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2136 | - | 1 | //++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ |
2 | //++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ |
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3 | |||
4 | //############################################################################ |
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5 | //# HISTORY gps.c |
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6 | //# |
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2200 | - | 7 | //# 20.09.2015 Startet |
8 | //# - add Routine um einen Offset in Meter zu den aktuellen Koordinaten dazurechnen |
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9 | //# followme_calculate_offset(...) |
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10 | //# |
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2136 | - | 11 | //# 03.08.2015 cebra |
12 | //# - add: Routine um aus gegebenen Koordinaten mit Abstand und Winkel eine ZielKoordinate zu berechnen |
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13 | //# int nmea_move_horz( |
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14 | //# const nmeaPOS *start_pos, /**< Start position in radians */ |
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15 | //# nmeaPOS *end_pos, /**< Result position in radians */ |
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16 | //# double azimuth, /**< Azimuth (degree) [0, 359] */ |
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17 | //# double distance) /**< Distance (km) */ |
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18 | //# |
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19 | //# 27.06.2014 OG - NEU |
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20 | //# - chg: auf #include "../gps/mymath.h" angepasst |
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21 | //# |
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22 | //# 20.06.2014 OG - NEU |
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23 | //############################################################################ |
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24 | |||
25 | |||
26 | #include "../cpu.h" |
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27 | #include <string.h> |
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28 | #include <util/delay.h> |
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29 | #include <avr/interrupt.h> |
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30 | #include <stdlib.h> |
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31 | #include <math.h> |
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32 | #include "../main.h" |
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33 | |||
34 | #include "../mk-data-structs.h" |
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35 | #include "../gps/mymath.h" |
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36 | #include "gps.h" |
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37 | |||
38 | |||
39 | /* |
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40 | // definiert in: mk_data-stucts.h |
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41 | typedef struct |
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42 | { |
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43 | u16 Distance; // distance to target in cm |
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44 | s16 Bearing; // course to target in deg |
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45 | } __attribute__((packed)) GPS_PosDev_t; |
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46 | */ |
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47 | |||
48 | /* |
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49 | // definiert in: mk_data-stucts.h |
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50 | typedef struct |
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51 | { |
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52 | s32 Longitude; // in 1E-7 deg |
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53 | s32 Latitude; // in 1E-7 deg |
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54 | s32 Altitude; // in mm |
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55 | u8 Status; // validity of data |
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56 | } __attribute__((packed)) GPS_Pos_t; |
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57 | */ |
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58 | |||
59 | |||
60 | //-------------------------------------------------------------- |
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61 | |||
62 | #define NMEA_PI (3.141592653589793) /**< PI value */ |
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63 | #define NMEA_PI180 (NMEA_PI / 180) /**< PI division by 180 */ |
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64 | #define NMEA_EARTHRADIUS_KM (6378) /**< Earth's mean radius in km */ |
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65 | #define R (6371) |
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66 | #define NMEA_EARTHRADIUS_M (NMEA_EARTHRADIUS_KM * 1000) /**< Earth's mean radius in m */ |
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67 | #define NMEA_EARTH_SEMIMAJORAXIS_M (6378137.0) /**< Earth's semi-major axis in m according WGS84 */ |
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68 | #define NMEA_EARTH_SEMIMAJORAXIS_KM (NMEA_EARTHMAJORAXIS_KM / 1000) /**< Earth's semi-major axis in km according WGS 84 */ |
