elaborate pre-aging) of < 1ppm/year, typically -0.5ppm/y.
References boards from hp commonly age -4 .. 8ppm/y, see also the threads about the 34470A and its reference board.
Only the high stability option is tested to -2ppm/y. Waste of money, to my opinion.
As a stand-alone reference, you urgently need a buffer circuit, to protect the LTZ1000 reference from short circuits, which would shift the reference voltage.
As well you can use this buffer to create a reasonably stable 10V output.
HP designed several other errors into the circuit, especially they still assemble this 200k resistor , which should NOT be used on the A version of the LTZ1000, as it creates an unwanted T.C. of about 0.3ppm/K. W/o that resistor, it probably would have near zero T.C.
The whole board is not covered, so the delicate solder joints might create thermal noise from the continuous air draught. In the LT datasheet it is strictly recommended to protect ALL solder joints of the PCB from air draughts.
There are several other improvements to this standard circuit, like the adding of several blocking capacitors by Andreas, which definitely gives better suppression of external e.m.c., and to my opinion better noise performance.
I have designed the most simple PCB, single sided, non -A version, no voodoo slits, no fancy 4 layers with mystical, squiggled tracks.
Simply thermally balanced tracks, where needed, and least expensive components, i.e. no ultra stable Vishay hermetically sealed, oil filled VHP something resistors.
I have put it in a double shielded enclosure, i.e. tuner box with thermal insulation, and an outer aluminum case, and used a simple 12V supply.
Andreas and branadic have added a low noise LDO on their boards, so that's the best solution, I guess, especially when you add a battery backup.
These circuits simply run ultra stable over time, and are nearly free of noise and "popcorn" disturbances.
So I recommend to build one or two of those reference boards:
https://www.eevblog.com/forum/metrology/ultra-precision-reference-ltz1000/msg1336573/#msg1336573https://www.eevblog.com/forum/metrology/ultra-precision-reference-ltz1000/msg3886166/#msg3886166Frank
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