/* DoD NIMA World Magnetic Model. * from http://www.ngdc.noaa.gov * #define TEST_MAIN */ #include #include #include #include #include "astro.h" static char mfn[] = "wmm.cof"; /* file with model coefficients */ static int geomag(FILE *wmmdat, int *maxdeg); static int geomg1(FILE *wmmdat, float alt, float glat, float glon, float t, float *dec, float *mdp, float *ti, float *gv); /* compute magnetic declination for given location, elevation and time. * sign is such that mag bearing = true az + mag deviation. * return 0 if ok, -1 if no model file, -2 if time outside model range. * fill err[] with excuse if return < 0. */ int magdecl ( double l, double L, /* geodesic lat, +N, long, +E, rads */ double e, /* elevation, m */ double y, /* time, decimal year */ char *dir, /* dir for model file */ double *mdp, /* magnetic deviation, rads E of N */ char *err) /* err message if return < 0 */ { float dlat = raddeg(l); float dlon = raddeg(L); float alt = e/1000.; int maxdeg = 12; float dec, dp, ti, gv; char mfile[1024]; FILE *wmmdat; int s; /* open model file */ sprintf (mfile, "%s/%s", dir, mfn); wmmdat = fopen (mfile, "r"); if (!wmmdat) { sprintf (err, "%s: %s", mfile, strerror(errno)); return (-1); } /* compute deviation */ geomag(wmmdat, &maxdeg); s = geomg1(wmmdat,alt,dlat,dlon,y,&dec,&dp,&ti,&gv); fclose(wmmdat); if (s < 0) { sprintf (err, "%s: Magnetic model only available for %g .. %g. See http://www.ngdc.noaa.gov", mfile, ti, ti+5); return (-2); } *mdp = degrad(dec); return (0); } #if defined(TEST_MAIN) int main(int ac, char *av[]) { char err[1024]; float altm, dlat, dlon; float t; double dec; S1: printf("\n\n\n ENTER LATITUDE IN DECIMAL DEGREES (+25.0)\n"); scanf("%f", &dlat); printf(" ENTER LONGITUDE IN DECIMAL DEGREES (-100.0)\n"); scanf("%f", &dlon); printf(" ENTER ALTITUDE IN METERS\n"); scanf("%f", &altm); printf(" ENTER TIME IN DECIMAL YEAR\n"); scanf("%f",&t); if (magdecl (degrad(dlat), degrad(dlon), altm, t, "auxil", &dec, err) < 0) { printf ("%s\n", err); return(1); } printf("\n LATITUDE: = %-7.2f DEG",dlat); printf("\n LONGITUDE: = %-7.2f DEG\n",dlon); printf("\n ALTITUDE = %.2f METERS",altm); printf("\n DATE = %-5.1f\n",t); printf("\n\t\t\t OUTPUT\n\t\t\t ------"); printf("\n DEC = %-7.2f DEG", raddeg(dec)); printf("\n\n\n DO YOU NEED MORE POINT DATA? (y or n)\n"); scanf("%s", err); if ((err[0] =='y')||(err[0] == 'Y')) goto S1; return(0); } #endif /* defined(TEST_MAIN) */ /************************************************************************* * return 0 if ok, -1 if time is out of range with base epoc in *ti */ static int E0000(FILE *wmmdat, int IENTRY, int *maxdeg, float alt, float glat, float glon, float t, float *dec, float *mdp, float *ti, float *gv) { static int maxord,i,icomp,n,m,j,D1,D2,D3,D4; static float