Im not ignoring anyone. But I didn't understood your post. That scale from that graph shows 0V to 0.7V. Not from 1.5V to 3V as you say here. And Im prioritizing, and probably at that time I was thinking on something else what to do. Sorry about not testing your ideas. But I only have 2 hands and a certain amount of time and concentration. You must understand that. Is good that you point me towards your solution.I guess you are ignoring my posts. That is ok. I am not offended.
I posted a solution in post #108. If you use a 5 V supply, the outputs are in 0.5 V steps.
30 °C = 1.5 V
40 °C = 2.0 V
50 °C = 2.5 V
60 °C = 3.0 V
Now connect this to an LM3914N, trim the range and offset, and you're done!
- So you say,, to test this cct:

- You made me wonder for a few minutes why didnt I use this simple cct in the first place? But I did. You just copied what I did in the very first post. Take a look in my #1 post and you'll see this exact cct. That cct is using "your cct" linked directly to comparator imput and I actually got the best results from it, now in retrospect, but with a very big shifting problem that bugged me from the very beginning. Now, after all this time and experiments and 3 circuits, I start to kind of see where the problem really is. And Im suspecting my LM393 for low sensitivity. I have to test it yet, for now is a suspicion.
Here:
Only that you are using a battery and Im using an aligator clip from my 5V PSU. And different values for components.But its the same idea. Also I build this not only here in simulator, but in reality too with relatively interconnected results. I started to make a "full" circuit based on this circuit idea already comprised of 2 ICs, so 4 comparators, for 30,40,50,60*C steps. But with the knowledge they will have that serious error Im mentioning all the time, "the shifting problem". It remains the only one that works. Funny, isn't it?
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