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69 | #define NMEA_EARTH_FLATTENING (1 / 298.257223563) /**< Earth's flattening according WGS 84 */ |
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70 | #define NMEA_DOP_FACTOR (5) /**< Factor for translating DOP to meters */ |
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71 | |||
2196 | - | 72 | |
73 | // Definitonen für FollowMeStep2 |
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74 | #define LONG_DIV 10000000 |
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75 | #define LAT_DIV LONG_DIV |
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2199 | - | 76 | #define FOLLOWME_M2DEG 111111 |
77 | #define FOLLOWME_ROUND_100 100 |
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2196 | - | 78 | |
79 | |||
2136 | - | 80 | # define NMEA_POSIX(x) x |
81 | |||
82 | |||
83 | |||
84 | /** |
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85 | * \fn nmea_degree2radian |
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86 | * \brief Convert degree to radian |
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87 | */ |
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88 | double nmea_degree2radian(double val) |
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89 | { return (val * NMEA_PI180); } |
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90 | |||
91 | |||
92 | //------------------------------------------------------------------------------------------ |
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93 | nmeaPOS NMEApos; |
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94 | nmeaPOS NMEATarget; |
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95 | |||
96 | /** |
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97 | * \brief Horizontal move of point position |
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98 | */ |
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99 | int nmea_move_horz( |
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100 | const nmeaPOS *start_pos, /**< Start position in radians */ |
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101 | nmeaPOS *end_pos, /**< Result position in radians */ |
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102 | double azimuth, /**< Azimuth (degree) [0, 359] */ |
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103 | double distance /**< Distance (km) */ |
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104 | ) |
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105 | { |
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106 | nmeaPOS p1 = *start_pos; |
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107 | int RetVal = 1; |
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108 | |||
109 | distance /= NMEA_EARTHRADIUS_KM; /* Angular distance covered on earth's surface */ |
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110 | azimuth = nmea_degree2radian(azimuth); |
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111 | |||
112 | end_pos->lat = asin( sin(p1.lat) * cos(distance) + cos(p1.lat) * sin(distance) * cos(azimuth)); |
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113 | |||
114 | end_pos->lon = p1.lon + atan2( sin(azimuth) * sin(distance) * cos(p1.lat), cos(distance) - sin(p1.lat) * sin(end_pos->lat)); |
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115 | |||
116 | if(NMEA_POSIX(isnan)(end_pos->lat) || NMEA_POSIX(isnan)(end_pos->lon)) |
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117 | { |
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118 | end_pos->lat = 0; end_pos->lon = 0; |
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119 | RetVal = 0; |
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120 | } |
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121 | |||
122 | return RetVal; |
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123 | } |
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124 | |||
125 | |||
2196 | - | 126 | // Berechnet die Position der Kopters für FollowMeStep2 |
127 | // Momentan wird die gleich Position ausgegeben |
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2200 | - | 128 | // Benutzt die c_cos_8192 der FC |
129 | // TODO: move to followme.c |
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2136 | - | 130 | |
2200 | - | 131 | uint8_t followme_calculate_offset( |
132 | const nmeaPOS *pPktPos, /**< Start position in radians */ |
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2196 | - | 133 | nmeaPOS *target_pos, /**< Result position in radians */ |
134 | int d_lat, /**< Distance lat(m) */ |
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2200 | - | 135 | int d_long /**< Distance long(m) */ |
2196 | - | 136 | ) |
137 | { |
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2200 | - | 138 | nmeaPOS pktPos = *pPktPos; |
139 | |||
140 | target_pos->lat = pktPos.lat + ( d_lat * ( LAT_DIV / FOLLOWME_M2DEG ) ); |
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141 | target_pos->lon = pktPos.lon + ( d_long * ( LONG_DIV / FOLLOWME_M2DEG ) * 8192 ) / abs ( c_cos_8192( (int16_t)(pktPos.lat / LONG_DIV ) ) ); |
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2196 | - | 142 | |
143 | return 1; |
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144 | } |
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145 | |||
146 | |||
2136 | - | 147 | //############################################################################################### |
