// gps.cxx - distance-measuring equipment. // Written by David Megginson, started 2003. // // This file is in the Public Domain and comes with no warranty. #ifdef HAVE_CONFIG_H # include #endif #include #include #include #include #include #include #include
#include
#include
#include
#include #include #include "gps.hxx" SG_USING_STD(string); GPS::GPS ( SGPropertyNode *node) : _last_valid(false), _last_longitude_deg(0), _last_latitude_deg(0), _last_altitude_m(0), _last_speed_kts(0) { int i; for ( i = 0; i < node->nChildren(); ++i ) { SGPropertyNode *child = node->getChild(i); string cname = child->getName(); string cval = child->getStringValue(); if ( cname == "name" ) { name = cval; } else if ( cname == "number" ) { num = child->getIntValue(); } else { SG_LOG( SG_INSTR, SG_WARN, "Error in gps config logic" ); if ( name.length() ) { SG_LOG( SG_INSTR, SG_WARN, "Section = " << name ); } } } } GPS::GPS () : _last_valid(false), _last_longitude_deg(0), _last_latitude_deg(0), _last_altitude_m(0), _last_speed_kts(0) { } GPS::~GPS () { } void GPS::init () { route = new SGRoute; route->clear(); string branch; branch = "/instrumentation/" + name; SGPropertyNode *node = fgGetNode(branch.c_str(), num, true ); _longitude_node = fgGetNode("/position/longitude-deg", true); _latitude_node = fgGetNode("/position/latitude-deg", true); _altitude_node = fgGetNode("/position/altitude-ft", true); _magvar_node = fgGetNode("/environment/magnetic-variation-deg", true); _serviceable_node = node->getChild("serviceable", 0, true); _electrical_node = fgGetNode("/systems/electrical/outputs/gps", true); SGPropertyNode *wp_node = node->getChild("wp", 0, true); SGPropertyNode *wp0_node = wp_node->getChild("wp", 0, true); SGPropertyNode *wp1_node = wp_node->getChild("wp", 1, true); addWp = wp1_node->getChild("Add-to-route", 0, true); _wp0_longitude_node = wp0_node->getChild("longitude-deg", 0, true); _wp0_latitude_node = wp0_node->getChild("latitude-deg", 0, true); _wp0_altitude_node = wp0_node->getChild("altitude-deg", 0, true); _wp0_ID_node = wp0_node->getChild("ID", 0, true); _wp0_name_node = wp0_node->getChild("name", 0, true); _wp0_course_node = wp0_node->getChild("desired-course-deg", 0, true); _wp0_waypoint_type_node = wp0_node->getChild("waypoint-type", 0, true); _wp0_distance_node = wp0_node->getChild("distance-nm", 0, true); _wp0_ttw_node = wp0_node->getChild("TTW", 0, true); _wp0_bearing_node = wp0_node->getChild("bearing-true-deg", 0, true); _wp0_mag_bearing_node = wp0_node->getChild("bearing-mag-deg", 0, true); _wp0_course_deviation_node = wp0_node->getChild("course-deviation-deg", 0, true); _wp0_course_error_nm_node = wp0_node->getChild("course-error-nm", 0, true); _wp0_to_flag_node = wp0_node->getChild("to-flag", 0, true); _true_wp0_bearing_error_node = wp0_node->getChild("true-bearing-error-deg", 0, true); _magnetic_wp0_bearing_error_node = wp0_node->getChild("magnetic-bearing-error-deg", 0, true); _wp1_longitude_node = wp1_node->getChild("longitude-deg", 0, true); _wp1_latitude_node = wp1_node->getChild("latitude-deg", 0, true); _wp1_altitude_node = wp1_node->getChild("altitude-deg", 0, true); _wp1_ID_node = wp1_node->getChild("ID", 0, true); _wp1_name_node = wp1_node->getChild("name", 0, true); _wp1_course_node = wp1_node->getChild("desired-course-deg", 0, true); _wp1_waypoint_type_node = wp1_node->getChild("waypoint-type", 