So, currently my only guess is the attached circuit,
this is only for the first stage (negative voltages), i realize that another stage should be added.
However, the characteristic is very far from what is required.
So, having tried to follow the lead of MikeMI,
i'm getting closer, currently, i am able to get the correct behavior for positive voltages, i.e (almost) linear follow upto 7V saturation, and then constant 7V.
However, still unable to get the correct behavior on the negative side.
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A question on that note,
what determines the voltage at which the opamp goes into saturation?
Try googling for "precision rectifier" This should help you with the part of the transfer function between -8 and + 8 volts. I will leave you to work out how to deal with the parts between -15 and -8 volts and between + 8 and + 15 volts.
Thank you! That hint got me going on the right way and i found that characteristic to be the one of a Full Wave Rectifier.
After simulation of the op amp based circuit i am able to get the correct characteristic.
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However, i still have one problem,
is there a way to control the gain regardless of the power supply used for the Op Amps?
I am currently able to get a maximum voltage of 8V when setting the power supply to +-9.5V,
can i get the same with a supply of +-15V?
Hi MikeMl,
Apologies for giving basically the same in my post #10 as you had given in your post #7. I only noticed it today .
rhaeg,
I suspect using the rail voltage to limit the output may not be acceptable as a solution. I also suspect the classic zener diode in the feedback may also be unacceptable as it would require selecting an 8.2 volt zener that was at the low end of its tolerance. I can think of a way that would probably work using one extra op amp but I can't think a hint. (Other than giving you the full idea.)