Team:KULeuven/Modeling/Integrated Model

From 2009.igem.org

(Difference between revisions)
(Tracking problem)
(Tracking problem)
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with T the total open loop gain. As we wish to eliminate the transfer of disturbances to the output of our system, we have to maximize the loop gain of the system.
with T the total open loop gain. As we wish to eliminate the transfer of disturbances to the output of our system, we have to maximize the loop gain of the system.
We have simulated this behaviour in the non linear model of our bacteria.
We have simulated this behaviour in the non linear model of our bacteria.
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[[Image:Tracking_error.png|750px|center|thumb|Tracking error on step input in function of amplitude and time]]
=Disturbance rejection=
=Disturbance rejection=

Revision as of 20:41, 28 September 2009


Tuning the controller

Here we consider the problem of choosing the amount of proportional action in the feedback loop, in following sections terminology and concepts used in linear control theory are used. It's of course obvious will not behave in a linearly way. But the concepts and design strategies of linear control theory can be translated to non-linear control theory.

One of the most useful ways of investigating the behaviour of closed loop system is the investigation of the open loop system. The open loop system is the system which one becomes if you 'remove' the differentiator.

Block model of the system with proportional controller

Stability

Tracking problem

We are mostly interested in the ability of the controlled system to follow a step input signal, for a linear system the steady state tracking error is:

Eqn7165.png

with T the total open loop gain. As we wish to eliminate the transfer of disturbances to the output of our system, we have to maximize the loop gain of the system. We have simulated this behaviour in the non linear model of our bacteria.


Tracking error on step input in function of amplitude and time

Disturbance rejection

Robustness