148 | |||
149 | |||
150 | |||
151 | //-------------------------------------------------------------- |
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152 | GPS_PosDev_t gps_Deviation( GPS_Pos_t pos1, GPS_Pos_t pos2 ) |
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153 | { |
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154 | int32_t lat1, lon1, lat2, lon2; |
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155 | int32_t d1, dlat; |
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156 | GPS_PosDev_t PosDev; |
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157 | |||
158 | lon1 = pos1.Longitude; |
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159 | lat1 = pos1.Latitude; |
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160 | |||
161 | lon2 = pos2.Longitude; |
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162 | lat2 = pos2.Latitude; |
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163 | |||
164 | d1 = (1359 * (int32_t)(c_cos_8192((lat1 + lat2) / 20000000)) * ((lon1 - lon2)/10))/ 10000000; |
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165 | dlat = (1113 * (lat1 - lat2) / 10000); |
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166 | |||
167 | PosDev.Bearing = (my_atan2(d1, dlat) + 540) % 360; // 360 +180 besserer Vergleich mit MkCockpit |
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168 | PosDev.Distance = sqrt32( d1 * d1 + dlat * dlat ); // |
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169 | //PosDev.Distance = sqrt32( d1 * d1 + dlat * dlat ) * 10; // *10 um von dm auf cm zu kommen |
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170 | |||
171 | return PosDev; |
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172 | } |
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173 | |||
174 | |||
175 | ///** |
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176 | // * \brief Calculate distance between two points |
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177 | // * \return Distance in meters |
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178 | // */ |
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179 | //int32_t nmea_distance( |
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180 | // const nmeaPOS *from_pos, /**< From position in radians */ |
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181 | // const nmeaPOS *to_pos /**< To position in radians */ |
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182 | // ) |
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183 | //{ |
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184 | // int32_t dist = ((int32_t)NMEA_EARTHRADIUS_M) * acos( |
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185 | // sin(to_pos->lat) * sin(from_pos->lat) + |
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186 | // cos(to_pos->lat) * cos(from_pos->lat) * cos(to_pos->lon - from_pos->lon) |
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187 | // ); |
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188 | // return dist; |
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189 | //} |
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190 | |||
191 | |||
192 | |||
193 | //// Berechnung von Distanz und Winkel aus GPS-Daten home(MK eingeschaltet) |
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194 | //// zur aktuellen Position(nach Motorstart) |
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195 | //geo_t calc_geo(HomePos_t *home, GPS_Pos_t *pos) |
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196 | //{ double lat1, lon1, lat2, lon2, d1, dlat; |
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197 | // geo_t geo; |
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198 | // |
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199 | // lon1 = MK_pos.Home_Lon; |
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200 | // lat1 = MK_pos.Home_Lat; |
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201 | // lon2 = (double)pos->Longitude / 10000000.0; |
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202 | // lat2 = (double)pos->Latitude / 10000000.0; |
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203 | // |
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204 | // // Formel verwendet von http://www.kompf.de/gps/distcalc.html |
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205 | // // 111.3 km = Abstand zweier Breitenkreise und/oder zweier Längenkreise am Äquator |
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206 | // // es wird jedoch in Meter weiter gerechnet |
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207 | // d1 = 111300 * (double)cos((double)(lat1 + lat2) / 2 * DEG_TO_RAD) * (lon1 - lon2); |
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208 | // dlat = 111300 * (double)(lat1 - lat2); |
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209 | // // returns a value in metres http://www.kompf.de/gps/distcalc.html |
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210 | // geo.bearing = fmod((RAD_TO_DEG * (double)atan2(d1, dlat)) + 180, 360); // +180 besserer Vergleich mit MkCockpit |
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211 | // if (geo.bearing > 360) geo.bearing -= 360; // bekam schon Werte über 400 |
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212 | // geo.distance = sqrt(d1 * d1 + dlat * dlat); |
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213 | // return(geo); |
