initial commit / add all books

1 files changed, 79 insertions, 0 deletions

diff --git a/3432/CH7/EX7.20/Ex7_20.sce b/3432/CH7/EX7.20/Ex7_20.sce
new file mode 100644
index 000000000..14140dde4
--- /dev/null
+++ b/3432/CH7/EX7.20/Ex7_20.sce
@@ -0,0 +1,79 @@
+//Example 7.20

+// Pole Placement as a Dominant Second-Order System

+

+xdel(winsid())//close all graphics Windows

+clear;

+clc;

+//------------------------------------------------------------------

+

+clc;

+clear all;

+

+// State space representation

+F=[0 2 0 0 0;-0.10 -0.35 0.1 0.1 0.75; 0 0 0 2 0;...

+ 0.4 0.4 -0.4 -1.4 0; 0 -0.03 0 0 -1];

+G=[0 0 0 0 1]';

+H=[0.5 0 0.5 0 0]; //Tape position at the head

+Ht=[-0.2 -0.2 0.2 0.2 0]; //Tension output

+J=0;

+n=sqrt(length(F))

+// Desired poles

+Pc=[-0.707+0.707*%i -0.707-0.707*%i -4 -4 -4]/1.5;

+//------------------------------------------------------------------

+// State feedback gain matrix via LQR (riccati equation)

+Q = eye(5,5);

+R =1

+// Riccati equation

+P=riccati(F, G*inv(R)*G', Q, 'c')

+K1=inv(R)*G'*P

+//------------------------------------------------------------------

+// State feedback gain matrix via pole-placement

+exec('./acker_dk.sci', -1);

+K2=acker_dk(F,G,Pc);

+disp(K2,'K2=',"Gain by ackermans formula" );

+//------------------------------------------------------------------

+Ntilde1=-inv(H*inv(F-G*K1)*G); //input gain for LQR feedback gain.

+Ntilde2=-inv(H*inv(F-G*K2)*G); //input gain for Ackerman's feedback gain.

+

+syscl1=syslin('c',(F-G*K1),G*Ntilde1,H,J); //closed loop system with K1

+syscl2=syslin('c',(F-G*K2),G*Ntilde2,H,J); //closed loop system with K2

+

+t=0:0.1:12;

+[y1 x1]=csim('step',t,syscl1); //response of position head with K1

+[y2 x2]=csim('step',t,syscl2); //response of position head with K2

+

+//plot of a position of read write head

+plot(t,y1,"m-."); //Design via LQR

+plot(t,y2,2); //Design via Ackerman's Formula

+

+//Title, labels and grid to the figure

+exec .\fig_settings.sci; // custom script for setting figure properties

+title('Step response of tape servomotor designs','fontsize',3);

+xlabel('Time t (sec.)','fontsize',2);

+ylabel('Tape Posotion','fontsize',2);

+

+xstring(2.5,1.1,"LQR")

+xarrows([3;4],[1.1;0.95],-1,1)

+xstring(5,0.7,["Dominant";"second order"])

+xarrows([5;4.2],[0.8;0.9],-1.5,1)

+//------------------------------------------------------------------

+

+//response as a tape tension

+yt1=Ht*x1;

+yt2=Ht*x2;

+

+figure(1)

+plot(t,yt1,"m-."); //Design via LQR

+plot(t,yt2,2); //Design via Ackerman's Formula

+

+//Title, labels and grid to the figure

+exec .\fig_settings.sci; // custom script for setting figure properties

+title('Tension plots for tape servomotor step responses','fontsize',3);

+xlabel('Time t (sec.)','fontsize',2);

+ylabel('Tape Tension','fontsize',2);

+

+xstring(3.5,0,"LQR")

+xarrows([3.7;4.7],[0;0],-1)

+xstring(6.1,-0.015,["Dominant";"second order"])

+xarrows([6;6],[-0.013;-0.002],-1)

+//------------------------------------------------------------------