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{{short description|Function describing the effects of feedback on a control system}}
A '''closed-loop transfer function''' in [[control theory]] is a mathematical expression ([[algorithm]]) describing the net result of the effects of a closed ([[feedback]]) [[loop (telecommunication)|loop]] on the input [[signal (information theory)|signal]] to the circuits enclosed by the loop.▼
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== Overview ==
The closed-loop [[transfer function]] is measured at the output. The output signal
An example of a closed-loop block diagram, from which a transfer function may be computed, is shown below:
[[Image:Closed Loop Block Deriv.png]]▼
The summing node and the ''G''(''s'') and ''H''(''s'') blocks can all be combined into one block, which would have the following transfer function:
: <math>\dfrac{Y(s)}{X(s)} = \dfrac{G(s)}{1 + G(s) H(s)}</math>
<math>G(s) </math> is called the [[Feed forward (control)|feed forward]] transfer function, <math>H(s) </math> is called the [[Feedback#Control theory|feedback]] transfer function, and their product <math>G(s)H(s) </math> is called the '''open-loop transfer function'''.
==Derivation==
We define an intermediate signal Z (also known as [[error signal]]) shown as follows:
▲[[Image:Closed Loop Block Deriv.png]]
Using this figure we write:
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: <math>Y(s) = G(s)Z(s) </math>
: <math>Z(s) =X(s)-H(s)Y(s) </math>
Now, plug the second equation into the first to eliminate Z(s):
Move all the terms with Y(s) to the left hand side, and keep the term with X(s) on the right hand side:
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Therefore,
▲: <math>Y(s)+G(s)H(s)Y(s) = G(s)X(s)</math>
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==See also==
*[[Federal Standard 1037C]]
*[[Open-loop controller]]
* {{section link|Control theory|Open-loop and closed-loop (feedback) control}}
== References ==
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