vtx: fix VTX_SETTINGS_POWER_COUNT and add dummy entries to saPowerNames
[inav.git] / src / main / telemetry / ltm.c
blob45ab37deec50f2397f68301d2dc7a8d7d9d74abf
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/>.
19 * LightTelemetry from KipK
21 * Minimal one way telemetry protocol for really low bitrates (1200/2400 bauds).
22 * Effective for ground OSD, groundstation HUD and Antenna tracker
23 * http://www.wedontneednasa.com/2014/02/lighttelemetry-v2-en-route-to-ground-osd.html
25 * This implementation is for LTM v2 > 2400 baud rates
27 * Cleanflight implementation by Jonathan Hudson
30 #include <stdbool.h>
31 #include <stdint.h>
33 #include "platform.h"
36 #if defined(USE_TELEMETRY_LTM)
38 #include "build/build_config.h"
40 #include "common/axis.h"
41 #include "common/color.h"
42 #include "common/streambuf.h"
43 #include "common/utils.h"
45 #include "drivers/serial.h"
46 #include "drivers/time.h"
48 #include "fc/config.h"
49 #include "fc/fc_core.h"
50 #include "fc/rc_controls.h"
51 #include "fc/runtime_config.h"
53 #include "flight/imu.h"
54 #include "flight/failsafe.h"
55 #include "flight/mixer.h"
56 #include "flight/pid.h"
58 #include "io/gps.h"
59 #include "io/ledstrip.h"
60 #include "io/serial.h"
62 #include "navigation/navigation.h"
64 #include "rx/rx.h"
66 #include "sensors/acceleration.h"
67 #include "sensors/barometer.h"
68 #include "sensors/battery.h"
69 #include "sensors/boardalignment.h"
70 #include "sensors/diagnostics.h"
71 #include "sensors/gyro.h"
72 #include "sensors/sensors.h"
73 #include "sensors/pitotmeter.h"
74 #include "sensors/diagnostics.h"
76 #include "telemetry/ltm.h"
77 #include "telemetry/telemetry.h"
80 #define TELEMETRY_LTM_INITIAL_PORT_MODE MODE_TX
81 #define LTM_CYCLETIME 100
82 #define LTM_SCHEDULE_SIZE (1000/LTM_CYCLETIME)
84 static serialPort_t *ltmPort;
85 static serialPortConfig_t *portConfig;
86 static bool ltmEnabled;
87 static portSharing_e ltmPortSharing;
88 static uint8_t ltmFrame[LTM_MAX_MESSAGE_SIZE];
89 static uint8_t ltm_x_counter;
91 static void ltm_initialise_packet(sbuf_t *dst)
93 dst->ptr = ltmFrame;
94 dst->end = ARRAYEND(ltmFrame);
96 sbufWriteU8(dst, '$');
97 sbufWriteU8(dst, 'T');
100 static void ltm_finalise(sbuf_t *dst)
102 uint8_t crc = 0;
103 for (const uint8_t *ptr = &ltmFrame[3]; ptr < dst->ptr; ++ptr) {
104 crc ^= *ptr;
106 sbufWriteU8(dst, crc);
107 sbufSwitchToReader(dst, ltmFrame);
108 serialWriteBuf(ltmPort, sbufPtr(dst), sbufBytesRemaining(dst));
111 #if defined(USE_GPS)
113 * GPS G-frame 5Hhz at > 2400 baud
114 * LAT LON SPD ALT SAT/FIX
116 void ltm_gframe(sbuf_t *dst)
118 uint8_t gps_fix_type = 0;