0, true); _wp1_distance_node = wp1_node->getChild("distance-nm", 0, true); _wp1_ttw_node = wp1_node->getChild("TTW", 0, true); _wp1_bearing_node = wp1_node->getChild("bearing-true-deg", 0, true); _wp1_mag_bearing_node = wp1_node->getChild("bearing-mag-deg", 0, true); _wp1_course_deviation_node = wp1_node->getChild("course-deviation-deg", 0, true); _wp1_course_error_nm_node = wp1_node->getChild("course-error-nm", 0, true); _wp1_to_flag_node = wp1_node->getChild("to-flag", 0, true); _true_wp1_bearing_error_node = wp1_node->getChild("true-bearing-error-deg", 0, true); _magnetic_wp1_bearing_error_node = wp1_node->getChild("magnetic-bearing-error-deg", 0, true); _get_nearest_airport_node = wp1_node->getChild("get-nearest-airport", 0, true); _tracking_bug_node = node->getChild("tracking-bug", 0, true); _raim_node = node->getChild("raim", 0, true); _indicated_longitude_node = node->getChild("indicated-longitude-deg", 0, true); _indicated_latitude_node = node->getChild("indicated-latitude-deg", 0, true); _indicated_altitude_node = node->getChild("indicated-altitude-ft", 0, true); _indicated_vertical_speed_node = node->getChild("indicated-vertical-speed", 0, true); _true_track_node = node->getChild("indicated-track-true-deg", 0, true); _magnetic_track_node = node->getChild("indicated-track_magnetic-deg", 0, true); _speed_node = node->getChild("indicated-ground-speed-kt", 0, true); _odometer_node = node->getChild("odometer", 0, true); _trip_odometer_node = node->getChild("trip-odometer", 0, true); _true_bug_error_node = node->getChild("true-bug-error-deg", 0, true); _magnetic_bug_error_node = node->getChild("magnetic-bug-error-deg", 0, true); _leg_distance_node = wp_node->getChild("leg-distance-nm", 0, true); _leg_course_node = wp_node->getChild("leg-true-course-deg", 0, true); _leg_magnetic_course_node = wp_node->getChild("leg-mag-course-deg", 0, true); _alt_dist_ratio_node = wp_node->getChild("alt-dist-ratio", 0, true); _leg_course_deviation_node = wp_node->getChild("leg-course-deviation-deg", 0, true); _leg_course_error_nm_node = wp_node->getChild("leg-course-error-nm", 0, true); _leg_to_flag_node = wp_node->getChild("leg-to-flag", 0, true); _alt_deviation_node = wp_node->getChild("alt-deviation-ft", 0, true); _route = node->getChild("route", 0, true); popWp = _route->getChild("Pop-WP", 0, true); addWp->setBoolValue(false); popWp->setBoolValue(false); _serviceable_node->setBoolValue(true); } void GPS::update (double delta_time_sec) { // If it's off, don't bother. if (!_serviceable_node->getBoolValue() || !_electrical_node->getBoolValue()) { _last_valid = false; _last_longitude_deg = 0; _last_latitude_deg = 0; _last_altitude_m = 0; _last_speed_kts = 0; _raim_node->setDoubleValue(false); _indicated_longitude_node->setDoubleValue(0); _indicated_latitude_node->setDoubleValue(0); _indicated_altitude_node->setDoubleValue(0); _indicated_vertical_speed_node->setDoubleValue(0); _true_track_node->setDoubleValue(0); _magnetic_track_node->setDoubleValue(0); _speed_node->setDoubleValue(0); _wp1_distance_node->setDoubleValue(0); _wp1_bearing_node->setDoubleValue(0); _wp1_longitude_node->setDoubleValue(0); _wp1_latitude_node->setDoubleValue(0); _wp1_course_node->setDoubleValue(0); _odometer_node->setDoubleValue(0); _trip_odometer_node->setDoubleValue(0); _tracking_bug_node->setDoubleValue(0); _true_bug_error_node->setDoubleValue(0); _magnetic_bug_error_node->setDoubleValue(0); _true_wp1_bearing_error_node->setDoubleValue(0); _magnetic_wp1_bearing_error_node->setDoubleValue(0); return; } // Get