c[13][13],cd[13][13],tc[13][13],dp[13][13],snorm[169], sp[13],cp[13],fn[13],fm[13],pp[13],k[13][13],pi,dtr,a,b,re, a2,b2,c2,a4,b4,c4,epoc,gnm,hnm,dgnm,dhnm,flnmj,otime,oalt, olat,olon,dt,rlon,rlat,srlon,srlat,crlon,crlat,srlat2, crlat2,q,q1,q2,ct,st,r2,r,d,ca,sa,aor,ar,br,bt,bp,bpp, par,temp1,temp2,parp,bx,by,bz,bh; static char model[20], c_str[81], c_new[5]; static float *p = snorm; switch(IENTRY){case 0: goto GEOMAG; case 1: goto GEOMG1;} GEOMAG: /* INITIALIZE CONSTANTS */ maxord = *maxdeg; sp[0] = 0.0; cp[0] = *p = pp[0] = 1.0; dp[0][0] = 0.0; a = 6378.137; b = 6356.7523142; re = 6371.2; a2 = a*a; b2 = b*b; c2 = a2-b2; a4 = a2*a2; b4 = b2*b2; c4 = a4 - b4; /* READ WORLD MAGNETIC MODEL SPHERICAL HARMONIC COEFFICIENTS */ c[0][0] = 0.0; cd[0][0] = 0.0; fgets(c_str, 80, wmmdat); sscanf(c_str,"%f%s",&epoc,model); S3: fgets(c_str, 80, wmmdat); /* CHECK FOR LAST LINE IN FILE */ for (i=0; i<4 && (c_str[i] != '\0'); i++) { c_new[i] = c_str[i]; c_new[i+1] = '\0'; } icomp = strcmp("9999", c_new); if (icomp == 0) goto S4; /* END OF FILE NOT ENCOUNTERED, GET VALUES */ sscanf(c_str,"%d%d%f%f%f%f",&n,&m,&gnm,&hnm,&dgnm,&dhnm); if (m <= n) { c[m][n] = gnm; cd[m][n] = dgnm; if (m != 0) { c[n][m-1] = hnm; cd[n][m-1] = dhnm; } } goto S3; /* CONVERT SCHMIDT NORMALIZED GAUSS COEFFICIENTS TO UNNORMALIZED */ S4: *snorm = 1.0; for (n=1; n<=maxord; n++) { *(snorm+n) = *(snorm+n-1)*(float)(2*n-1)/(float)n; j = 2; for (m=0,D1=1,D2=(n-m+D1)/D1; D2>0; D2--,m+=D1) { k[m][n] = (float)(((n-1)*(n-1))-(m*m))/(float)((2*n-1)*(2*n-3)); if (m > 0) { flnmj = (float)((n-m+1)*j)/(float)(n+m); *(snorm+n+m*13) = *(snorm+n+(m-1)*13)*sqrt(flnmj); j = 1; c[n][m-1] = *(snorm+n+m*13)*c[n][m-1]; cd[n][m-1] = *(snorm+n+m*13)*cd[n][m-1]; } c[m][n] = *(snorm+n+m*13)*c[m][n]; cd[m][n] = *(snorm+n+m*13)*cd[m][n]; } fn[n] = (float)(n+1); fm[n] = (float)n; } k[1][1] = 0.0; otime = oalt = olat = olon = -1000.0; return (0); /*************************************************************************/ GEOMG1: dt = t - epoc; if (otime < 0.0 && (dt < 0.0 || dt > 5.0)) { *ti = epoc; /* pass back base time for diag msg */ return (-1); } pi = 3.14159265359; dtr = pi/180.0; rlon = glon*dtr; rlat = glat*dtr; srlon = sin(rlon); srlat = sin(rlat); crlon = cos(rlon); crlat = cos(rlat); srlat2 = srlat*srlat; crlat2 = crlat*crlat; sp[1] = srlon; cp[1] = crlon; /* CONVERT FROM GEODETIC COORDS. TO SPHERICAL COORDS. */ if (alt != oalt || glat != olat) { q = sqrt(a2-c2*srlat2); q1 = alt*q; q2 = ((q1+a2)/(q1+b2))*((q1+a2)/(q1+b2)); ct = srlat/sqrt(q2*crlat2+srlat2); st = sqrt(1.0-(ct*ct)); r2 = (alt*alt)+2.0*q1+(a4-c4*srlat2)/(q*q); r = sqrt(r2); d = sqrt(a2*crlat2+b2*srlat2); ca = (alt+d)/r; sa = c2*crlat*srlat/(r*d); } if (glon != olon) { for (m=2; m<=maxord; m++) { sp[m] = sp[1]*cp[m-1]+cp[1]*sp[m-1]; cp[m] = cp[1]*cp[m-1]-sp[1]*sp[m-1]; } } aor = re/r; ar = aor*aor; br = bt = bp = bpp = 0.0; for (n=1; n<=maxord; n++) { ar = ar*aor; for (m=0,D3=1,D4=(n+m+D3)/D3; D4>0; D4--,m+=D3) { /* COMPUTE UNNORMALIZED ASSOCIATED LEGENDRE POLYNOMIALS AND DERIVATIVES VIA RECURSION RELATIONS */ if (alt != oalt || glat != olat) { if (n == m) { *(p+n+m*13) = st**(p+n-1+(m-1)*13); dp[m][n] = st*dp[m-1][n-1]+ct**(p+n-1+(m-1)*13); goto S50; } if (n == 1 && m == 0) { *(p+n+m*13) = ct**(p+n-1+m*13); dp[m][n] = ct*dp[m][n-1]-st**(p+n-1+m*13); goto S50; } if (n > 1 && n != m) { if (m > n-2) *(p+n-2+m*13) = 0.0; if (m > n-2) dp[m][n-2] = 0.0; *(p+n+m*13) = ct**(p+n-1+m*13)-k[m][n]**(p+n-2+m*13); dp[m][n] = ct*dp[m][n-1] - st**(p+n-1+m*13)-k[m][n]*dp[m][n-2]; } } S50: /* TIME ADJUST THE GAUSS COEFFICIENTS */ if (t != otime) { tc[m][n] = c[m][n]+dt*cd[m][n]; if (m != 0) tc[n][m-1] = c[n][m-1]+dt*cd[n][m-1]; } /* ACCUMULATE TERMS OF THE SPHERICAL HARMONIC EXPANSIONS */ par = ar**(p+n+m*13); if (m == 0) { temp1 = tc[m][n]*cp[m]; temp2 = tc[m][n]*sp[m]; } else { temp1 = tc[m][n]*cp[m]+tc[n][m-1]*sp[m]; temp2 = tc[m][n]*sp[m]-tc[n][m-1]*cp[m]; } bt = bt-ar*temp1*dp[m][n]; bp += (fm[m]*temp2*par); br += (fn[n]*temp1*par); /* SPECIAL CASE: NORTH/SOUTH GEOGRAPHIC POLES */ if (st == 0.0 && m == 1) { if (n == 1) pp[n] = pp[n-1]; else pp[n] = ct*pp[n-1]-k[m][n]*pp[n-2]; parp = ar*pp[n]; bpp += (fm[m]*temp2*parp); } } } if (st == 0.0) bp = bpp; else bp /= st; /* ROTATE MAGNETIC VECTOR COMPONENTS FROM SPHERICAL TO GEODETIC COORDINATES */ bx = -bt*ca-br*sa; by = bp; bz = bt*sa-br*ca; /* COMPUTE DECLINATION (DEC), INCLINATION (DIP) AND TOTAL INTENSITY (TI) */ bh = sqrt((bx*bx)+(by*by)); *ti = sqrt((bh*bh)+(bz*bz)); *dec = atan2(by,bx)/dtr; *mdp = atan2(bz,bh)/dtr; /* COMPUTE MAGNETIC GRID VARIATION IF THE CURRENT GEODETIC POSITION IS IN THE ARCTIC OR ANTARCTIC (I.E. GLAT > +55 DEGREES OR GLAT < -55 DEGREES) OTHERWISE, SET MAGNETIC GRID VARIATION TO -999.0 */ *gv = -999.0; if (fabs(glat) >= 55.) { if (glat > 0.0 && glon >= 0.0) *gv = *dec-glon; if (glat > 0.0 && glon < 0.0) *gv = *dec+fabs(glon); if (glat < 0.0 && glon >= 0.0) *gv = *dec+glon; if (glat < 0.0 && glon < 0.0) *gv = *dec-fabs(glon); if (*gv > +180.0) *gv -= 360.0; if (*gv < -180.0) *gv += 360.0; } otime = t; oalt = alt; olat = glat; olon = glon; return (0); } /*************************************************************************/ static int geomag(FILE *wmmdat, int *maxdeg) { return (E0000(wmmdat,0,maxdeg,0.0,0.0,0.0,0.0,NULL,NULL,NULL,NULL)); } /*************************************************************************/ static int geomg1(FILE *wmmdat, float alt, float glat, float glon, float t, float *dec, float *mdp, float *ti, float *gv) { return (E0000(wmmdat,1,NULL,alt,glat,glon,t,dec,mdp,ti,gv)); } /* For RCS Only -- Do Not Edit */ static char *rcsid[2] = {(char *)rcsid, "@(#) $RCSfile: magdecl.c,v $ $Date: 2011-09-21 16:17:49 $ $Revision: 1.8 $ $Name: not supported by cvs2svn $"};