control-system/Assignment 4 - PI/integral_tf.m

% Variable
s = tf('s');
J = 0.01;
b = 0.1;
K = 0.01;
R = 1;
L = 0.5;

Kp = 1;
% Ki = 1;
% Ki = 3;
% Ki = 5;
 Ki = 7;
% Ki = 9;

% Define Transfer Function
num_motor = [K];
den_motor = [J*L J*R+b*L R*b+K*K];

motor = tf(num_motor,den_motor)
% Define Control Function
C = tf([Kp Ki],[1 0])
% Define Closed-Loop function
complete = feedback(motor*C,1);
% Process system responses
subplot(311), impulse(complete);   % Impulse reponse
subplot(312), step(complete);      % Step Response
subplot(313), step(complete / s);  % Ramp response
stepinfo(complete)
% Calculate the Stead-State Error
[y,t] = step(complete); % Calculate Steady-State error
sse = abs(1 - y(end))
% Limit the graph
xlim([0 50])
ylim([0 3])
Add new assignment 2022-09-12 23:39:09 +07:00			`% Variable`
			`s = tf('s');`
			`J = 0.01;`
			`b = 0.1;`
			`K = 0.01;`
			`R = 1;`
			`L = 0.5;`

			`Kp = 1;`
			`% Ki = 1;`
			`% Ki = 3;`
			`% Ki = 5;`
			`Ki = 7;`
			`% Ki = 9;`

			`% Define Transfer Function`
			`num_motor = [K];`
			`den_motor = [JL JR+bL Rb+K*K];`

			`motor = tf(num_motor,den_motor)`
			`% Define Control Function`
			`C = tf([Kp Ki],[1 0])`
			`% Define Closed-Loop function`
			`complete = feedback(motor*C,1);`
			`% Process system responses`
			`subplot(311), impulse(complete); % Impulse reponse`
			`subplot(312), step(complete); % Step Response`
			`subplot(313), step(complete / s); % Ramp response`
			`stepinfo(complete)`
			`% Calculate the Stead-State Error`
			`[y,t] = step(complete); % Calculate Steady-State error`
			`sse = abs(1 - y(end))`
			`% Limit the graph`
			`xlim([0 50])`
			`ylim([0 3])`