Ejemplo n.º 1
0
// 
// test Cholesky decomposition
//
void autotest_matrixcf_chol()
{
    float tol = 1e-3f;  // error tolerance

    // lower triangular matrix with positive values on diagonal
    float complex L[16]= {
        1.01,                    0,                       0,                       0,
       -1.42 + _Complex_I*0.25,  0.50,                    0,                       0,
        0.32 - _Complex_I*1.23,  2.01 + _Complex_I*0.78,  0.30,                    0,
       -1.02 + _Complex_I*1.02, -0.32 - _Complex_I*0.03, -1.65 + _Complex_I*2.01,  1.07};

    float complex A[16];    // A = L * L^T
    float complex Lp[16];   // output Cholesky decomposition

    unsigned int i;

    // compute A
    matrixcf_mul_transpose(L,4,4,A);

    // force A to be positive definite
    for (i=0; i<4; i++)
        matrix_access(A,4,4,i,i) = creal(matrix_access(A,4,4,i,i));

    // run decomposition
    matrixcf_chol(A,4,Lp);

    if (liquid_autotest_verbose) {
        printf("L :\n");
        matrixcf_print(L,4,4);
        printf("A :\n");
        matrixcf_print(A,4,4);
        printf("Lp:\n");
        matrixcf_print(Lp,4,4);
    }

    for (i=0; i<16; i++) {
        CONTEND_DELTA( crealf(L[i]), crealf(Lp[i]), tol );
        CONTEND_DELTA( cimagf(L[i]), cimagf(Lp[i]), tol );
    }
}
Ejemplo n.º 2
0
// 
// AUTOTEST: Test matrixcf multiply/transpose
//
void autotest_matrixcf_transmul()
{
    // error tolerance
    float tol = 1e-4f;

    // 3 x 2 complex matrix
    float complex x[6] = {
      -1.984187180846 - _I*1.160899576428,  -0.094097208353 - _I*1.664868369484,
       1.444228871367 - _I*1.830348997497,  -2.157958848569 - _I*0.672986734466,
      -0.889198235505 - _I*2.191307103110,  -0.532344808521 - _I*1.384544279335};

    // computation vectors
    float complex xxT[9];
    float complex xTx[4];
    float complex xxH[9];
    float complex xHx[4];

    // test vectors

    float complex xxT_test[9] = {
        8.06533 +  _I*0.00000,    0.58272 -  _I*1.77897,    6.66340 -  _I*2.55969,
        0.58272 +  _I*1.77897,   10.54567 +  _I*0.00000,    4.80721 +  _I*2.16276,
        6.66340 +  _I*2.55969,    4.80721 -  _I*2.16276,    7.79285 +  _I*0.00000};

    float complex xTx_test[4] = {
       16.3132 +  _I*0.0000,    3.7420 -  _I*1.6630,
        3.7420 +  _I*1.6630,   10.0907 +  _I*0.0000};

    float complex xxH_test[9] = {
      -0.1736 + _I*4.9202,  -5.9078 + _I*5.6112,  -3.0345 + _I*6.3968,
      -5.9078 + _I*5.6112,   2.9395 - _I*2.3823,  -5.0781 + _I*1.8088,
      -3.0345 + _I*6.3968,  -5.0781 + _I*1.8088,  -5.6447 + _I*5.3711};

    float complex xHx_test[4] = {
      -2.6862 + _I*3.2170,  -8.6550 + _I*8.7882,
      -8.6550 + _I*8.7882,  -0.1926 + _I*4.6920};

    // run computations
    matrixcf_mul_transpose(x,3,2,xxT);
    matrixcf_transpose_mul(x,3,2,xTx);
    matrixcf_mul_hermitian(x,3,2,xxH);
    matrixcf_hermitian_mul(x,3,2,xHx);