119 int32_t ltm_lat = 0, ltm_lon = 0, ltm_alt = 0, ltm_gs = 0;
121 if (sensors(SENSOR_GPS)
122 #ifdef USE_GPS_FIX_ESTIMATION
123 || STATE(GPS_ESTIMATED_FIX)
124 #endif
126 if (gpsSol.fixType == GPS_NO_FIX)
127 gps_fix_type = 1;
128 else if (gpsSol.fixType == GPS_FIX_2D)
129 gps_fix_type = 2;
130 else if (gpsSol.fixType == GPS_FIX_3D)
131 gps_fix_type = 3;
133 ltm_lat = gpsSol.llh.lat;
134 ltm_lon = gpsSol.llh.lon;
135 ltm_gs = gpsSol.groundSpeed / 100;
138 ltm_alt = getEstimatedActualPosition(Z); // cm
140 sbufWriteU8(dst, 'G');
141 sbufWriteU32(dst, ltm_lat);
142 sbufWriteU32(dst, ltm_lon);
143 sbufWriteU8(dst, (uint8_t)ltm_gs);
144 sbufWriteU32(dst, ltm_alt);
145 sbufWriteU8(dst, (gpsSol.numSat << 2) | gps_fix_type);
147 #endif
150 * Sensors S-frame 5Hhz at > 2400 baud
151 * VBAT(mv) Current(ma) RSSI AIRSPEED ARM/FS/FMOD
152 * Flight mode(0-19):
153 * 0: Manual, 1: Rate, 2: Attitude/Angle, 3: Horizon,
154 * 4: Acro, 5: Stabilized1, 6: Stabilized2, 7: Stabilized3,
155 * 8: Altitude Hold, 9: Loiter/GPS Hold, 10: Auto/Waypoints,
156 * 11: Heading Hold / headFree, 12: Circle, 13: RTH, 14: FollowMe,
157 * 15: LAND, 16:FlybyWireA, 17: FlybywireB, 18: Cruise, 19: Unknown
160 void ltm_sframe(sbuf_t *dst)
162 ltm_modes_e lt_flightmode;
164 if (FLIGHT_MODE(MANUAL_MODE))
165 lt_flightmode = LTM_MODE_MANUAL;
166 else if (FLIGHT_MODE(NAV_WP_MODE))
167 lt_flightmode = LTM_MODE_WAYPOINTS;
168 else if (FLIGHT_MODE(NAV_RTH_MODE))
169 lt_flightmode = LTM_MODE_RTH;
170 else if (FLIGHT_MODE(NAV_POSHOLD_MODE))
171 lt_flightmode = LTM_MODE_GPSHOLD;
172 else if (FLIGHT_MODE(NAV_COURSE_HOLD_MODE))
173 lt_flightmode = LTM_MODE_CRUISE;
174 else if (FLIGHT_MODE(NAV_LAUNCH_MODE))
175 lt_flightmode = LTM_MODE_LAUNCH;
176 else if (FLIGHT_MODE(AUTO_TUNE))
177 lt_flightmode = LTM_MODE_AUTOTUNE;
178 else if (FLIGHT_MODE(NAV_ALTHOLD_MODE))
179 lt_flightmode = LTM_MODE_ALTHOLD;
180 else if (FLIGHT_MODE(HEADFREE_MODE) || FLIGHT_MODE(HEADING_MODE))
181 lt_flightmode = LTM_MODE_HEADHOLD;
182 else if (FLIGHT_MODE(ANGLE_MODE))
183 lt_flightmode = LTM_MODE_ANGLE;
184 else if (FLIGHT_MODE(HORIZON_MODE))
185 lt_flightmode = LTM_MODE_HORIZON;
186 #ifdef USE_FW_AUTOLAND
187 else if (FLIGHT_MODE(NAV_FW_AUTOLAND))
188 lt_flightmode = LTM_MODE_LAND;
189 #endif
190 else
191 lt_flightmode = LTM_MODE_RATE; // Rate mode
193 uint8_t lt_statemode = (ARMING_FLAG(ARMED)) ? 1 : 0;
194 if (failsafeIsActive())
195 lt_statemode |= 2;
196 sbufWriteU8(dst, 'S');
197 sbufWriteU16(dst, getBatteryVoltage() * 10); //vbat converted to mv
198 sbufWriteU16(dst, (uint16_t)constrain(getMAhDrawn(), 0, 0xFFFF)); // current mAh (65535 mAh max)
199 sbufWriteU8(dst, (uint8_t)((getRSSI() * 254) / 1023)); // scaled RSSI (uchar)