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214 | //} |
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215 | |||
216 | // Berechnung von Distanz und Winkel aus GPS-Daten home(MK eingeschaltet) |
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217 | // zur aktuellen Position(nach Motorstart) |
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218 | //-------------------------------------------------------------- |
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219 | //-------------------------------------------------------------- |
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220 | |||
221 | /* |
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222 | geo_t calc_geo( HomePos_t *home, GPS_Pos_t *pos ) |
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223 | { |
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224 | int32_t lat1, lon1, lat2, lon2; |
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225 | int32_t d1, dlat; |
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226 | geo_t geo; |
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227 | |||
228 | lon1 = home->Home_Lon; |
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229 | lat1 = home->Home_Lat; |
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230 | lon2 = pos->Longitude; |
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231 | lat2 = pos->Latitude; |
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232 | |||
233 | if( !CheckGPS ) |
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234 | { |
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235 | writex_gpspos( 0, 3, home->Home_Lat , MNORMAL, 0,0); // Anzeige: Breitengrad (Latitude) |
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236 | writex_gpspos( 11, 3, home->Home_Lon , MNORMAL, 0,0); // Anzeige: Laengengrad (Longitude) |
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237 | writex_gpspos( 0, 4, pos->Latitude , MNORMAL, 0,0); // Anzeige: Breitengrad (Latitude) |
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238 | writex_gpspos( 11, 4, pos->Longitude , MNORMAL, 0,0); // Anzeige: Laengengrad (Longitude) |
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239 | |||
240 | //lcd_puts_at (0, 3, my_itoa(home->Home_Lat, 10, 7, 7), 0); // 30.05.2014 OG: my_itoa() gibt es nicht mehr |
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241 | //lcd_puts_at (11, 3, my_itoa(home->Home_Lon, 10, 7, 7), 0); // 30.05.2014 OG: my_itoa() gibt es nicht mehr |
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242 | //lcd_puts_at (0, 4, my_itoa(pos->Latitude, 10, 7, 7), 0); // 30.05.2014 OG: my_itoa() gibt es nicht mehr |
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243 | //lcd_puts_at (11, 4, my_itoa(pos->Longitude, 10, 7, 7), 0); // 30.05.2014 OG: my_itoa() gibt es nicht mehr |
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244 | } |
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245 | |||
246 | // Formel verwendet von http://www.kompf.de/gps/distcalc.html |
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247 | // 111.3 km = Abstand zweier Breitenkreise und/oder zweier Langenkreise am Äquator |
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248 | // es wird jedoch in dm Meter weiter gerechnet |
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249 | // (tlon1 - tlon2)/10) sonst uint32_t-Ãœberlauf bei cos(0) gleich 1 |
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250 | d1 = (1359 * (int32_t)(c_cos_8192((lat1 + lat2) / 20000000)) * ((lon1 - lon2)/10))/ 10000000; |
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251 | dlat = 1113 * (lat1 - lat2) / 10000; |
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252 | geo.bearing = (my_atan2(d1, dlat) + 540) % 360; // 360 +180 besserer Vergleich mit MkCockpit |
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253 | geo.distance = sqrt32(d1 * d1 + dlat * dlat); |
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254 | if( !CheckGPS ) |
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255 | { |
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256 | lcd_printp_at (0, 5, PSTR("Bear:"), 0); |
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257 | |||
258 | lcdx_printf_at_P( 5, 5, MNORMAL, 0,0, PSTR("%3d"), geo.bearing ); |
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259 | //lcd_puts_at (5, 5, my_itoa((uint32_t)geo.bearing, 3, 0, 0), 0); // 30.05.2014 OG: my_itoa() gibt es nicht mehr |
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260 | |||
261 | lcd_printp_at (8, 5, PSTR("\x1e"), 0); |
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262 | lcd_printp_at (9, 5, PSTR("Dist:"), 0); |
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263 | |||
264 | lcdx_printf_at_P( 15, 5, MNORMAL, 0,0, PSTR("%3d"), geo.distance ); |
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265 | //lcd_puts_at (15, 5, my_itoa((uint32_t)geo.distance, 3, 1, 1), 0); // 30.05.2014 OG: my_itoa() gibt es nicht mehr |
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266 | |||
267 | lcd_printp_at (20, 5, PSTR("m"), 0); |
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268 | } |
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269 | |||
270 | |||
271 | return(geo); |
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272 | } |
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273 | */ |
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274 |