From: curt Date: Tue, 28 Mar 2000 22:08:31 +0000 (+0000) Subject: Ed Williams: Added some bulletproofing at the poles. X-Git-Url: https://git.mxchange.org/?a=commitdiff_plain;h=420c747551769d3fdeaf7a8014a738da7fb8537e;p=simgear.git Ed Williams: Added some bulletproofing at the poles. --- diff --git a/simgear/magvar/magvar.cxx b/simgear/magvar/magvar.cxx index 319dca13..455abfab 100644 --- a/simgear/magvar/magvar.cxx +++ b/simgear/magvar/magvar.cxx @@ -1,7 +1,7 @@ // magvar.cxx -- compute local magnetic variation given position, // altitude, and date // -// This is an implimentation of the NIMA WMM 2000 +// This is an implementation of the NIMA (formerly DMA) WMM2000 // // http://www.nima.mil/GandG/ngdc-wmm2000.html // @@ -20,6 +20,32 @@ // save many sqrt() calls on subsequent invocations // left old code as SGMagVarOrig() for testing purposes // 3/28/2000 Norman Vine -- nhv@yahoo.com +// +// Put in some bullet-proofing to handle magnetic and geographic poles. +// 3/28/2000 EAW + +// The routine uses a spherical harmonic expansion of the magnetic +// potential up to twelfth order, together with its time variation, as +// described in Chapter 4 of "Geomagnetism, Vol 1, Ed. J.A.Jacobs, +// Academic Press (London 1987)". The program first converts geodetic +// coordinates (lat/long on elliptic earth and altitude) to spherical +// geocentric (spherical lat/long and radius) coordinates. Using this, +// the spherical (B_r, B_theta, B_phi) magnetic field components are +// computed from the model. These are finally referred to surface (X, Y, +// Z) coordinates. +// +// Fields are accurate to better than 200nT, variation and dip to +// better than 0.5 degrees, with the exception of the declination near +// the magnetic poles (where it is ill-defined) where the error may reach +// 4 degrees or more. +// +// Variation is undefined at both the geographic and +// magnetic poles, even though the field itself is well-behaved. To +// avoid the routine blowing up, latitude entries corresponding to +// the geographic poles are slightly offset. At the magnetic poles, +// the routine returns zero variation. + + // // This program is free software; you can redistribute it and/or // modify it under the terms of the GNU General Public License as @@ -180,7 +206,7 @@ double SGMagVar( double lat, double lon, double h, long dat, double* field ) double sinpsi, cospsi, inv_s; static int been_here = 0; - + double sinlat = sin(lat); double coslat = cos(lat); @@ -201,9 +227,10 @@ double SGMagVar( double lat, double lon, double h, long dat, double* field ) /* r is geocentric radial distance */ c = cos(theta); s = sin(theta); - inv_s = 1.0 / s; + /* protect against zero divide at geographic poles */ + inv_s = 1.0 / (s + (s == 0.)*1.0e-8); - /*zero out arrays */ + /* zero out arrays */ for ( n = 0; n <= nmax; n++ ) { for ( m = 0; m <= n; m++ ) { P[n][m] = 0; @@ -224,7 +251,7 @@ double SGMagVar( double lat, double lon, double h, long dat, double* field ) for ( n = 2; n <= nmax; n++ ) { root[n] = sqrt((2.0*n-1) / (2.0*n)); } - + for ( m = 0; m <= nmax; m++ ) { double mm = m*m; for ( n = max(m + 1, 2); n <= nmax; n++ ) { @@ -234,7 +261,7 @@ double SGMagVar( double lat, double lon, double h, long dat, double* field ) } been_here = 1; } - + for ( n=2; n <= nmax; n++ ) { // double root = sqrt((2.0*n-1) / (2.0*n)); P[n][n] = P[n-1][n-1] * s * root[n]; @@ -251,7 +278,7 @@ double SGMagVar( double lat, double lon, double h, long dat, double* field ) P[n][m] = (P[n-1][m] * c * (2.0*n-1) - P[n-2][m] * roots[m][n][0]) * roots[m][n][1]; - + DP[n][m] = ((DP[n-1][m] * c - P[n-1][m] * s) * (2.0*n-1) - DP[n-2][m] * roots[m][n][0]) * roots[m][n][1]; @@ -280,7 +307,7 @@ double SGMagVar( double lat, double lon, double h, long dat, double* field ) B_phi = 0.0; fn_0 = r_0/r; fn = fn_0 * fn_0; - + for ( n = 1; n <= nmax; n++ ) { double c1_n=0; double c2_n=0; @@ -313,8 +340,10 @@ double SGMagVar( double lat, double lon, double h, long dat, double* field ) field[4]=Y; field[5]=Z; /* output fields */ - /* find variation, leave in radians! */ - return atan2(Y, X); /* E is positive */ + /* find variation in radians */ + /* return zero variation at magnetic pole X=Y=0. */ + /* E is positive */ + return (X != 0. || Y != 0.) ? atan2(Y, X) : (double) 0.; } @@ -341,11 +370,11 @@ double SGMagVarOrig( double lat, double lon, double h, long dat, double* field ) r = sqrt(r); - /* r is geocentric radial distance */ + /* r is geocentric radial distance */ c = cos(theta); s = sin(theta); - /*zero out arrays */ + /* zero out arrays */ for ( n = 0; n <= nmax; n++ ) { for ( m = 0; m <= n; m++ ) { P[n][m] = 0; @@ -429,7 +458,7 @@ double SGMagVarOrig( double lat, double lon, double h, long dat, double* field ) field[4]=Y; field[5]=Z; /* output fields */ - /* find variation, leave in radians! */ + /* find variation, leave in radians! */ return atan2(Y, X); /* E is positive */ } #endif // TEST_NHV_HACKS