Thread: Velocity PID(F) Best Practices - To Integrate, or Not To Integrate?
View Single Post
  #11   Spotlight this post!  
Unread 12-08-2016, 01:45 AM
Jared Russell's Avatar
Jared Russell Jared Russell is offline
Taking a year (mostly) off
FRC #0254 (The Cheesy Poofs), FRC #0341 (Miss Daisy)
Team Role: Engineer
  
Join Date: Nov 2002
Rookie Year: 2001
Location: San Francisco, CA
Posts: 3,069
Jared Russell has a reputation beyond reputeJared Russell has a reputation beyond reputeJared Russell has a reputation beyond reputeJared Russell has a reputation beyond reputeJared Russell has a reputation beyond reputeJared Russell has a reputation beyond reputeJared Russell has a reputation beyond reputeJared Russell has a reputation beyond reputeJared Russell has a reputation beyond reputeJared Russell has a reputation beyond reputeJared Russell has a reputation beyond repute
Re: Velocity PID(F) Best Practices - To Integrate, or Not To Integrate?
Quote:
Originally Posted by calcmogul View Post
Oblarg is correct that the behavior of the velocity PID tuning constants doesn't match the displacement PID. I tried to get something with close enough dynamics that teams could use a similar tuning procedure for both (except in the velocity case, there's no steady-state error so I made Ki not do anything).
This is totally reasonable, and in practice you need an integrator if your loop rate is slow or you are concerned about the effects of rapid oscillation on the lifetime of your mechanical components.

Quote:
Originally Posted by calcmogul View Post
e_ss = 1/(1+Kp*K/(bR+K^2))
e_ss approaches zero as Kp approaches infinity, and the closed-loop transfer function is stable for all positive values of Kp.
Last edited by Jared Russell : 12-08-2016 at 01:58 AM.
Reply With Quote