^^ Thanks for that!
I used a simple opamp (FET input) to solve the servo issues. As long as the contacts made a connection of less than 1 Meg ohm, it worked fine. The reduced current through the contacts got rid of contact noise as well. Later I sorted out that if the opamp had a cap in the feedback network, by being careful of the value of the cap the motor would come on slowly and turn off slowly- in effect it would find a speed of the groove cut and settle in on it, thus reducing the tracking error even more, and also eliminating the motor noise.
I ran the opamp off of a separate supply (a 12Volt wall-wart). The opamp drove a transistor that actually turned the motor on and off. Once it was all set up correctly, it was quite reliable and low noise.
I've often thought about revisiting the concept using modern materials- in particular there are motion tracks now that have zero slop in the bearings. Such parts are costly compared to the original arm but nothing compared to modern arms.
I used a simple opamp (FET input) to solve the servo issues. As long as the contacts made a connection of less than 1 Meg ohm, it worked fine. The reduced current through the contacts got rid of contact noise as well. Later I sorted out that if the opamp had a cap in the feedback network, by being careful of the value of the cap the motor would come on slowly and turn off slowly- in effect it would find a speed of the groove cut and settle in on it, thus reducing the tracking error even more, and also eliminating the motor noise.
I ran the opamp off of a separate supply (a 12Volt wall-wart). The opamp drove a transistor that actually turned the motor on and off. Once it was all set up correctly, it was quite reliable and low noise.
I've often thought about revisiting the concept using modern materials- in particular there are motion tracks now that have zero slop in the bearings. Such parts are costly compared to the original arm but nothing compared to modern arms.