// Calculate ILS heading #include #include #include #include #include STL_STRING #include #include SG_USING_STD(string); SG_USING_STD(cout); SG_USING_STD(endl); int main( int argc, char **argv ) { if ( argc != 9 ) { cout << "Wrong usage" << endl; } double loc_lat = atof( argv[1] ); double loc_lon = atof( argv[2] ); string dir = argv[3]; double rwy_lat = atof( argv[4] ); double rwy_lon = atof( argv[5] ); double rwy_hdg = atof( argv[6] ); double rwy_len = atof( argv[7] ) * SG_DEGREES_TO_RADIANS; double rwy_wid = atof( argv[8] ); if ( dir == "FOR" ) { rwy_hdg += 180.0; if ( rwy_hdg > 360.0 ) { rwy_hdg -= 360.0; } } // calculate runway threshold point double thresh_lat, thresh_lon, return_az; geo_direct_wgs_84 ( 0.0, rwy_lat, rwy_lon, rwy_hdg, rwy_len / 2.0, &thresh_lat, &thresh_lon, &return_az ); cout << "Threshold = " << thresh_lat << "," << thresh_lon << endl; // calculate distance from threshold to localizer double az1, az2, dist_m; geo_inverse_wgs_84( 0.0, loc_lat, loc_lon, thresh_lat, thresh_lon, &az1, &az2, &dist_m ); cout << "Distance = " << dist_m << endl; // back project that distance along the runway center line double nloc_lat, nloc_lon; geo_direct_wgs_84 ( 0.0, thresh_lat, thresh_lon, rwy_hdg + 180.0, dist_m, &nloc_lat, &nloc_lon, &return_az ); printf("New localizer = %.6f %.6f\n", nloc_lat, nloc_lon ); return 0; }