# Characteristic Equation of A Closed Loop System in Terms of PI Controller

Just wondering if you could guide me on how to find the characteristic equation of a trasfer function G(s) (see below for G(s)) in terms of the coefficients in the PI controller?

G(s) = 45/(5s + 2)

No sure what to do here, as I'm used to just multiplying the error by the proportional gain - but there's no error value provided.

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``````Given:
G(s) = 45/(5s + 2) (plant transfer function)
C(s) = Kp + Ki/s (PI Controller transfer function)
``````

and assuming your system looks like: https://www.dropbox.com/s/wtt4tvujn6tpepv/block_diag.JPG

The equation of the closed loop transfer function is:

``````Gcl(s) =  C(s)G(s)/(1+C(s)G(s)) = CG/(1+CG)
``````

In general, If you had another transfer function on the feedback path, H(s), the the closed loop transfer function becomes:

``````CG / (1 + CGH)
``````

If you plug in G(s) and C(s) as shown above you will get the following closed loop transfer function after some algebraic simplification:

``````[45*Kp*s + Ki] / [5*s*s + (2 + 45*Kp)*s + Ki]
``````

and so the characteristic equation is

``````5*s*s + (2 + 45*Kp)*s + Ki = 0
``````

Notice how the integral term adds a pole to the system but has a side effect of also adding a zero which could produce unwanted transient behaviour if Kp is not chosen correctly. The presence of Kp in the s term in the denominator shows that the value of Kp will determine the damping ratio of the system and therefore determine the transient response.