vtx: fix VTX_SETTINGS_POWER_COUNT and add dummy entries to saPowerNames
[inav.git] / src / main / navigation / navigation_geo.c
blobe823ca637e5e17208e2812526b8d6d98e7dfa2ba
1 /*
2 * This file is part of Cleanflight.
4 * Cleanflight is free software: you can redistribute it and/or modify
5 * it under the terms of the GNU General Public License as published by
6 * the Free Software Foundation, either version 3 of the License, or
7 * (at your option) any later version.
9 * Cleanflight is distributed in the hope that it will be useful,
10 * but WITHOUT ANY WARRANTY; without even the implied warranty of
11 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
12 * GNU General Public License for more details.
14 * You should have received a copy of the GNU General Public License
15 * along with Cleanflight. If not, see <http://www.gnu.org/licenses/>.
18 #include <stdbool.h>
19 #include <stdint.h>
20 #include <math.h>
22 #include "platform.h"
24 #include "build/build_config.h"
25 #include "build/debug.h"
27 #include "common/axis.h"
28 #include "common/filter.h"
29 #include "common/maths.h"
31 #include "sensors/sensors.h"
32 #include "sensors/acceleration.h"
33 #include "sensors/boardalignment.h"
35 #include "flight/pid.h"
36 #include "flight/imu.h"
38 #include "fc/config.h"
39 #include "fc/runtime_config.h"
41 #include "navigation/navigation.h"
42 #include "navigation/navigation_private.h"
44 #include "navigation/navigation_declination_gen.c"
46 static float get_lookup_table_val(unsigned lat_index, unsigned lon_index)
48 return declination_table[lat_index][lon_index];
51 float geoCalculateMagDeclination(const gpsLocation_t * llh) // degrees units
54 * If the values exceed valid ranges, return zero as default
55 * as we have no way of knowing what the closest real value
56 * would be.
58 const float lat = llh->lat / 10000000.0f;
59 const float lon = llh->lon / 10000000.0f;
61 if (lat < -90.0f || lat > 90.0f ||
62 lon < -180.0f || lon > 180.0f) {
63 return 0.0f;
66 /* round down to nearest sampling resolution */
67 int min_lat = (int)(lat / SAMPLING_RES) * SAMPLING_RES;
68 int min_lon = (int)(lon / SAMPLING_RES) * SAMPLING_RES;
70 /* for the rare case of hitting the bounds exactly
71 * the rounding logic wouldn't fit, so enforce it.
74 /* limit to table bounds - required for maxima even when table spans full globe range */
75 if (lat <= SAMPLING_MIN_LAT) {
76 min_lat = SAMPLING_MIN_LAT;
79 if (lat >= SAMPLING_MAX_LAT) {
80 min_lat = (int)(lat / SAMPLING_RES) * SAMPLING_RES - SAMPLING_RES;
83 if (lon <= SAMPLING_MIN_LON) {
84 min_lon = SAMPLING_MIN_LON;
87 if (lon >= SAMPLING_MAX_LON) {
88 min_lon = (int)(lon / SAMPLING_RES) * SAMPLING_RES - SAMPLING_RES;
91 /* find index of nearest low sampling point */
92 const unsigned min_lat_index = (-(SAMPLING_MIN_LAT) + min_lat) / SAMPLING_RES;
93 const unsigned min_lon_index = (-(SAMPLING_MIN_LON) + min_lon) / SAMPLING_RES;
95 const float declination_sw = get_lookup_table_val(min_lat_index, min_lon_index);
96 const float declination_se = get_lookup_table_val(min_lat_index, min_lon_index + 1);
97 const float declination_ne = get_lookup_table_val(min_lat_index + 1, min_lon_index + 1);
98 const float declination_nw = get_lookup_table_val(min_lat_index + 1, min_lon_index);
100 /* perform bilinear interpolation on the four grid corners */
102 const float declination_min = ((lon - min_lon) / SAMPLING_RES) * (declination_se - declination_sw) + declination_sw;
103 const float declination_max = ((lon - min_lon) / SAMPLING_RES) * (declination_ne - declination_nw) + declination_nw;
105 return ((lat - min_lat) / SAMPLING_RES) * (declination_max - declination_min) + declination_min;
108 void geoSetOrigin(gpsOrigin_t *origin, const gpsLocation_t *llh, geoOriginResetMode_e resetMode)
110 if (resetMode == GEO_ORIGIN_SET) {
111 origin->valid = true;
112 origin->lat = llh->lat;
113 origin->lon = llh->lon;
114 origin->alt = llh->alt;
115 origin->scale = constrainf(cos_approx((ABS(origin->lat) / 10000000.0f) * 0.0174532925f), 0.01f, 1.0f);
117 else if (origin->valid && (resetMode == GEO_ORIGIN_RESET_ALTITUDE)) {
118 origin->alt = llh->alt;
122 bool geoConvertGeodeticToLocal(fpVector3_t *pos, const gpsOrigin_t *origin, const gpsLocation_t *llh, geoAltitudeConversionMode_e altConv)
124 if (origin->valid) {
125 pos->x = (llh->lat - origin->lat) * DISTANCE_BETWEEN_TWO_LONGITUDE_POINTS_AT_EQUATOR;
126 pos->y = (llh->lon - origin->lon) * (DISTANCE_BETWEEN_TWO_LONGITUDE_POINTS_AT_EQUATOR * origin->scale);
128 // If flag GEO_ALT_RELATIVE, than llh altitude is already relative to origin
129 if (altConv == GEO_ALT_RELATIVE) {
130 pos->z = llh->alt;
131 } else {
132 pos->z = llh->alt - origin->alt;
134 return true;
137 pos->x = 0.0f;
138 pos->y = 0.0f;
139 pos->z = 0.0f;
140 return false;
143 bool geoConvertGeodeticToLocalOrigin(fpVector3_t * pos, const gpsLocation_t *llh, geoAltitudeConversionMode_e altConv)
145 return geoConvertGeodeticToLocal(pos, &posControl.gpsOrigin, llh, altConv);
148 bool geoConvertLocalToGeodetic(gpsLocation_t *llh, const gpsOrigin_t * origin, const fpVector3_t *pos)
150 float scaleLonDown;
152 if (origin->valid) {
153 llh->lat = origin->lat;
154 llh->lon = origin->lon;
155 llh->alt = origin->alt;
156 scaleLonDown = origin->scale;
158 else {
159 llh->lat = 0;
160 llh->lon = 0;
161 llh->alt = 0;
162 scaleLonDown = 1.0f;
165 llh->lat += lrintf(pos->x / DISTANCE_BETWEEN_TWO_LONGITUDE_POINTS_AT_EQUATOR);
166 llh->lon += lrintf(pos->y / (DISTANCE_BETWEEN_TWO_LONGITUDE_POINTS_AT_EQUATOR * scaleLonDown));
167 llh->alt += lrintf(pos->z);
168 return origin->valid;