```
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.

More information on poles, zeros, and system dynamics:
http://web.mit.edu/2.14/www/Handouts/PoleZero.pdf