<div dir="ltr">Thanks for the follow ups Neil and Bryan! Hotspots and stress testing are how I'm familiar with temp chambers in the first place (thermal cameras are super fun), but in this context I'm more interested in objective measurements of, say, frequency deviation over temperature for VCOs and how to do it properly but on a shoestring budget. I have plenty of info to run with now, will comment again with more questions later I'm sure.</div><div class="gmail_extra"><br><div class="gmail_quote">On Thu, May 11, 2017 at 3:08 PM, Neil Johnson <span dir="ltr"><<a href="mailto:neil.johnson71@gmail.com" target="_blank">neil.johnson71@gmail.com</a>></span> wrote:<br><blockquote class="gmail_quote" style="margin:0 0 0 .8ex;border-left:1px #ccc solid;padding-left:1ex">Hi Brian,<br>
<span class=""><br>
> The key is that if any part your circuit does overheat, then you'll need to fix the design. You need multiple thermocouples in order to find out which chip is the one that's overheating, and that in turn will tell you which part of the circuit needs adjustment.<br>
<br>
</span>You don't need a thermal oven to find out which chips are overheating.<br>
A finger tip will usually suffice, or if you don't like pain then a<br>
thermal imaging camera (quite cheap nowadays from China).<br>
<span class=""><br>
> There's also the fact that different chips are rated for different maximum temperatures, so you'll need to know the precise temperature of each chip to know whether your product has "failed." You can't wait for total failure of the product itself, because not every chip is going to instantly stop working just because you've gone above its temperature limit. However, you want to make sure that your circuit design prevents each individual chip from exceeding its ratings, otherwise you have no guarantee that your product will last.<br>
<br>
</span>Commercial grade components are specified to 70 degrees C, die<br>
temperatures maybe to 125 C. The main purpose of a thermal oven is to<br>
see how a circuit behaves at temperatures other than ambient. As the<br>
designer you should already know which components are going to be<br>
dissipating heat and design accordingly. A chamber can then be used<br>
to verify your design.<br>
<br>
For example, one time I had a product that would get hot. We knew it<br>
would get hot, and designed in heat spreaders. What we wanted to find<br>
out was how hot the external case would get at elevated ambient<br>
temperatures, say 45 C. Some 24 hour tests in a chamber provided the<br>
answers.<br>
<br>
Another use I've put my "chamber" to was to run extended memory tests<br>
on DRAM at high ambient temperatures. Again, this was nothing to do<br>
with finding out what got hot - we knew that - but wanted to find out<br>
what effect temperature had on DRAM reliability.<br>
<span class=""><br>
> I've seen the process and the mess of thermocouples on prototypes, but I've never actually run these tests myself. I'm guessing that if the ambient temperature exceeds the chip ratings, then there's no circuit that could pass the test without refrigeration.<br>
<br>
</span>Ambient rarely exceeds chip ratings, unless you work in a chippy.<br>
What you can do is following thermal calcs determine whether the<br>
system can work reliably at the design's stated maximum working<br>
ambient temperature. For example, a synthesizer module might be<br>
expected to work reliably in a case with a large power supply, where<br>
the internal ambient temperature has risen to, say, 50-60 C. A<br>
thermal chamber allows you to run your module at that temperature<br>
repeatably for extended testing. For example, you can test your VCO's<br>
stability with temperature in a more reliable and repeatable way than<br>
you can with a hair dryer.<br>
<span class=""><br>
> Standard fans can only help when ambient air is cooler than the parts need to be. I've seen the reports, and they mention which chip exceeded its temperature limits, and under what conditions. This usually allows the circuit designer enough clues to reduce the heat in the problem areas.<br>
<br>
</span>A thermal imaging camera gives a very good picture of where the<br>
hotspots are. Definitely easier way to find hotspots than poking<br>
around with thermocouples!<br>
<span class="HOEnZb"><font color="#888888"><br>
Neil<br>
--<br>
<a href="http://www.njohnson.co.uk" rel="noreferrer" target="_blank">http://www.njohnson.co.uk</a><br>
</font></span><div class="HOEnZb"><div class="h5"><br>
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