200 #if defined(USE_PITOT)
201 sbufWriteU8(dst, (sensors(SENSOR_PITOT) && pitotIsHealthy())? getAirspeedEstimate() / 100.0f : 0); // in m/s
202 #else
203 sbufWriteU8(dst, 0);
204 #endif
205 sbufWriteU8(dst, (lt_flightmode << 2) | lt_statemode);
209 * Attitude A-frame - 10 Hz at > 2400 baud
210 * PITCH ROLL HEADING
212 void ltm_aframe(sbuf_t *dst)
214 sbufWriteU8(dst, 'A');
215 sbufWriteU16(dst, DECIDEGREES_TO_DEGREES(attitude.values.pitch));
216 sbufWriteU16(dst, DECIDEGREES_TO_DEGREES(attitude.values.roll));
217 sbufWriteU16(dst, DECIDEGREES_TO_DEGREES(attitude.values.yaw));
220 #if defined(USE_GPS)
222 * OSD additional data frame, 1 Hz rate
223 * This frame will be ignored by Ghettostation, but processed by GhettOSD if it is used as standalone onboard OSD
224 * home pos, home alt, direction to home
226 void ltm_oframe(sbuf_t *dst)
228 sbufWriteU8(dst, 'O');
229 sbufWriteU32(dst, GPS_home.lat);
230 sbufWriteU32(dst, GPS_home.lon);
231 sbufWriteU32(dst, GPS_home.alt);
232 sbufWriteU8(dst, 1); // OSD always ON
233 sbufWriteU8(dst, STATE(GPS_FIX_HOME) ? 1 : 0);
235 #endif
238 * Extended information data frame, 1 Hz rate
239 * This frame is intended to report extended GPS and NAV data, however at the moment it contains only HDOP value
241 void ltm_xframe(sbuf_t *dst)
243 uint8_t sensorStatus =
244 (isHardwareHealthy() ? 0 : 1) << 0; // bit 0 - hardware failure indication (1 - something is wrong with the hardware sensors)
246 sbufWriteU8(dst, 'X');
247 #if defined(USE_GPS)
248 sbufWriteU16(dst, gpsSol.hdop);
249 #else
250 sbufWriteU16(dst, 9999);
251 #endif
252 sbufWriteU8(dst, sensorStatus);
253 sbufWriteU8(dst, ltm_x_counter);
254 sbufWriteU8(dst, getDisarmReason());
255 sbufWriteU8(dst, 0);
256 ltm_x_counter++; // overflow is OK
259 /** OSD additional data frame, ~4 Hz rate, navigation system status
261 void ltm_nframe(sbuf_t *dst)
263 sbufWriteU8(dst, 'N');
264 sbufWriteU8(dst, NAV_Status.mode);
265 sbufWriteU8(dst, NAV_Status.state);
266 sbufWriteU8(dst, NAV_Status.activeWpAction);
267 sbufWriteU8(dst, NAV_Status.activeWpNumber);
268 sbufWriteU8(dst, NAV_Status.error);
269 sbufWriteU8(dst, NAV_Status.flags);
272 #define LTM_BIT_AFRAME (1 << 0)
273 #define LTM_BIT_GFRAME (1 << 1)
274 #define LTM_BIT_SFRAME (1 << 2)
275 #define LTM_BIT_OFRAME (1 << 3)
276 #define LTM_BIT_NFRAME (1 << 4)
277 #define LTM_BIT_XFRAME (1 << 5)
280 * This is the normal (default) scheduler, needs c. 4800 baud or faster
281 * Equates to c. 303 bytes / second
283 static uint8_t ltm_normal_schedule[LTM_SCHEDULE_SIZE] = {
284 LTM_BIT_AFRAME | LTM_BIT_GFRAME,
