mirror of
https://github.com/gabrielkheisa/control-system.git
synced 2024-11-27 22:03:22 +07:00
112 lines
2.5 KiB
Mathematica
112 lines
2.5 KiB
Mathematica
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clc
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clear all
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close all
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% Get the tangent line
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J = 0.01;
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b = 0.1;
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K = 0.01;
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R = 1;
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L = 0.5;
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s = tf('s');
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num_motor = [K];
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den_motor = [J*L J*R+b*L R*b+K*K];
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motor = tf(num_motor,den_motor);
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% =========== mencari tangenline dan menetukan nilai T dan Y ================
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tic
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timeVal=tic;
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[y,t] = step(motor);
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h = mean(diff(t));
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dy = gradient(y, h); % Numerical Derivative
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[~,idx] = max(dy); % Index Of Maximum
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b = [t([idx-1,idx+1]) ones(2,1)] \ y([idx-1,idx+1]); % Regression Line Around Maximum Derivative
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tv = [-b(2)/b(1); (1-b(2))/b(1)]; % Independent Variable Range For Tangent Line Plot
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f = [tv ones(2,1)] * b; % Calculate Tangent Line
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L = tv(1);
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T = tv(2);
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figure(1)
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plot(t, y)
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hold on
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plot(tv, f, '-r') % Tangent Line
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plot(t(idx), y(idx), '.r')
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title('Mencari tangent line plant ')% Maximum Vertical
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hold off
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grid
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% ================ menentukan control PID sistem ===================
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% Deklarasi variable control
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control = tf(zeros(1,1,5));
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sys=tf(zeros(1,1,5));
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complete=tf(zeros(1,1,5));
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% sistem dengan P
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kp = T/L
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control(:,:,1)= tf([0 kp 0],[1 0]);
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% sistem dengan PI
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kp = 0.9*T/L
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Ti= L/0.3;
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ki = kp/Ti
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control(:,:,2)= tf([0 kp ki],[1 0]);
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% sistem dengan PID
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kp = 1.2*T/L
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Ti= 2*L;
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ki = kp/Ti
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Td = 0.5*L;
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kd = kp*Td
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control(:,:,3)= tf([kd kp ki],[1 0]);
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toc
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%menentukan transfer function sistem
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for x = 1:3
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sys(:,:,x) = motor*control(:,:,x);
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complete(:,:,x) = feedback(sys(:,:,x),1);
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end
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for x = 1:3
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%Step response
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figure(2)
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hold on
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step(complete(:,:,x));
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title('Step Response sistem')
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legend('kendali P', 'kendali PI','kendali PID')
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hold off
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% Mencari karakteristik gelombang
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tf_info(x)= stepinfo(complete(:,:,x));
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% mencari steady state error
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[y,t]=step(complete(:,:,x));
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sserror(x)=(1-y(end));
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% Impulse Repsonse
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figure(3)
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hold on
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impulse(complete(:,:,x));
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title('Impulse Response sistem')
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legend('kendali P', 'kendali PI','kendali PID')
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hold off
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% Ramp Repsonse
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figure(4)
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hold on
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step(complete(:,:,x)/s);
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title('Ramp Response sistem')
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legend('kendali P', 'kendali PI','kendali PID')
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hold off
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figure(5)
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hold on
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step(complete(:,:,x)/(s*s));
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title('Acceleration Response sistem')
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legend('kendali P', 'kendali PI','kendali PID')
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hold off
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end
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