Hi James, thanks for the kind words. I have a more similar videos at kzbin.info/aero/PLxdnSsBqCrrF9KOQRB9ByfB0EUMwnLO9o . Please feel free to check them out, I'd love to hear your thoughts as an academic. Thanks for watching!

That being said, never discount the power of guess and check 🙂

Hi, Thanks for the kind words, I'm glad you enjoyed the video. If you find these videos helpful, I hope you'll consider supporting the channel via Patreon at www.patreon.com/christopherwlum or via the 'Thanks' button underneath the video. Given your interest in this topic, I'd love to have you a as a Patron as I'm able to talk/interact personally with all Patrons. I can also answer any questions, provide code, notes, downloads, etc. on Patreon. Thanks for watching! -Chris

Hi, Thanks for the kind words, I'm glad you enjoyed the video. If you find these videos helpful, I hope you'll consider supporting the channel via Patreon at www.patreon.com/christopherwlum or via the 'Thanks' button underneath the video. Given your interest in this topic, I'd love to have you a as a Patron as I'm able to talk/interact personally with all Patrons. I can also answer any questions, provide code, notes, downloads, etc. on Patreon. Thanks for watching! -Chris

Hi, Thanks for the kind words, I'm glad you enjoyed the video. If you find these videos helpful, I hope you'll consider supporting the channel via Patreon at www.patreon.com/christopherwlum or via the 'Thanks' button underneath the video. Given your interest in this topic, I'd love to have you a as a Patron as I'm able to talk/interact personally with all Patrons. I can also answer any questions, provide code, notes, downloads, etc. on Patreon. Thanks for watching! -Chris

Thanks, that is a huge compliment. I see some of your videos are also in the Brian Douglas style so it is good to see other like-minded people here on KZbin. Thanks for watching!

It depends on what system specifically you are controlling. For instance, if you are controlling a motor to have a specific speed, it would be speed. But if you are controlling a motor to maintain a given position, like a servomotor, it would be position. The device after the PID controller in general, is called the plant, as in factory. It's a representation of the dynamics of the process you are controlling. It represents how the output of your controller is turned into a signal to drive the actuator (motor, piston, etc) that controls the system being controlled, and turns it into the physical measurement that is of interest to control. As an example, if you are controlling a DC servomotor to maintain a certain position, the plant dynamics would consist of a model for the coil inductance (L), the coil resistance (R), the rotational inertia of the motor and all that is attached to it (J), the motor field constant (K) that relates current to torque (and likewise speed to back EMF), and the drag it experiences (D). The controller would produce a voltage that would then indirectly determine the current that the motor coil receives, and the torque that propels it forward. Here's a diagram that show a DC motor's dynamics, and the interaction among all these terms: forums.mikeholt.com/attachments/1691248709486-png.2566732/ For a free-spinning motor (no external mechanical load), you can use this diagram to show that the dynamics of the motor can be represented by this transfer function, that relates input voltage U(s) to speed Omega(s): Omega(s)/U(s) = 1/((D + J s)*(L s + R) + K^2) This would be the plant transfer function, if you were interested in controlling the speed. If you were interested in controlling the position like a servomotor, then we'd integrate to find the plant transfer function would be: Theta(s)/U(s) = 1/(s*((D + J s)*(L s + R) + K^2)) If your goal is for Theta(s) to track a desired input angle X(s), then you'd put this plant in series with its controller, and with a feedback loop. This controller would translate the error of X(s) - Theta(s), and use it to generate the voltage necessary to control this motor.

In D control