the aircraft position // TODO: Add noise and other errors. double longitude_deg = _longitude_node->getDoubleValue(); double latitude_deg = _latitude_node->getDoubleValue(); double altitude_m = _altitude_node->getDoubleValue() * SG_FEET_TO_METER; double magvar_deg = _magvar_node->getDoubleValue(); /* // Bias and random error double random_factor = sg_random(); double random_error = 1.4; double error_radius = 5.1; double bias_max_radius = 5.1; double random_max_radius = 1.4; bias_length += (random_factor-0.5) * 1.0e-3; if (bias_length <= 0.0) bias_length = 0.0; else if (bias_length >= bias_max_radius) bias_length = bias_max_radius; bias_angle += (random_factor-0.5) * 1.0e-3; if (bias_angle <= 0.0) bias_angle = 0.0; else if (bias_angle >= 360.0) bias_angle = 360.0; double random_length = random_factor * random_max_radius; double random_angle = random_factor * 360.0; double bias_x = bias_length * cos(bias_angle * SG_PI / 180.0); double bias_y = bias_length * sin(bias_angle * SG_PI / 180.0); double random_x = random_length * cos(random_angle * SG_PI / 180.0); double random_y = random_length * sin(random_angle * SG_PI / 180.0); double error_x = bias_x + random_x; double error_y = bias_y + random_y; double error_length = sqrt(error_x*error_x + error_y*error_y); double error_angle = atan(error_y / error_x) * 180.0 / SG_PI; double lat2; double lon2; double az2; geo_direct_wgs_84 ( altitude_m, latitude_deg, longitude_deg, error_angle, error_length, &lat2, &lon2, &az2 ); //cout << lat2 << " " << lon2 << endl; printf("%f %f \n", bias_length, bias_angle); printf("%3.7f %3.7f \n", lat2, lon2); printf("%f %f \n", error_length, error_angle); */ double speed_kt, vertical_speed_mpm; _raim_node->setBoolValue(true); _indicated_longitude_node->setDoubleValue(longitude_deg); _indicated_latitude_node->setDoubleValue(latitude_deg); _indicated_altitude_node->setDoubleValue(altitude_m * SG_METER_TO_FEET); if (_last_valid) { double track1_deg, track2_deg, distance_m, odometer, mag_track_bearing; geo_inverse_wgs_84(altitude_m, _last_latitude_deg, _last_longitude_deg, latitude_deg, longitude_deg, &track1_deg, &track2_deg, &distance_m); speed_kt = ((distance_m * SG_METER_TO_NM) * ((1 / delta_time_sec) * 3600.0)); vertical_speed_mpm = ((altitude_m - _last_altitude_m) * 60 / delta_time_sec); _indicated_vertical_speed_node->setDoubleValue (vertical_speed_mpm * SG_METER_TO_FEET); _true_track_node->setDoubleValue(track1_deg); mag_track_bearing = track1_deg - magvar_deg; SG_NORMALIZE_RANGE(mag_track_bearing, 0.0, 360.0); _magnetic_track_node->setDoubleValue(mag_track_bearing); speed_kt = fgGetLowPass(_last_speed_kts, speed_kt, delta_time_sec/20.0); _last_speed_kts = speed_kt; _speed_node->setDoubleValue(speed_kt); odometer = _odometer_node->getDoubleValue(); _odometer_node->setDoubleValue(odometer + distance_m * SG_METER_TO_NM); odometer = _trip_odometer_node->getDoubleValue(); _trip_odometer_node->setDoubleValue(odometer + distance_m * SG_METER_TO_NM); // Get waypoint 0 position double wp0_longitude_deg = _wp0_longitude_node->getDoubleValue(); double wp0_latitude_deg = _wp0_latitude_node->getDoubleValue(); double wp0_altitude_m = _wp0_altitude_node->getDoubleValue() * SG_FEET_TO_METER; double wp0_course_deg = _wp0_course_node->getDoubleValue(); double wp0_distance, wp0_bearing_deg, wp0_course_deviation_deg, wp0_course_error_m, wp0_TTW, wp0_bearing_error_deg; string wp0_ID = _wp0_ID_node->getStringValue(); // Get waypoint 1 position double wp1_longitude_deg = _wp1_longitude_node->getDoubleValue(); double wp1_latitude_deg = _wp1_latitude_node->getDoubleValue(); double wp1_altitude_m = _wp1_altitude_node->getDoubleValue() * SG_FEET_TO_METER; double wp1_course_deg = _wp1_course_node->getDoubleValue(); double wp1_distance, wp1_bearing_deg, wp1_course_deviation_deg, wp1_course_error_m, wp1_TTW, wp1_bearing_error_deg; string wp1_ID = _wp1_ID_node->getStringValue(); // If the get-nearest-airport-node is true. // Get the nearest airport, and set it as waypoint 1. if (_get_nearest_airport_node->getBoolValue()) { FGAirport a; //cout << "Airport found" << endl; a = globals->get_airports()->search(longitude_deg, latitude_deg, false); _wp1_ID_node->setStringValue(a.getId().c_str()); wp1_longitude_deg = a.getLongitude(); wp1_latitude_deg = a.getLatitude(); _wp1_name_node->setStringValue(a.getName().c_str()); _get_nearest_airport_node->setBoolValue(false); _last_wp1_ID = wp1_ID = a.getId().c_str(); } // If the waypoint 0 ID has changed, try to find the new ID // in the airport-, fix-, nav-database. if ( !(_last_wp0_ID == wp0_ID) ) { string waypont_type = _wp0_waypoint_type_node->getStringValue(); if (waypont_type == "airport") { FGAirport a; a = globals->get_airports()->search( wp0_ID ); if ( a.getId() == wp0_ID ) { //cout << "Airport found" << endl; wp0_longitude_deg = a.getLongitude(); wp0_latitude_deg = a.getLatitude(); _wp0_name_node->setStringValue(a.getName().c_str()); } } else if (waypont_type == "nav") { FGNavRecord *n = globals->get_navlist()->findByIdent(wp0_ID.c_str(), longitude_deg, latitude_deg); if ( n != NULL ) { //cout << "Nav found" << endl; wp0_longitude_deg = n->get_lon(); wp0_latitude_deg = n->get_lat(); _wp0_name_node->setStringValue(n->get_name().c_str()); } } else if (waypont_type == "fix") { FGFix f; if ( globals->get_fixlist()->query(wp0_ID, &f) ) { //cout << "Fix found" << endl; wp0_longitude_deg = f.get_lon(); wp0_latitude_deg = f.get_lat(); _wp0_name_node->setStringValue(wp0_ID.c_str()); } } _last_wp0_ID = wp0_ID; } // If the waypoint 1 ID has changed, try to find the new ID // in the airport-, fix-, nav-database. if ( !(_last_wp1_ID == wp1_ID) ) { string waypont_type = _wp1_waypoint_type_node->getStringValue(); if (waypont_type == "airport") { FGAirport a; a = globals->get_airports()->search( wp1_ID ); if ( a.getId() == wp1_ID ) { //cout << "Airport found" << endl; wp1_longitude_deg = a.getLongitude(); wp1_latitude_deg = a.getLatitude(); _wp1_name_node->setStringValue(a.getName().c_str()); } } else if (waypont_type == "nav") { FGNavRecord *n = globals->get_navlist()->findByIdent(wp1_ID.c_str(), longitude_deg, latitude_deg); if ( n != NULL ) { //cout << "Nav found" << endl; wp1_longitude_deg = n->get_lon(); wp1_latitude_deg = n->get_lat(); _wp1_name_node->setStringValue(n->get_name().c_str()); } } else if (waypont_type == "fix") { FGFix f; if ( globals->get_fixlist()->query(wp1_ID, &f) ) { //cout << "Fix found" << endl; wp1_longitude_deg = f.get_lon(); wp1_latitude_deg = f.get_lat(); _wp1_name_node->setStringValue(wp1_ID.c_str()); } } _last_wp1_ID = wp1_ID; } // If any of the two waypoints have changed // we need to calculate a new course between them, // and values for vertical navigation. if ( wp0_longitude_deg != _wp0_longitude_deg || wp0_latitude_deg != _wp0_latitude_deg || wp0_altitude_m != _wp0_altitude_m || wp1_longitude_deg != _wp1_longitude_deg || wp1_latitude_deg != _wp1_latitude_deg || wp1_altitude_m != _wp1_altitude_m ) { // Update the global variables _wp0_longitude_deg = wp0_longitude_deg; _wp0_latitude_deg = wp0_latitude_deg; _wp0_altitude_m = wp0_altitude_m; _wp1_longitude_deg = wp1_longitude_deg; _wp1_latitude_deg = wp1_latitude_deg; _wp1_altitude_m = wp1_altitude_m; // Get the course and distance from wp0 to wp1 SGWayPoint wp0(wp0_longitude_deg, wp0_latitude_deg, wp0_altitude_m); SGWayPoint wp1(wp1_longitude_deg, wp1_latitude_deg, wp1_altitude_m); wp1.CourseAndDistance(wp0, &_course_deg, &_distance_m); double leg_mag_course = _course_deg - magvar_deg; SG_NORMALIZE_RANGE(leg_mag_course, 0.0, 360.0); // Get the altitude / distance ratio if ( distance_m > 0.0 ) { double alt_difference_m = wp0_altitude_m - wp1_altitude_m; _alt_dist_ratio = alt_difference_m / _distance_m; } _leg_distance_node->setDoubleValue(_distance_m * SG_METER_TO_NM); _leg_course_node->setDoubleValue(_course_deg); _leg_magnetic_course_node->setDoubleValue(leg_mag_course); _alt_dist_ratio_node->setDoubleValue(_alt_dist_ratio); _wp0_longitude_node->setDoubleValue(wp0_longitude_deg); _wp0_latitude_node->setDoubleValue(wp0_latitude_deg); _wp1_longitude_node->setDoubleValue(wp1_longitude_deg); _wp1_latitude_node->setDoubleValue(wp1_latitude_deg); } // Find the bearing and distance to waypoint 0. SGWayPoint wp0(wp0_longitude_deg, wp0_latitude_deg, wp0_altitude_m); wp0.CourseAndDistance(longitude_deg, latitude_deg, altitude_m, &wp0_bearing_deg, &wp0_distance); _wp0_distance_node->setDoubleValue(wp0_distance * SG_METER_TO_NM); _wp0_bearing_node->setDoubleValue(wp0_bearing_deg); double wp0_mag_bearing_deg = wp0_bearing_deg - magvar_deg; SG_NORMALIZE_RANGE(wp0_mag_bearing_deg, 0.0, 360.0); _wp0_mag_bearing_node->setDoubleValue(wp0_mag_bearing_deg); wp0_bearing_error_deg = track1_deg - wp0_bearing_deg; SG_NORMALIZE_RANGE(wp0_bearing_error_deg, -180.0, 180.0); _true_wp0_bearing_error_node->setDoubleValue(wp0_bearing_error_deg); // Estimate time to waypoint 0. // The estimation does not take track into consideration, // so if you are going away from the waypoint the TTW will // increase. Makes most sense when travelling directly towards // the waypoint. if (speed_kt > 0.0 && wp0_distance > 0.0) { wp0_TTW = (wp0_distance * SG_METER_TO_NM) / (speed_kt / 3600); } else { wp0_TTW = 0.0; } unsigned int wp0_TTW_seconds = (int) (wp0_TTW + 0.5); if (wp0_TTW_seconds < 356400) { // That's 99 hours unsigned int wp0_TTW_minutes = 0; unsigned int wp0_TTW_hours = 0; char wp0_TTW_str[9]; while (wp0_TTW_seconds >= 3600) { wp0_TTW_seconds -= 3600; wp0_TTW_hours++; } while (wp0_TTW_seconds >= 60) { wp0_TTW_seconds -= 60; wp0_TTW_minutes++; } snprintf(wp0_TTW_str, 9, "%02d:%02d:%02d", wp0_TTW_hours, wp0_TTW_minutes, wp0_TTW_seconds); _wp0_ttw_node->setStringValue(wp0_TTW_str); } else _wp0_ttw_node->setStringValue("--:--:--"); // Course deviation is the diffenrence between the bearing // and the course. wp0_course_deviation_deg = wp0_bearing_deg - wp0_course_deg; SG_NORMALIZE_RANGE(wp0_course_deviation_deg, -180.0, 180.0); // If the course deviation is less than 90 degrees to either side, // our desired course is towards the waypoint. // It does not matter if we are actually moving // towards or from the waypoint. if (fabs(wp0_course_deviation_deg) < 90.0) { _wp0_to_flag_node->setBoolValue(true); } // If it's more than 90 degrees the desired // course is from the waypoint. else if (fabs(wp0_course_deviation_deg) > 90.0) { _wp0_to_flag_node->setBoolValue(false); // When the course is away from the waypoint, // it makes sense to change the sign of the deviation. wp0_course_deviation_deg *= -1.0; SG_NORMALIZE_RANGE(wp0_course_deviation_deg, -90.0, 90.0); } _wp0_course_deviation_node->setDoubleValue(wp0_course_deviation_deg); // Cross track error. wp0_course_error_m = sin(wp0_course_deviation_deg * SG_PI / 180.0) * (wp0_distance); _wp0_course_error_nm_node->setDoubleValue(wp0_course_error_m * SG_METER_TO_NM); // Find the bearing and distance to waypoint 1. SGWayPoint wp1(wp1_longitude_deg, wp1_latitude_deg, wp1_altitude_m); wp1.CourseAndDistance(longitude_deg, latitude_deg, altitude_m, &wp1_bearing_deg, &wp1_distance); _wp1_distance_node->setDoubleValue(wp1_distance * SG_METER_TO_NM); _wp1_bearing_node->setDoubleValue(wp1_bearing_deg); double wp1_mag_bearing_deg = wp1_bearing_deg - magvar_deg; SG_NORMALIZE_RANGE(wp1_mag_bearing_deg, 0.0, 360.0); _wp1_mag_bearing_node->setDoubleValue(wp1_mag_bearing_deg); wp1_bearing_error_deg = track1_deg - wp1_bearing_deg; SG_NORMALIZE_RANGE(wp1_bearing_error_deg, -180.0, 180.0); _true_wp1_bearing_error_node->setDoubleValue(wp1_bearing_error_deg); // Estimate time to waypoint 1. // The estimation does not take track into consideration, // so if you are going away from the waypoint the TTW will // increase. Makes most sense when travelling directly towards // the waypoint. if (speed_kt > 0.0 && wp1_distance > 0.0) { wp1_TTW = (wp1_distance * SG_METER_TO_NM) / (speed_kt / 3600); } else { wp1_TTW = 0.0; } unsigned int wp1_TTW_seconds = (int) (wp1_TTW + 0.5); if (wp1_TTW_seconds < 356400) { // That's 99 hours unsigned int wp1_TTW_minutes = 0; unsigned int wp1_TTW_hours = 0; char wp1_TTW_str[9]; while (wp1_TTW_seconds >= 3600) { wp1_TTW_seconds -= 3600; wp1_TTW_hours++; } while (wp1_TTW_seconds >= 60) { wp1_TTW_seconds -= 60; wp1_TTW_minutes++; } snprintf(wp1_TTW_str, 9, "%02d:%02d:%02d", wp1_TTW_hours, wp1_TTW_minutes, wp1_TTW_seconds); _wp1_ttw_node->setStringValue(wp1_TTW_str); } else _wp1_ttw_node->setStringValue("--:--:--"); // Course deviation is the diffenrence between the bearing // and the course. wp1_course_deviation_deg = wp1_bearing_deg - wp1_course_deg; SG_NORMALIZE_RANGE(wp1_course_deviation_deg, -180.0, 180.0); // If the course deviation is less than 90 degrees to either side, // our desired course is towards the waypoint. // It does not matter if we are actually moving // towards or from the waypoint. if (fabs(wp1_course_deviation_deg) < 90.0) { _wp1_to_flag_node->setBoolValue(true); } // If it's more than 90 degrees the desired // course is from the waypoint. else if (fabs(wp1_course_deviation_deg) > 90.0) { _wp1_to_flag_node->setBoolValue(false); // When the course is away from the waypoint, // it makes sense to change the sign of the deviation. wp1_course_deviation_deg *= -1.0; SG_NORMALIZE_RANGE(wp1_course_deviation_deg, -90.0, 