Yes, Agree. I wrote tin the first post that "for your use a resistive heater would be better"
But everything else, I'd do over. Drill the aluminum block and use thermal epoxy to hold the sensor in place. Use a vacuum insulated mug or bowl for a cover and let a micro controller run a PID loop to control temperature.. You can keep it within 0.1C without the need to be a control theory expert. Another order of magnitude would really hard and expensive The last temperature controller I made was not as good but keeps a rubidium oscillator within about a degree. I put a thruster in the Rb's heat sink and a micro controller adjusts the fan speed. The self heat from the Rb unit is enough. The Rb is about the size and shape of an old 3.5 inch disk drive so I put it n an old disk drive enclosure that already had a place for a fan. As crude as this is, it is much better then what I had which was not control. The Rb output is better then I have means to measure now. So same with the poor man's oven. It can be very good with very little effort. What has happened is that now we have nearly free micro controllers and can use daily sophisticated control algorithms that HP could not use back in the day. We can actually model non linearities in the sensor. We can use a full on PID solution rather then the simple on/off thermostat. But no you don't want to cool a crystal, I was not suggesting that. We happened to have a high gain amplifier that was in effect counting electrons. On Mon, Jun 5, 2017 at 2:15 AM, Attila Kinali <[email protected]> wrote: > On Sun, 4 Jun 2017 22:01:45 -0700 > Chris Albertson <[email protected]> wrote: > > > Voltage is proportional to the product of resistance and absolute > > temperature. As an experiment place a voltage across a high value > > resister like say one 1M raise the volts until you are near the limit of > > the resister and connect it via a coupler cadaster to an audio amplifier. > > You will hear white noise in the speakers. > > Yes, Johnson noise increases by about 20% (or about 0.8dB) > when going from 25°C to 90°C. But Johnson noise is usually > not the first limiting noise one runs into when designing > a crystal oscillator. I would rather use a simpler, > "high temperature" oven and invest the time saved into a > desgining better oscillator structure. > > > > There is a similar effect in semi conductors. The best example of this > is > > visual noise in digital camera, when you tern the gain way up (set the > ISO > > high) you can see it in the photo. > > > > All of this is proportion; to absolute. > > > > As I remember we ran the "oven" at -20C There was a valve used to flash > out > > the air inside with inert welding gas to reduce ice. > > If the -20°C was used on the camera, then this is not to reduce Johnson > noise, but the dark current noise. While the former is due to thermal > vibration of the atom lattice, the later is due to spontaneous forming > of electron-hole pairs in the p-n junction region. Thus also their > temperature characteristics differ: While Johnson noise is linear > in temperature, dark current noise is (almost) exponential in temperature. > Going down from room temperature to 0°C is something like a factor 100 > (IIRC, from memory, could be wrong) in noise for a CCD. While for > a resistor, the difference is almost negligible. > > Attila Kinali > -- > You know, the very powerful and the very stupid have one thing in common. > They don't alters their views to fit the facts, they alter the facts to > fit the views, which can be uncomfortable if you happen to be one of the > facts that needs altering. -- The Doctor > _______________________________________________ > 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. > -- Chris Albertson Redondo Beach, California _______________________________________________ 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.