    // test results
    unsigned int i;

    for (i=0; i<9; i++) {
        CONTEND_DELTA( crealf(xxT[i]), crealf(xxT_test[i]), tol );
        CONTEND_DELTA( cimagf(xxT[i]), cimagf(xxT_test[i]), tol );
    }

    for (i=0; i<4; i++) {
        CONTEND_DELTA( crealf(xTx[i]), crealf(xTx_test[i]), tol );
        CONTEND_DELTA( cimagf(xTx[i]), cimagf(xTx_test[i]), tol );
    }

    for (i=0; i<9; i++) {
        CONTEND_DELTA( crealf(xxH[i]), crealf(xxH_test[i]), tol );
        CONTEND_DELTA( cimagf(xxH[i]), cimagf(xxH_test[i]), tol );
    }

    for (i=0; i<4; i++) {
        CONTEND_DELTA( crealf(xHx[i]), crealf(xHx_test[i]), tol );
        CONTEND_DELTA( cimagf(xHx[i]), cimagf(xHx_test[i]), tol );
    }
}
Ejemplo n.º 3
0
// 
// AUTOTEST: Q/R decomp (Gram-Schmidt)
//
void autotest_matrixcf_qrdecomp()
{
    float tol = 1e-4f;  // error tolerance

    float complex A[16]= {
       2.11402 - 0.57604*_I,  0.41750 + 1.00833*_I, -0.96264 - 3.62196*_I, -0.20679 - 1.02668*_I,
       0.00854 + 1.61626*_I,  0.84695 - 0.32736*_I, -1.01862 - 1.10786*_I, -1.78877 + 1.84456*_I,
      -2.97901 - 1.30384*_I,  0.52289 + 1.89110*_I,  1.32576 - 0.36737*_I,  0.04717 + 0.20628*_I,
       0.28970 + 0.64247*_I, -0.55916 + 0.68302*_I,  1.40615 + 0.62398*_I, -0.12767 - 0.53997*_I};


    float complex Q[16];
    float complex R[16];

    float complex Q_test[16] = {
       0.4917069 - 0.1339829*_I,  0.4296604 + 0.5598343*_I, -0.3093337 - 0.2783187*_I,  0.2152058 - 0.1509579*_I,
       0.0019872 + 0.3759317*_I,  0.2427682 + 0.0092564*_I, -0.4223052 - 0.0325125*_I, -0.5035680 + 0.6055326*_I,
      -0.6928955 - 0.3032643*_I,  0.0541098 + 0.4680729*_I, -0.0821501 + 0.0696538*_I,  0.2796678 + 0.3407228*_I,
       0.0673832 + 0.1494333*_I, -0.2704656 + 0.3844264*_I, -0.2850673 + 0.7447073*_I, -0.1735849 - 0.2936151*_I};

    float complex R_test[16] = {
       4.29936 + 0.00000*_I, -0.92262 - 0.78948*_I, -1.02577 - 1.04067*_I,  0.54122 - 0.00234*_I,
       0.00000 + 0.00000*_I,  2.27373 + 0.00000*_I, -2.93951 - 2.62657*_I, -1.15474 + 0.32321*_I,
       0.00000 + 0.00000*_I,  0.00000 + 0.00000*_I,  1.70137 + 0.00000*_I,  0.68991 - 0.34832*_I,
       0.00000 + 0.00000*_I,  0.00000 + 0.00000*_I,  0.00000 + 0.00000*_I,  2.39237 + 0.00000*_I};

    unsigned int i;

    // run decomposition
    matrixcf_qrdecomp_gramschmidt(A,4,4,Q,R);

    if (liquid_autotest_verbose) {
        printf("Q :\n");
        matrixcf_print(Q,4,4);
        printf("expected Q :\n");
        matrixcf_print(Q_test,4,4);

        printf("\n\n");
        printf("R :\n");
        matrixcf_print(R,4,4);
        printf("expected R :\n");
        matrixcf_print(R_test,4,4);
    }

    for (i=0; i<16; i++) {
        CONTEND_DELTA( crealf(Q[i]), crealf(Q_test[i]), tol );
        CONTEND_DELTA( cimagf(Q[i]), cimagf(Q_test[i]), tol );

        CONTEND_DELTA( crealf(R[i]), crealf(R_test[i]), tol );
        CONTEND_DELTA( cimagf(R[i]), cimagf(R_test[i]), tol );
    }

    // test Q*R  == A
    float complex QR_test[16];
    matrixcf_mul(Q,4,4, R,4,4, QR_test,4,4);
    for (i=0; i<16; i++)
        CONTEND_DELTA( A[i], QR_test[i], tol );