90.0); } _wp1_course_deviation_node->setDoubleValue(wp1_course_deviation_deg); // Cross track error. wp1_course_error_m = sin(wp1_course_deviation_deg * SG_PI / 180.0) * (wp1_distance); _wp1_course_error_nm_node->setDoubleValue(wp1_course_error_m * SG_METER_TO_NM); // Leg course deviation is the diffenrence between the bearing // and the course. double course_deviation_deg = wp1_bearing_deg - _course_deg; SG_NORMALIZE_RANGE(course_deviation_deg, -180.0, 180.0); // If the course deviation is less than 90 degrees to either side, // our desired course is towards the waypoint. // It does not matter if we are actually moving // towards or from the waypoint. if (fabs(course_deviation_deg) < 90.0) { _leg_to_flag_node->setBoolValue(true); } // If it's more than 90 degrees the desired // course is from the waypoint. else if (fabs(course_deviation_deg) > 90.0) { _leg_to_flag_node->setBoolValue(false); // When the course is away from the waypoint, // it makes sense to change the sign of the deviation. course_deviation_deg *= -1.0; SG_NORMALIZE_RANGE(course_deviation_deg, -90.0, 90.0); } _leg_course_deviation_node->setDoubleValue(course_deviation_deg); // Cross track error. double course_error_m = sin(course_deviation_deg * SG_PI / 180.0) * (_distance_m); _leg_course_error_nm_node->setDoubleValue(course_error_m * SG_METER_TO_NM); // Altitude deviation double desired_altitude_m = wp1_altitude_m + wp1_distance * _alt_dist_ratio; double altitude_deviation_m = altitude_m - desired_altitude_m; _alt_deviation_node->setDoubleValue(altitude_deviation_m * SG_METER_TO_FEET); // Tracking bug. double tracking_bug = _tracking_bug_node->getDoubleValue(); double true_bug_error = tracking_bug - track1_deg; double magnetic_bug_error = tracking_bug - mag_track_bearing; // Get the errors into the (-180,180) range. SG_NORMALIZE_RANGE(true_bug_error, -180.0, 180.0); SG_NORMALIZE_RANGE(magnetic_bug_error, -180.0, 180.0); _true_bug_error_node->setDoubleValue(true_bug_error); _magnetic_bug_error_node->setDoubleValue(magnetic_bug_error); // Add WP 1 to the route. if ( addWp->getBoolValue() ) { addWp->setBoolValue(false); SGWayPoint tempWp( _wp1_longitude_node->getDoubleValue(), _wp1_latitude_node->getDoubleValue(), _wp1_altitude_node->getDoubleValue(), SGWayPoint::WGS84, _wp1_ID_node->getStringValue(), _wp1_name_node->getStringValue() ); route->add_waypoint(tempWp); SGPropertyNode *wp = _route->getChild("Waypoint", route->size()-1, true); SGPropertyNode *id = wp->getChild("ID", 0, true); SGPropertyNode *name = wp->getChild("Name", 0, true); SGPropertyNode *lat = wp->getChild("Latitude", 0, true); SGPropertyNode *lon = wp->getChild("Longitude", 0, true); SGPropertyNode *alt = wp->getChild("Altitude", 0, true); id->setStringValue( tempWp.get_id().c_str() ); name->setStringValue( tempWp.get_name().c_str() ); lat->setDoubleValue( tempWp.get_target_lat() ); lon->setDoubleValue( tempWp.get_target_lon() ); alt->setDoubleValue( tempWp.get_target_alt() ); } if ( popWp->getBoolValue() ) { popWp->setBoolValue(false); route->delete_first(); _route->removeChild("Waypoint", 0, false); } } else { _true_track_node->setDoubleValue(0.0); _magnetic_track_node->setDoubleValue(0.0); _speed_node->setDoubleValue(0.0); } _last_valid = true; _last_longitude_deg = longitude_deg; _last_latitude_deg = latitude_deg; _last_altitude_m = altitude_m; } // end of gps.cxx