[quote author="bcarso"][quote author="JohnRoberts"]
One helpful approach when using them in something like a state variable is to configure them so their end points of adjustment are independent of bulk resistance. So instead of a 10K pot with a 1k end limit resistor to deliver a 10:1 adjustment range use no end limit resistor so wiper goes all the way to ground and parallel the wiper resistor with something like a 9X R from the top of the pot. Now the endpoints are the 5% resistor tolerance or better not 20%.
JR[/quote]
I can't quite visualize that. Are you talking about a Kerwin-Huelsman SVF with two inverting integrators?
For that topology I used this arrangement: have a fixed series R, call it R1, to the inverting opamp input with feedback C. Hang the pot from the inverting amp input to common/noninverting opamp input. Have resistor R2 from the pot wiper to the driven end of R1.
Now with pot at max ccw you have exactly R1 as your integrator R. With pot at max cw you have the parallel value of R1 and R2.
Slight disadvantages: the noise gain is higher a bit because the pot end-to-end R is hanging there all the time. Also your previous stage is driving a heavier load at the low frequency endpoint than it would with a simple series R plus variable R.[/quote]
Sorry don't recognise those names...
If I follow your approach it may give an interesting taper or law, but you are using the pot element resistance in the path so it's 20% tolerance can bite you for accuracy. I prefer to use the pot's as potentiometers so you are dealing more with ratios.
Pot goes from preceding output to ground. resistor from wiper, and resistor from top of pot to integrator - input.
When wiper is to ground wiper resistor is out of circuit and LF is defined by resistor in parallel.
Sorry if not clear...
JR
One helpful approach when using them in something like a state variable is to configure them so their end points of adjustment are independent of bulk resistance. So instead of a 10K pot with a 1k end limit resistor to deliver a 10:1 adjustment range use no end limit resistor so wiper goes all the way to ground and parallel the wiper resistor with something like a 9X R from the top of the pot. Now the endpoints are the 5% resistor tolerance or better not 20%.
JR[/quote]
I can't quite visualize that. Are you talking about a Kerwin-Huelsman SVF with two inverting integrators?
For that topology I used this arrangement: have a fixed series R, call it R1, to the inverting opamp input with feedback C. Hang the pot from the inverting amp input to common/noninverting opamp input. Have resistor R2 from the pot wiper to the driven end of R1.
Now with pot at max ccw you have exactly R1 as your integrator R. With pot at max cw you have the parallel value of R1 and R2.
Slight disadvantages: the noise gain is higher a bit because the pot end-to-end R is hanging there all the time. Also your previous stage is driving a heavier load at the low frequency endpoint than it would with a simple series R plus variable R.[/quote]
Sorry don't recognise those names...
If I follow your approach it may give an interesting taper or law, but you are using the pot element resistance in the path so it's 20% tolerance can bite you for accuracy. I prefer to use the pot's as potentiometers so you are dealing more with ratios.
Pot goes from preceding output to ground. resistor from wiper, and resistor from top of pot to integrator - input.
When wiper is to ground wiper resistor is out of circuit and LF is defined by resistor in parallel.
Sorry if not clear...
JR