    // test Q*Q' == eye(4)
    float complex QQT_test[16];
    matrixcf_mul_transpose(Q,4,4, QQT_test);
    float complex I4[16];
    matrixcf_eye(I4,4);
    for (i=0; i<16; i++)
        CONTEND_DELTA( QQT_test[i], I4[i], tol );
}
Ejemplo n.º 4
0
int main() {

    float x[6] = {
        1, 2, 3,
        4, 5, 6
    };

    float y[9] = {
        1, 2, 3,
        4, 5, 6,
        7, 8, 9
    };

    float z[6];

    // compute z = x * y
    printf("z = x * y :\n");
    matrixf_mul(x,2,3,y,3,3,z,2,3);
    matrixf_print(z,2,3);

    /*
    // compute z = y * x'
    matrixf_transpose(x);
    printf("x' : \n");
    matrixf_print(x);
    matrixf_transpose(z);
    matrixf_multiply(y,x,z);
    printf("z = y * x' :\n");
    matrixf_print(z);

    matrixf_destroy(x);
    matrixf_destroy(y);
    matrixf_destroy(z);
    */

    float s[16] = {
        1,2,3,4,
        5,5,7,8,
        6,4,8,7,
        1,0,3,1
    };
    float s_inv[16];
    memmove(s_inv,s,16*sizeof(float));
    matrixf_inv(s_inv,4,4);

    float i4[16];
    matrixf_mul(s,4,4,s_inv,4,4,i4,4,4);

    printf("\ns:\n");
    matrixf_print(s,4,4);
    printf("\ninv(s):\n");
    matrixf_print(s_inv,4,4);
    printf("\ns*inv(s):\n");
    matrixf_print(i4,4,4);

    printf("\n");
    float det = matrixf_det(s,4,4);
    printf("det(s) = %12.8f\n", det);

#if 0
    // pivot test (matrix inversion)
    float t[32] = {
        1,2,3,4,  1,0,0,0,
        5,5,7,8,  0,1,0,0,
        6,4,8,7,  0,0,1,0,
        1,0,3,1,  0,0,0,1
    };

    unsigned int i;
    for (i=0; i<4; i++) {
        matrixf_pivot(t,4,8,i,i);
        matrixf_print(t,4,8);
    }

    unsigned int j;
    for (i=0; i<4; i++) {
        float v = matrix_access(t,4,8,i,i);
        for (j=0; j<8; j++)
            matrix_access(t,4,8,i,j) /= v;
    }
    matrixf_print(t,4,8);
#endif

    printf("\n");
    printf("testing L/U decomposition [Crout's method]\n");
    float L[16], U[16], P[16];
    matrixf_ludecomp_crout(s,4,4,L,U,P);
    matrixf_print(L,4,4);
    matrixf_print(U,4,4);

    printf("\n");
    printf("testing L/U decomposition [Doolittle's method]\n");
    matrixf_ludecomp_doolittle(s,4,4,L,U,P);
    matrixf_print(L,4,4);
    matrixf_print(U,4,4);

    printf("\n\n");
    float X[16] = {
        0.84382,  -2.38304,   1.43061,  -1.66604,
        3.99475,   0.88066,   4.69373,   0.44563,
        7.28072,  -2.06608,   0.67074,   9.80657,
        6.07741,  -3.93099,   1.22826,  -0.42142
    };
    float Y[16];
    printf("\nX:\n");
    matrixf_print(X,4,4);

    // swaprows
    memmove(Y,X,16*sizeof(float));
    matrixf_swaprows(Y,4,4,0,2);
    printf("\nmatrixf_swaprows(X,4,4,0,2):\n");
    matrixf_print(Y,4,4);

    // pivot test
    memmove(Y,X,16*sizeof(float));
    matrixf_pivot(Y,4,4,1,2);
    printf("\nmatrixf_pivot(X,4,4,1,2):\n");
    matrixf_print(Y,4,4);

    // inverse test
    memmove(Y,X,16*sizeof(float));
    matrixf_inv(Y,4,4);
    printf("\nmatrixf_inv(X,4,4):\n");
    matrixf_print(Y,4,4);

    // determinant test
    float D = matrixf_det(X,4,4);
    printf("\nmatrixf_det(X,4) = %12.8f\n", D);

