Thin film resistors can be noisy. So even if they are low TC the noise can be a problem. The TDP1603 series only specifies <-30 dB of excess noise. This would be too much for a low noise voltmeter. There are a few thin film resistor arrays with lower noise specs, but not that many. Going by the data sheets the LT5400 arrays may be an option in a few cases, if suitable values are available.
Even if the resistors inside the BMF arrays are individual substrates, they are very likely from the same batch and thus still very similar. The thermal coupling is not as good, but this is compensated by a much better absolute TC.
With temperature control the TC is not that important any more. Though it could still effect the linearity by local self-heating.
Indeed, NI of -30 dB would be catastrophic. Once I tried to measure the excess noise of Vishay bulk metal foil resistors and concluded that it was below the detection capabilities of my setup. That was done with a Wheatsone bridge biased with 40 V.
There is a bit of self-heating effect in the array. I see it as a slight thermal tail when I step the input voltage from 0 to 10 V. It's on the order of 0.1 ppm with time constant in the tens of seconds. I know it's thermal, because I can see the reaction of the temperature controller correlated with it. My conclusion was that it's a small effect that could be ignored.
Castorp: I'm intrigued about opamps in analog frontend. Did you try any other comparable autozero opamps? What about AZ switching noise? It can be problematic, depending on input impedance. Perhaps classic (as not AZ) opamps would be OK since the whole unit is temperature regulated?
I'm sure your choice was optimal for this project, but I'm curious about thinking and reasons behind it.
Initially I used ADA4522-1. So far I haven't seen any hint of switching noise with those modern auto-zero amps. It could be due to the fact that we always have low source impedance. Or it's just way out of the signal band, or both.
I wanted something with lots of open-loop gain and high CMRR, so that it makes a good buffer where I don't have to worry about linearity. Also, I checked that they don't exhibit thermal tails. That's something I discovered with another design, where the buffers were built of AD8512. The tail was on the order of 1-2 ppm, time const. 20-30s, for a 10 V step.
From top of my head, I measured the SAR ADCs sampling at 1 MSPS. When it comes to broadband white noise, their behaviour is pretty straightforward. There's a fixed rms noise value, so you get the lowest density when you run at the highest sampling rate. In other words, you spread this noise over a wider bandwidth. I guess that's the kT/C noise of the sampling capacitor spread over a very wide bandwidth, which aliases multiple times in the Nyquist band. I just checked the datasheet of LTC2378-20 - it states a -3 dB analog bandwidth of 34 MHz. That's way over the maximum sampling rate.
hmmm ok i was able to curve fit the noise plot of 7177, the plot i could assume is done at 10k SPS. the total rms noise 1Hz~10kHz will find 1.8uV rms, this fits the datasheet (the 1/f noise contribution below 1 Hz appears to be very small). but starting with 2380, the 100nV white noise is high, the rms noise will have to be >10uV, this suggest the 2380 is likely running at around 500k SPS (1M SPS ~ 16uV rms). above 125k SPS the 2380 has extra 2~3dbm of noise power (~165). whereas for 7177, the noise power between 1k~10k is nearly the same (~164), but 1k SPS is still a tad lower as reflected by the datasheet. "it looks like the dots are connecting" isnt it?
this kind of scratches an itchy curiosity regarding how much 1/f noise would impact the overall noise content of the ADC, esp below 1Hz. i think the 1/f noise corner need to be quite high to force 2380 into an "uncompetitive" seat. like the 7176-2 ?
so i could still assume, the 2380 should still beat the 7177 when using 2k~ 16k SPS range ... maybe 
but this is all paper numbers. there is also a chance i curve fitted wrongly ! i would say my fitting is very low precision.
i highly recommend some of you out there to try curve fit and see for yourself, maybe an actual expert will find something i didnt "notice".
I'll double-check. I did those measurements 2 years ago, which almost feels like a previous life... because I have a small kid
Sorry If my question not appropriate in this thread.
Castorp can you described a little about Your temp management in rack and in field.
is that also CERN design etc etc
It's a totally appropriate question.
Those cabinets are not CERN design - they are commercial. They keep the temperature at 23 degrees C. The temperature down in the LHC tunnel doesn't vary with time of day or seasons, but there's a lot of equipment that dissipates lots of power, so locally it could vary by 5 degrees or more. It's correlated with the machine cycle - the power converters output max current when the beams reach their nominal energy.
Those LTZ1000s certainly have a good life there
First of all, they are powered all the time. And then, there's the on-chip heater and its loop, the Peltier-stabilized module, and then all that's within the large cabinets. All in all, 3 nested control loops.
Another question to the cirquit:
Do you really use a MMBFJ202 for T2?
According to the data sheet it will deliver between 0.9 and 4.5 mA at zero Gate voltage which is too low for the 4-5 mA Zener + the voltage dividers (temperature setpoint + 5V divider).
I am asking because I used the BF245C/BF545C up to now. (12-25 mA zero gate voltage current).
But I have recognized that it is obsolete now and I am looking for a replacement.
Yes, that's what we use. I guess it operates with a bit of -Vgs to source those milliamps - maybe a volt or so.
Unfortunately, lots of discrete JFETs are becoming obsolete these days...
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