Mathc complexes/a341
Apparence
Décomposition d'une matrice en éléments propres
Installer et compiler ces fichiers dans votre répertoire de travail.
c00b.c |
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/* ------------------------------------ */
/* save as : c00b.c */
/* ------------------------------------ */
#include "w_a.h"
/* ------------------------------------ */
#define FACTOR_E +1.E-4
/* ------------------------------------ */
/* ------------------------------------ */
double f(
double x)
{
return(cos(2*x));
}
char feq[] = "cos(2*x)";
/* ------------------------------------ */
double g(
double x)
{
return(2*cos(x)*cos(x)-1);
}
char geq[] = "2*cos(x)**2-1";
/* ------------------------------------ */
/* ------------------------------------ */
void fun(int rc)
{
double **A = rcsymmetric_mZ( i_mZ(rc,rc),99);
double **A_T = ctranspose_mZ(A, i_mZ(rc,rc));
double **U = X_U_mZ(A_T, i_mZ(rc,rc),FACTOR_E);
double **U_T = ctranspose_mZ(U, i_mZ(rc,rc));
double **U_TA = mul_mZ(U_T, A, i_mZ(rc,rc));
double **X = mul_mZ(U_TA, U, i_mZ(rc,rc));
double **cos2X = f_eigs_mZ(f,X, i_mZ(rc,rc));
double **Ucos2X = mul_mZ(U,cos2X, i_mZ(rc,rc));
double **cos2 = mul_mZ(Ucos2X,U_T, i_mZ(rc,rc));
double **twocosP2mns1X = f_eigs_mZ(g,X, i_mZ(rc,rc));
double **UtwocosP2mns1X = mul_mZ(U,twocosP2mns1X, i_mZ(rc,rc));
double **twocosP2mns1 = mul_mZ(UtwocosP2mns1X,U_T, i_mZ(rc,rc));
clrscrn();
printf(" A :");
p_mZ(A, S9,P1, S8,P1, C4);
printf(" U :");
p_mZ(U, S9,P4, S8,P4, C4);
printf(" X = U_T * A * U :");
p_mZ(X, S11,P3, S7,P3, C4);
stop();
clrscrn();
printf(" cos(2*A)");
p_mZ(cos2, S7,P3, S7,P3, C6);
printf(" 2*cos(A)*cos(A)-1");
p_mZ(twocosP2mns1, S7,P3, S7,P3, C6);
f_mZ(A);
f_mZ(A_T);
f_mZ(U);
f_mZ(U_T);
f_mZ(U_TA);
f_mZ(X);
f_mZ(cos2X);
f_mZ(Ucos2X);
f_mZ(cos2);
f_mZ(twocosP2mns1X);
f_mZ(UtwocosP2mns1X);
f_mZ(twocosP2mns1);
}
/* ------------------------------------ */
int main(void)
{
time_t t;
srand(time(&t));
do
{
fun(R4);
} while(stop_w());
return 0;
}
/* ------------------------------------ */
/* ------------------------------------ */
Exemple de sortie écran :
A :
+20901.0 +0.0i -5124.0 +8398.0i +1911.0-12822.0i +637.0 -6614.0i
-5124.0 -8398.0i +29876.0 +0.0i +2664.0 -2146.0i -4089.0 -1659.0i
+1911.0+12822.0i +2664.0 +2146.0i +16912.0 +0.0i -1352.0 -649.0i
+637.0 +6614.0i -4089.0 +1659.0i -1352.0 +649.0i +11944.0 +0.0i
U :
+0.2214 -0.5933i -0.3956 +0.1038i -0.0226 -0.1500i +0.0252 +0.6388i
-0.6878 +0.0260i -0.2692 -0.5440i +0.3003 -0.0300i -0.1699 +0.1945i
+0.2617 +0.0065i -0.1668 -0.6516i -0.3269 +0.1211i +0.5914 -0.0886i
+0.2380 +0.0000i +0.1093 +0.0000i +0.8743 +0.0000i +0.4087 +0.0000i
X = U_T * A * U :
+39150.644 +0.000i +0.000 +0.000i -0.000 +0.000i -0.000 -0.000i
+0.000 -0.000i +27612.736 +0.000i -0.000 +0.000i -0.000 -0.000i
-0.000 -0.000i -0.000 +0.000i +12130.233 -0.000i +0.000 +0.000i
+0.000 +0.000i -0.000 -0.000i +0.000 -0.000i +739.387 +0.000i
Press return to continue.
cos(2*A)
+0.013 +0.000i -0.279 +0.642i +0.074 -0.130i +0.072 -0.367i
-0.279 -0.642i +0.156 +0.000i -0.484 +0.008i +0.030 -0.005i
+0.074 +0.130i -0.484 -0.008i -0.472 -0.000i -0.204 +0.132i
+0.072 +0.367i +0.030 +0.005i -0.204 -0.132i +0.299 +0.000i
2*cos(A)*cos(A)-1
+0.013 +0.000i -0.279 +0.642i +0.074 -0.130i +0.072 -0.367i
-0.279 -0.642i +0.156 +0.000i -0.484 +0.008i +0.030 -0.005i
+0.074 +0.130i -0.484 -0.008i -0.472 -0.000i -0.204 +0.132i
+0.072 +0.367i +0.030 +0.005i -0.204 -0.132i +0.299 +0.000i
Press return to continue
Press X return to stop