    // L/U decomp (Crout's method)
    matrixf_ludecomp_crout(X,4,4,L,U,P);
    printf("\nmatrixf_ludecomp_crout(X,4,4,L,U,P)\n");
    printf("L:\n");
    matrixf_print(L,4,4);
    printf("U:\n");
    matrixf_print(U,4,4);

    // L/U decomp (Doolittle's method)
    matrixf_ludecomp_doolittle(X,4,4,L,U,P);
    printf("\nmatrixf_ludecomp_doolittle(X,4,4,L,U,P)\n");
    printf("L:\n");
    matrixf_print(L,4,4);
    printf("U:\n");
    matrixf_print(U,4,4);

    printf("\n");
    printf("testing Q/R decomposition [Gram-Schmidt]\n");
    float Q[16], R[16];
    matrixf_qrdecomp_gramschmidt(X,4,4,Q,R);
    matrixf_print(Q,4,4);
    matrixf_print(R,4,4);

    /*
    float b[4] = {
       0.91489,
       0.71789,
       1.06553,
      -0.81707};
    */

    float Xb[20] = {
        0.84382,  -2.38304,   1.43061,  -1.66604,   0.91489,
        3.99475,   0.88066,   4.69373,   0.44563,   0.71789,
        7.28072,  -2.06608,   0.67074,   9.80657,   1.06553,
        6.07741,  -3.93099,   1.22826,  -0.42142,  -0.81707
    };
    printf("\n[X b] =\n");
    matrixf_print(Xb,4,5);

    matrixf_gjelim(Xb,4,5);
    printf("\nmatrixf_gjelim(Xb,4,5)\n");
    matrixf_print(Xb,4,5);

    // compute a*a'
    float a[20] = {
        -0.24655,  -1.78843,   0.39477,   0.43735,  -1.08998,
        -0.42751,   0.62496,   1.43802,   0.19814,   0.78155,
        -0.35658,  -0.81875,  -1.09984,   1.87006,  -0.94191,
        0.39553,  -2.02036,   1.17393,   1.54591,   1.29663
    };

    printf("\na =\n");
    matrixf_print(a,4,5);

    printf("\n\n");
    printf("computing a*a'\n");
    float aaT[16];
    matrixf_mul_transpose(a,4,5,aaT);
    matrixf_print(aaT,4,4);

    printf("\n\n");
    printf("computing a'*a\n");
    float aTa[25];
    matrixf_transpose_mul(a,4,5,aTa);
    matrixf_print(aTa,5,5);

    printf("\n");
    printf("testing Gram-Schmidt\n");
    float Xgs[12] = {
        1., 2., 1.,
        0., 2., 0.,
        2., 3., 1.,
        1., 1., 0.
    };
    float Ugs[12];
    float Ugs_test[12] = {
        sqrtf(6.)/6.,   sqrtf(2.)/6.,   2./3.,
        0.,             2.*sqrtf(2.)/3.,-1./3.,
        sqrtf(6.)/3.,   0.,             0.,
        sqrtf(6.)/6.,   -sqrtf(2.)/6.,  -2./3.
    };
    matrixf_gramschmidt(Xgs,4,3,Ugs);

    printf("X:\n");
    matrixf_print(Xgs,4,3);
    printf("normalized X:\n");
    matrixf_print(Ugs,4,3);
    printf("expected:\n");
    matrixf_print(Ugs_test,4,3);


    //
    // test Cholesky decomposition
    //

    printf("\n");
    printf("testing Cholesky decomposition\n");
    // generate  input matrix
    float complex Lp[9] = { 1.0,                   0.0,                   0.0,
                            -3.1 + 0.2*_Complex_I,  0.3,                   0.0,
                            1.7 + 0.5*_Complex_I, -0.6 - 0.3*_Complex_I,  2.9
                          };
    float complex Ap[9];
    matrixcf_mul_transpose(Lp, 3, 3, Ap);
    float complex Lc[9];
    matrixcf_chol(Ap, 3, Lc);

    printf("Lp:\n");
    matrixcf_print(Lp, 3, 3);
    printf("Ap:\n");
    matrixcf_print(Ap, 3, 3);
    printf("Lc:\n");
    matrixcf_print(Lc, 3, 3);

    printf("done.\n");
    return 0;
}