285 LTM_BIT_AFRAME | LTM_BIT_SFRAME | LTM_BIT_OFRAME,
286 LTM_BIT_AFRAME | LTM_BIT_GFRAME,
287 LTM_BIT_AFRAME | LTM_BIT_SFRAME | LTM_BIT_NFRAME,
288 LTM_BIT_AFRAME | LTM_BIT_GFRAME,
289 LTM_BIT_AFRAME | LTM_BIT_SFRAME | LTM_BIT_XFRAME,
290 LTM_BIT_AFRAME | LTM_BIT_GFRAME,
291 LTM_BIT_AFRAME | LTM_BIT_SFRAME | LTM_BIT_NFRAME,
292 LTM_BIT_AFRAME | LTM_BIT_GFRAME,
293 LTM_BIT_AFRAME | LTM_BIT_SFRAME | LTM_BIT_NFRAME
297 * This is the medium scheduler, needs c. 2400 baud or faster
298 * Equates to c. 164 bytes / second
300 static uint8_t ltm_medium_schedule[LTM_SCHEDULE_SIZE] = {
301 LTM_BIT_AFRAME,
302 LTM_BIT_GFRAME,
303 LTM_BIT_AFRAME | LTM_BIT_SFRAME,
304 LTM_BIT_OFRAME,
305 LTM_BIT_AFRAME | LTM_BIT_XFRAME,
306 LTM_BIT_OFRAME,
307 LTM_BIT_AFRAME | LTM_BIT_SFRAME,
308 LTM_BIT_GFRAME,
309 LTM_BIT_AFRAME,
310 LTM_BIT_NFRAME
314 * This is the slow scheduler, needs c. 1200 baud or faster
315 * Equates to c. 105 bytes / second (91 b/s if the second GFRAME is zeroed)
317 static uint8_t ltm_slow_schedule[LTM_SCHEDULE_SIZE] = {
318 LTM_BIT_GFRAME,
319 LTM_BIT_SFRAME,
320 LTM_BIT_AFRAME,
322 LTM_BIT_OFRAME,
323 LTM_BIT_XFRAME,
324 LTM_BIT_GFRAME, // consider zeroing this for even lower bytes/sec
326 LTM_BIT_AFRAME,
327 LTM_BIT_NFRAME,
330 /* Set by initialisation */
331 static uint8_t *ltm_schedule;
333 static void process_ltm(void)
335 static uint8_t ltm_scheduler = 0;
336 uint8_t current_schedule = ltm_schedule[ltm_scheduler];
338 sbuf_t ltmFrameBuf;
339 sbuf_t *dst = &ltmFrameBuf;
341 if (current_schedule & LTM_BIT_AFRAME) {
342 ltm_initialise_packet(dst);
343 ltm_aframe(dst);
344 ltm_finalise(dst);
347 #if defined(USE_GPS)
348 if (current_schedule & LTM_BIT_GFRAME) {
349 ltm_initialise_packet(dst);
350 ltm_gframe(dst);
351 ltm_finalise(dst);
354 if (current_schedule & LTM_BIT_OFRAME) {
355 ltm_initialise_packet(dst);
356 ltm_oframe(dst);
357 ltm_finalise(dst);
360 if (current_schedule & LTM_BIT_XFRAME) {
361 ltm_initialise_packet(dst);
362 ltm_xframe(dst);
363 ltm_finalise(dst);
365 #endif
367 if (current_schedule & LTM_BIT_SFRAME) {
368 ltm_initialise_packet(dst);
369 ltm_sframe(dst);
370 ltm_finalise(dst);
373 if (current_schedule & LTM_BIT_NFRAME) {
374 ltm_initialise_packet(dst);
375 ltm_nframe(dst);
376 ltm_finalise(dst);
379 ltm_scheduler = (ltm_scheduler + 1) % 10;
382 void handleLtmTelemetry(void)
384 static uint32_t ltm_lastCycleTime;
385 if (!ltmEnabled)
386 return;
387 if (!ltmPort)
388 return;
389 const uint32_t now = millis();
390 if ((now - ltm_lastCycleTime) >= LTM_CYCLETIME) {
391 process_ltm();
392 ltm_lastCycleTime = now;
396 void freeLtmTelemetryPort(void)
398 closeSerialPort(ltmPort);
399 ltmPort = NULL;
