東北大学学友会準加盟団体 From The Earth の高高度ロケットFTE-06(通称:海豚)にて使用したソフトウェアです.ご自由にお使いください.このプログラムによって生じた損害について当団体は一切責任を負いません.また,各モジュールのライブラリは当団体が作成したものではないので再配布は禁止します.
Dependencies: mbed FATFileSystem
Fork of FTE-06 by
Diff: GPS/GPS.cpp
- Revision:
- 46:a8617076f021
- Child:
- 48:58213015bb90
--- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/GPS/GPS.cpp Mon Aug 21 16:24:34 2017 +0000 @@ -0,0 +1,287 @@ +#include "GPS.h" + +GPS::GPS(PinName tx, PinName rx) : _gps(tx, rx) { + _gps.baud(9600); + nmea_longitude = 0.0; + nmea_latitude = 0.0; + utc_time = 0; + ns = ' '; + ew = ' '; + lock = 0; + satelites = 0; + hdop = 0.0; + msl_altitude = 0.0; + msl_units = ' '; + + rmc_status = ' '; + speed_k = 0.0; + course_d = 0.0; + date = 0; + + dec_longitude = 0.0; + dec_latitude = 0.0; + + gll_status = ' '; + + course_t = 0.0; // ground speed true + course_t_unit = ' '; + course_m = 0.0; // magnetic + course_m_unit = ' '; + speed_k_unit = ' '; + speed_km = 0.0; // speek km/hr + speed_km_unit = ' '; + + altitude_ft = 0.0; +#ifdef OPEN_LOG + is_logging = false; +#endif +} + +#ifdef OPEN_LOG +void GPS::start_log() { + is_logging = true; +} + +void GPS::new_file(void) { + _openLog.newFile(); +} + +void GPS::stop_log(void) { + is_logging = false; +} +#endif + +float GPS::nmea_to_dec(float deg_coord, char nsew) { + int degree = (int)(deg_coord/100); + float minutes = deg_coord - degree*100; + float dec_deg = minutes / 60; + float decimal = degree + dec_deg; + if (nsew == 'S' || nsew == 'W') { // return negative + decimal *= -1; + } + return decimal; +} + +int GPS::sample() { + int line_parsed = 0; + + if (_gps.readable()) { + getline(); + +#ifdef OPEN_LOG + if (is_logging && lock) { + format_for_log(); + _openLog.write(bfr); + } +#endif + + // Check if it is a GPGGA msg (matches both locked and non-locked msg) + if (sscanf(msg, "GPGGA,%f,%f,%c,%f,%c,%d,%d,%f,%f,%c", &utc_time, &nmea_latitude, &ns, &nmea_longitude, &ew, &lock, &satelites, &hdop, &msl_altitude, &msl_units) >= 1) { + line_parsed = GGA; + } + // Check if it is a GPRMC msg + else if (sscanf(msg, "GPRMC,%f,%c,%f,%c,%f,%f,%d", &utc_time, &ns, &nmea_longitude, &ew, &speed_k, &course_d, &date) >= 1) { + line_parsed = RMC; + } + // GLL - Geographic Position-Lat/Lon + else if (sscanf(msg, "GPGLL,%f,%c,%f,%c,%f,%c", &nmea_latitude, &ns, &nmea_longitude, &ew, &utc_time, &gll_status) >= 1) { + line_parsed = GLL; + } + // VTG-Course Over Ground and Ground Speed + else if (sscanf(msg, "GPVTG,%f,%c,%f,%c,%f,%c,%f,%c", &course_t, &course_t_unit, &course_m, &course_m_unit, &speed_k, &speed_k_unit, &speed_km, &speed_km_unit) >= 1) { + line_parsed = VTG; + } + + if(satelites == 0) { + lock = 0; + } + } + if (!lock) { + return NO_LOCK; + } else if (line_parsed) { + return line_parsed; + } else { + return NOT_PARSED; + } +} + + +// INTERNAL FUNCTINS //////////////////////////////////////////////////////////// +float GPS::trunc(float v) { + if (v < 0.0) { + v*= -1.0; + v = floor(v); + v*=-1.0; + } else { + v = floor(v); + } + return v; +} + +void GPS::getline() { + while (_gps.getc() != '$'); // wait for the start of a line + for (int i=0; i<1022; i++) { + msg[i] = _gps.getc(); + if (msg[i] == '\r') { + msg[i] = 0; + return; + } + } + error("Overflow in getline"); +} + +void GPS::format_for_log() { + bfr[0] = '$'; + for (int i = 0; i < 1022; i++) { + bfr[i+1] = msg[i]; + if (msg[i] == 0 || msg[i] =='$') { + bfr[i+1] = '\r'; + bfr[i+2] = '\n'; + bfr[i+3] = 0; + return; + } + } + error("Overflow in format"); +} + +// GET FUNCTIONS ///////////////////////////////////////////////////////////////// +float GPS::get_msl_altitude() { + if (!lock) + return 0.0; + else + return msl_altitude; +} + +int GPS::get_satelites() { + if (!lock) + return 0; + else + return satelites; +} + +float GPS::get_nmea_longitude() { + if (!lock) + return 0.0; + else + return nmea_longitude; +} + +float GPS::get_dec_longitude() { + dec_longitude = nmea_to_dec(nmea_longitude, ew); + if (!lock) + return 0.0; + else + return dec_longitude; +} + +float GPS::get_nmea_latitude() { + if (!lock) + return 0.0; + else + return nmea_latitude; +} + +float GPS::get_dec_latitude() { + dec_latitude = nmea_to_dec(nmea_latitude, ns); + if (!lock) + return 0.0; + else + return dec_latitude; +} + +float GPS::get_course_t() { + if (!lock) + return 0.0; + else + return course_t; +} + +float GPS::get_course_m() { + if (!lock) + return 0.0; + else + return course_m; +} + +float GPS::get_speed_k() { + if (!lock) + return 0.0; + else + return speed_k; +} + +float GPS::get_speed_km() { + if (!lock) + return 0.0; + else + return speed_km; +} + +float GPS::get_altitude_ft() { + if (!lock) + return 0.0; + else + return 3.280839895*msl_altitude; +} + +// NAVIGATION FUNCTIONS //////////////////////////////////////////////////////////// +float GPS::calc_course_to(float pointLat, float pontLong) { + const double d2r = PI / 180.0; + const double r2d = 180.0 / PI; + double dlat = abs(pointLat - get_dec_latitude()) * d2r; + double dlong = abs(pontLong - get_dec_longitude()) * d2r; + double y = sin(dlong) * cos(pointLat * d2r); + double x = cos(get_dec_latitude()*d2r)*sin(pointLat*d2r) - sin(get_dec_latitude()*d2r)*cos(pointLat*d2r)*cos(dlong); + return atan2(y,x)*r2d; +} + +/* +var y = Math.sin(dLon) * Math.cos(lat2); +var x = Math.cos(lat1)*Math.sin(lat2) - + Math.sin(lat1)*Math.cos(lat2)*Math.cos(dLon); +var brng = Math.atan2(y, x).toDeg(); +*/ + +/* + The Haversine formula according to Dr. Math. + http://mathforum.org/library/drmath/view/51879.html + + dlon = lon2 - lon1 + dlat = lat2 - lat1 + a = (sin(dlat/2))^2 + cos(lat1) * cos(lat2) * (sin(dlon/2))^2 + c = 2 * atan2(sqrt(a), sqrt(1-a)) + d = R * c + + Where + * dlon is the change in longitude + * dlat is the change in latitude + * c is the great circle distance in Radians. + * R is the radius of a spherical Earth. + * The locations of the two points in + spherical coordinates (longitude and + latitude) are lon1,lat1 and lon2, lat2. +*/ +double GPS::calc_dist_to_mi(float pointLat, float pontLong) { + const double d2r = PI / 180.0; + double dlat = pointLat - get_dec_latitude(); + double dlong = pontLong - get_dec_longitude(); + double a = pow(sin(dlat/2.0),2.0) + cos(get_dec_latitude()*d2r) * cos(pointLat*d2r) * pow(sin(dlong/2.0),2.0); + double c = 2.0 * asin(sqrt(abs(a))); + double d = 63.765 * c; + + return d; +} + +double GPS::calc_dist_to_ft(float pointLat, float pontLong) { + return calc_dist_to_mi(pointLat, pontLong)*5280.0; +} + +double GPS::calc_dist_to_km(float pointLat, float pontLong) { + return calc_dist_to_mi(pointLat, pontLong)*1.609344; +} + +double GPS::calc_dist_to_m(float pointLat, float pontLong) { + return calc_dist_to_mi(pointLat, pontLong)*1609.344; +} + + \ No newline at end of file