/* nag_tsa_gain_phase_bivar (g13cfc) Example Program. * * Copyright 1996 Numerical Algorithms Group. * * Mark 4, 1996. * Mark 8 revised, 2004. * */ #include #include #include #include #include #define L 80 #define KC 8*L #define NGMAX KC #define NXYMAX 300 int main(void) { Complex *xyg; Integer exit_status=0, i, is, j, kc=KC, l=L, mw, ng, nxy; NagError fail; double *gn=0, *gnlw=0, *gnup=0, *ph=0, *phlw=0, *phup=0, pw, pxy, *stats=0; double *x=0, *xg, *y=0, *yg; INIT_FAIL(fail); Vprintf("nag_tsa_gain_phase_bivar (g13cfc) Example Program Results\n"); /* Skip heading in data file */ Vscanf("%*[^\n] "); Vscanf("%ld ", &nxy); if (nxy > 0 && nxy <= NXYMAX) { if ( !( stats = NAG_ALLOC(4, double)) || !( x = NAG_ALLOC(KC, double)) || !( y = NAG_ALLOC(KC, double)) || !( gnlw = NAG_ALLOC(NGMAX, double)) || !( gnup = NAG_ALLOC(NGMAX, double)) || !( phlw = NAG_ALLOC(NGMAX, double)) || !( phup = NAG_ALLOC(NGMAX, double)) || !( gn = NAG_ALLOC(NGMAX, double)) || !( ph = NAG_ALLOC(NGMAX, double)) ) { Vprintf("Allocation failure\n"); exit_status = -1; goto END; } for (i = 1; i <= nxy; ++i) Vscanf("%lf ", &x[i - 1]); for (i = 1; i <= nxy; ++i) Vscanf("%lf ", &y[i - 1]); /* Set parameters for call to nag_tsa_spectrum_univar (g13cbc) and g13cdc * with mean correction and 10 percent taper */ pxy = 0.1; /* Window shape parameter and zero covariance at lag 16 */ pw = 0.5; mw = 16; /* Alignment shift of 3 */ is = 3; /* Obtain univariate spectrum for the x and the y series */ /* nag_tsa_spectrum_univar (g13cbc). * Univariate time series, smoothed sample spectrum using * spectral smoothing by the trapezium frequency (Daniell) * window */ nag_tsa_spectrum_univar(nxy, Nag_Mean, pxy, mw, pw, l, kc, Nag_Unlogged, x, &xg, &ng, stats, &fail); if (fail.code != NE_NOERROR) { Vprintf("Error from nag_tsa_spectrum_univar (g13cbc).\n%s\n", fail.message); exit_status = 1; goto END; } /* nag_tsa_spectrum_univar (g13cbc), see above. */ nag_tsa_spectrum_univar(nxy, Nag_Mean, pxy, mw, pw, l, kc, Nag_Unlogged, y, &yg, &ng, stats, &fail); if (fail.code != NE_NOERROR) { Vprintf("Error from nag_tsa_spectrum_univar (g13cbc).\n%s\n", fail.message); exit_status = 1; goto END; } /* Obtain cross spectrum of the bivariate series */ /* nag_tsa_spectrum_bivar (g13cdc). * Multivariate time series, smoothed sample cross spectrum * using spectral smoothing by the trapezium frequency * (Daniell) window */ nag_tsa_spectrum_bivar(nxy, Nag_Mean, pxy, mw, is, pw, l, kc, x, y, &xyg, &ng, &fail); if (fail.code != NE_NOERROR) { Vprintf("Error from nag_tsa_spectrum_bivar (g13cdc).\n%s\n", fail.message); exit_status = 1; goto END; } /* nag_tsa_gain_phase_bivar (g13cfc). * Multivariate time series, gain, phase, bounds, univariate * and bivariate (cross) spectra */ nag_tsa_gain_phase_bivar(xg, yg, xyg, ng, stats, gn, gnlw, gnup, ph, phlw, phup, &fail); if (fail.code != NE_NOERROR) { Vprintf("Error from nag_tsa_gain_phase_bivar (g13cfc).\n%s\n", fail.message); exit_status = 1; goto END; } Vprintf("\n"); Vprintf(" The gain\n\n"); Vprintf(" Lower Upper\n"); Vprintf(" Value bound bound\n\n"); for (j = 1; j <= ng; ++j) Vprintf("%6ld %10.4f %10.4f %10.4f\n", j - 1, gn[j - 1], gnlw[j - 1], gnup[j - 1]); Vprintf("\n The phase\n\n"); Vprintf(" Lower Upper\n"); Vprintf(" Value bound bound\n\n"); for (j = 1; j <= ng; ++j) Vprintf("%6ld %10.4f %10.4f %10.4f\n", j - 1, ph[j - 1], phlw[j - 1], phup[j - 1]); } NAG_FREE(xg); NAG_FREE(yg); NAG_FREE(xyg); END: if (stats) NAG_FREE(stats); if (x) NAG_FREE(x); if (y) NAG_FREE(y); if (gnlw) NAG_FREE(gnlw); if (gnup) NAG_FREE(gnup); if (phlw) NAG_FREE(phlw); if (phup) NAG_FREE(phup); if (gn) NAG_FREE(gn); if (ph) NAG_FREE(ph); return exit_status; }