400 ltmEnabled = false;
403 void initLtmTelemetry(void)
405 portConfig = findSerialPortConfig(FUNCTION_TELEMETRY_LTM);
406 ltmPortSharing = determinePortSharing(portConfig, FUNCTION_TELEMETRY_LTM);
411 static void configureLtmScheduler(void)
414 /* setup scheduler, default to 'normal' */
415 if (telemetryConfig()->ltmUpdateRate == LTM_RATE_MEDIUM)
416 ltm_schedule = ltm_medium_schedule;
417 else if (telemetryConfig()->ltmUpdateRate == LTM_RATE_SLOW)
418 ltm_schedule = ltm_slow_schedule;
419 else
420 ltm_schedule = ltm_normal_schedule;
424 void configureLtmTelemetryPort(void)
426 if (!portConfig) {
427 return;
429 baudRate_e baudRateIndex = portConfig->telemetry_baudrateIndex;
430 if (baudRateIndex == BAUD_AUTO) {
431 baudRateIndex = BAUD_19200;
434 /* Sanity check that we can support the scheduler */
435 if (baudRateIndex == BAUD_2400 && telemetryConfig()->ltmUpdateRate == LTM_RATE_NORMAL)
436 ltm_schedule = ltm_medium_schedule;
437 if (baudRateIndex == BAUD_1200)
438 ltm_schedule = ltm_slow_schedule;
440 ltmPort = openSerialPort(portConfig->identifier, FUNCTION_TELEMETRY_LTM, NULL, NULL, baudRates[baudRateIndex], TELEMETRY_LTM_INITIAL_PORT_MODE, SERIAL_NOT_INVERTED);
441 if (!ltmPort)
442 return;
443 ltm_x_counter = 0;
444 ltmEnabled = true;
447 void checkLtmTelemetryState(void)
449 if (portConfig && telemetryCheckRxPortShared(portConfig)) {
450 if (!ltmEnabled && telemetrySharedPort != NULL) {
451 ltmPort = telemetrySharedPort;
452 configureLtmScheduler();
453 ltmEnabled = true;
455 } else {
456 bool newTelemetryEnabledValue = telemetryDetermineEnabledState(ltmPortSharing);
457 if (newTelemetryEnabledValue == ltmEnabled)
458 return;
459 if (newTelemetryEnabledValue){
460 configureLtmScheduler();
461 configureLtmTelemetryPort();
464 else
465 freeLtmTelemetryPort();
469 int getLtmFrame(uint8_t *frame, ltm_frame_e ltmFrameType)
471 static uint8_t ltmFrame[LTM_MAX_MESSAGE_SIZE];
473 sbuf_t ltmFrameBuf = { .ptr = ltmFrame, .end =ARRAYEND(ltmFrame) };
474 sbuf_t * const sbuf = &ltmFrameBuf;
476 switch (ltmFrameType) {
477 default:
478 case LTM_AFRAME:
479 ltm_aframe(sbuf);
480 break;
481 case LTM_SFRAME:
482 ltm_sframe(sbuf);
483 break;
484 #if defined(USE_GPS)
485 case LTM_GFRAME:
486 ltm_gframe(sbuf);
487 break;
488 case LTM_OFRAME:
489 ltm_oframe(sbuf);
490 break;
491 #endif
492 case LTM_XFRAME:
493 ltm_xframe(sbuf);
494 break;
495 case LTM_NFRAME:
496 ltm_nframe(sbuf);
497 break;
499 sbufSwitchToReader(sbuf, ltmFrame);
500 const int frameSize = sbufBytesRemaining(sbuf);
501 for (int ii = 0; sbufBytesRemaining(sbuf); ++ii) {
502 frame[ii] = sbufReadU8(sbuf);
504 return frameSize;
506 #endif