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Proportional-Integral-Derivative control |
Intro2u.com -
Pic Below will show you the
characteristics of the each of proportional (P), the integral (I), and
the derivative (D) controls, and how to use them to obtain a desired
response. In this tutorial, we will consider the following unity
feedback system:
Plant: A system to be controlled
Controller: Provides the excitation for the plant; Designed to
control the overall system behavior
The three-term controller
The transfer function of the PID controller looks like
the following:
- Kp = Proportional gain
- KI = Integral gain
- Kd = Derivative gain
First, let's take a look at how the PID controller
works in a closed-loop system using the schematic shown above. The
variable (e) represents the tracking error, the difference between the
desired input value (R) and the actual output (Y). This error signal (e)
will be sent to the PID controller, and the controller computes both the
derivative and the integral of this error signal. The signal (u) just
past the controller is now equal to the proportional gain (Kp) times the
magnitude of the error plus the integral gain (Ki) times the integral of
the error plus the derivative gain (Kd) times the derivative of the
error.
This signal (u) will be sent to the plant, and the new
output (Y) will be obtained. This new output (Y) will be sent back to
the sensor again to find the new error signal (e). The controller takes
this new error signal and computes its derivative and its integral
again. This process goes on and on.
The characteristics of P, I, and D controllers
A proportional controller (Kp) will have the effect of
reducing the rise time and will reduce ,but never eliminate, the
steady-state error. An integral control (Ki) will have the effect of
eliminating the steady-state error, but it may make the transient
response worse. A derivative control (Kd) will have the effect of
increasing the stability of the system, reducing the overshoot, and
improving the transient response. Effects of each of controllers Kp, Kd,
and Ki on a closed-loop system are summarized in the table shown below.
| CL RESPONSE
|
RISE TIME |
OVERSHOOT |
SETTLING TIME
|
S-S ERROR |
| Kp |
Decrease |
Increase |
Small Change |
Decrease |
| Ki |
Decrease |
Increase |
Increase |
Eliminate |
| Kd |
Small Change |
Decrease |
Decrease |
Small Change
|
Note that these correlations may
not be exactly accurate, because Kp, Ki, and Kd are dependent of each
other. In fact, changing one of these variables can change the effect of
the other two. For this reason, the table should only be used as a
reference when you are determining the values for Ki, Kp and Kd.
Example Problem
Suppose we have a simple mass, spring, and damper
problem.
The modeling equation of this system is
 (1)
Taking the Laplace transform of the modeling equation
(1)
The transfer function between the displacement X(s)
and the input F(s) then becomes
Let
- M = 1kg
- b = 10 N.s/m
- k = 20 N/m
- F(s) = 1
Plug these values into the above transfer function
The goal of this problem is to show you how each of Kp,
Ki and Kd contributes to obtain
- Fast rise time
- Minimum overshoot
- No steady-state error
Open-loop step response
Let's first view the open-loop step response. Create a
new m-file and add in the following code:
num=1; den=[1 10 20];
step(num,den)
Running this m-file in the Matlab command
window should give you the plot shown below.
The DC gain of the plant transfer function is 1/20, so
0.05 is the final value of the output to an unit step input. This
corresponds to the steady-state error of 0.95, quite large indeed.
Furthermore, the rise time is about one second, and the settling time is
about 1.5 seconds. Let's design a controller that will reduce the rise
time, reduce the settling time, and eliminates the steady-state error.
Proportional control
From the table shown above, we see that the proportional
controller (Kp) reduces the rise time, increases the overshoot, and
reduces the steady-state error. The closed-loop transfer function of the
above system with a proportional controller is:
Let the proportional gain (Kp) equals 300 and change
the m-file to the following:
Kp=300; num=[Kp]; den=[1 10 20+Kp];
t=0:0.01:2;
step(num,den,t)
Running this m-file in the Matlab command
window should gives you the following plot.
Note:
The Matlab function called
cloop
can be used to obtain a closed-loop transfer function directly from the
open-loop transfer function (instead of obtaining closed-loop transfer
function by hand). The following m-file uses the
cloop
command that should give you the identical plot as the one shown above.
num=1;
den=[1 10 20];
Kp=300;
[numCL,denCL]=cloop(Kp*num,den);
t=0:0.01:2;
step(numCL, denCL,t)
The above plot shows that the
proportional controller reduced both the rise time and the steady-state
error, increased the overshoot, and decreased the settling time by small
amount.
Proportional-Derivative control
Now, let's take a look at a PD
control. From the table shown above, we see that the derivative
controller (Kd) reduces both the overshoot and the settling time. The
closed-loop transfer function of the given system with a PD controller
is:
Let Kp equals to 300 as before and
let Kd equals 10. Enter the following commands into an m-file and run it
in the Matlab command window.
Kp=300; Kd=10; num=[Kd Kp]; den=[1
10+Kd 20+Kp]; t=0:0.01:2; step(num,den,t)
This plot shows that the derivative
controller reduced both the overshoot and the settling time, and had
small effect on the rise time and the steady-state error.
Proportional-Integral control
Before going into a PID control,
let's take a look at a PI control. From the table, we see that an
integral controller (Ki) decreases the rise time, increases both the
overshoot and the settling time, and eliminates the steady-state error.
For the given system, the closed-loop transfer function with a PI
control is:
Let's reduce the Kp to 30, and let Ki
equals to 70. Create an new m-file and enter the following commands.
Kp=30; Ki=70; num=[Kp Ki]; den=[1 10
20+Kp Ki]; t=0:0.01:2; step(num,den,t)
Run this m-file in the Matlab command
window, and you should get the following plot.
We have reduced the proportional gain
(Kp) because the integral controller also reduces the rise time and
increases the overshoot as the proportional controller does (double
effect). The above response shows that the integral controller
eliminated the steady-state error.
Proportional-Integral-Derivative
control
Now, let's take a look at a PID
controller. The closed-loop transfer function of the given system with a
PID controller is:
After several trial and error runs,
the gains Kp=350, Ki=300, and Kd=50 provided the desired response. To
confirm, enter the following commands to an m-file and run it in the
command window. You should get the following step response.
Kp=350;
Ki=300;
Kd=50;
num=[Kd Kp Ki];
den=[1 10+Kd 20+Kp Ki];
t=0:0.01:2;
step(num,den,t)
Now, we have obtained the system with
no overshoot, fast rise time, and no steady-state error.
General tips for designing a PID
controller
When you are designing a PID controller
for a given system, follow the steps shown below to obtain a desired
response.
- Obtain an open-loop response and
determine what needs to be improved
- Add a proportional control to
improve the rise time
- Add a derivative control to
improve the overshoot
- Add an integral control to
eliminate the steady-state error
- Adjust each of Kp, Ki, and Kd
until you obtain a desired overall response. You can always refer to
the table shown in this "PID Tutorial" page to find out which
controller controls what characteristics.
Lastly,
please keep in mind that you do not need to implement all three
controllers (proportional, derivative, and integral) into a single
system, if not necessary. For example, if a PI controller gives a good
enough response (like the above example), then you don't need to
implement derivative controller to the system. Keep the controller as
simple as possible.
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