Plotting root locus with variables in transfer function
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Hi. I've been using matlab to plot root loci for my control systems class but I ran into a problem with a recent assignment. This particular problem asks me to plot the root locus of a system in which the transfer function has a variable gain in addition to numeric terms. I just don't have the matlab experience to figure out how to do this on my own with the help command. It would be greatly appreciated if anyone could help me with this. Thank you.
5 comentarios
Jonathan Epperl
el 25 de Nov. de 2012
You need to give more details for us to be able to help you. What is the form of the transfer function, where is the variable gain, where are the given numeric values?
Sean
el 26 de Nov. de 2012
Azzi Abdelmalek
el 26 de Nov. de 2012
rlocus don't work with transfer function in closed loop, you should give the transfer function in open loop, the k2 is a feedback to your system. Look at the example of my answer
Sean
el 26 de Nov. de 2012
So if I have a diagram like this:
Can I factor out the K2 somehow and use that in the rlocus command as the K portion?
Azzi Abdelmalek
el 26 de Nov. de 2012
Editada: Azzi Abdelmalek
el 26 de Nov. de 2012
Yes we can
g1=tf(1,[1 2]) % your GH(s) transfer function
g2=tf([1 1],[1 9]); % your second TF (s+1)/(s+9)
g=g1*g2;
rlocus(g)
Respuesta aceptada
Azzi Abdelmalek
el 25 de Nov. de 2012
Editada: Azzi Abdelmalek
el 25 de Nov. de 2012
If G(p) is your system transfer function, The transfer function of your system in a closed loop with gain k is Gc(p)=G(p)/(1+k.G(p))
%you are looking for closed loop system poles depending on k vakues
G=tf([1 10],[1 2 1]) % your system in open loop
k=0:0.1:100; % k values
rlocus(G,k); % your poles in closed loop
%or
rlocus(G);
Más respuestas (1)
Jonathan Epperl
el 26 de Nov. de 2012
Yeah, like Azzi is hinting: The regular Root Locus shows you where the solutions of the equation 1+k*G(s) = 0 go as you increase k from 0 to infinity.
Assuming you are interested in the transfer function from left to right here, it is
G_H/(1 + k_2*G_H*(s+1)/(s+9) ),
and so the closed-loop poles are precisely the solutions of 1 + k_2*G_H*(s+1)/(s+9) = 0. You will actually find, that this is the case for any transfer function in your loop, e.g. say from T_d to the controller output etc.
Anyway, you might be confused by the way the closed loop is written, probably you expect the controller in the forward path together with G_H, but you can just use the "normal" root locus techniques here, no trickery needed.
rlocus( series(G_H, tf([1 1],[1 9]) ) )
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