Difference between revisions of "Servo tuning basics"

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==Driver as a controller==
 
==Driver as a controller==
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===What is a feedback gain===
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Feedback gain means '''sensitivity to change output''' due to ''tracking error'' (the difference between setpoint and feedback). The simplest feedback controller is a proportional gain controller (P-gain) where output follows the formula ''output = Pgain*(setpoint-feedback)''. The problem of proportional gain controller is that it may never reach the setpoint because output starts approaching zero when the following error is reaching zero.
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Because of this, it's better to add in '''integrating component''' to the controller. Integrator accumulates the tracking error to a integrator variable. Integrator variable is like a bucket of water, when you add water, the water level rises and when you take out water, the level lowers. In controller the equation becomes: ''output = Pgain*(setpoint-feedback) + Igain*IntegralOf(setpoint-feedback)''.
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The characteristics of gain variables:
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*P-gain - reacts instantly to the tracking error but can't eliminate tracking error completely
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*I-gain - reacts slowly over time to the accumulated error, adjusts output until tracking error is dead zero
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===Low feedback gain, sluggish response===
 
===Low feedback gain, sluggish response===
 
[[File:Carexample sluggish.png|800px]]
 
[[File:Carexample sluggish.png|800px]]

Revision as of 08:51, 12 August 2013

Driving a servo motor is much like driving a car. Driving a car has many similarities including the key concepts of torque, velocity and position control. Most of this happens in the driver's head the same way than a servo drive does with a motor.

Driving (a.k.a servoing) a car

Carexample base.png

Driver as a controller

What is a feedback gain

Feedback gain means sensitivity to change output due to tracking error (the difference between setpoint and feedback). The simplest feedback controller is a proportional gain controller (P-gain) where output follows the formula output = Pgain*(setpoint-feedback). The problem of proportional gain controller is that it may never reach the setpoint because output starts approaching zero when the following error is reaching zero.

Because of this, it's better to add in integrating component to the controller. Integrator accumulates the tracking error to a integrator variable. Integrator variable is like a bucket of water, when you add water, the water level rises and when you take out water, the level lowers. In controller the equation becomes: output = Pgain*(setpoint-feedback) + Igain*IntegralOf(setpoint-feedback).

The characteristics of gain variables:

  • P-gain - reacts instantly to the tracking error but can't eliminate tracking error completely
  • I-gain - reacts slowly over time to the accumulated error, adjusts output until tracking error is dead zero

Low feedback gain, sluggish response

Carexample sluggish.png

Too high feedback gain, oscillation & instability

Carexample unstablepng.png

Optimum feedback gain, only little overshoot

Carexample stable.png

Optimum gain with realistic setpoint, optimum response

Carexample response accellimit.png