Merge pull request #11500 from klutvott123/crsf-baud-negotiation-improvements-2
[betaflight.git] / src / main / sensors / acceleration_init.c
blob2687a78d86c3b9cfe9ca4b7d69491eb35d7ab778
1 /*
2 * This file is part of Cleanflight and Betaflight.
4 * Cleanflight and Betaflight are free software. You can redistribute
5 * this software and/or modify this software under the terms of the
6 * GNU General Public License as published by the Free Software
7 * Foundation, either version 3 of the License, or (at your option)
8 * any later version.
10 * Cleanflight and Betaflight are distributed in the hope that they
11 * will be useful, but WITHOUT ANY WARRANTY; without even the implied
12 * warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
13 * See the GNU General Public License for more details.
15 * You should have received a copy of the GNU General Public License
16 * along with this software.
18 * If not, see <http://www.gnu.org/licenses/>.
21 #include <stdbool.h>
22 #include <stdint.h>
23 #include <string.h>
24 #include <math.h>
26 #include "platform.h"
28 #ifdef USE_ACC
30 #include "build/debug.h"
32 #include "common/axis.h"
33 #include "common/filter.h"
34 #include "common/utils.h"
36 #include "config/config_reset.h"
37 #include "config/feature.h"
39 #include "drivers/accgyro/accgyro.h"
40 #include "drivers/accgyro/accgyro_fake.h"
41 #include "drivers/accgyro/accgyro_mpu.h"
42 #include "drivers/accgyro/accgyro_mpu3050.h"
43 #include "drivers/accgyro/accgyro_mpu6050.h"
44 #include "drivers/accgyro/accgyro_mpu6500.h"
45 #include "drivers/accgyro/accgyro_spi_bmi160.h"
46 #include "drivers/accgyro/accgyro_spi_bmi270.h"
47 #include "drivers/accgyro/accgyro_spi_icm20649.h"
48 #include "drivers/accgyro/accgyro_spi_icm20689.h"
49 #include "drivers/accgyro/accgyro_spi_icm426xx.h"
50 #include "drivers/accgyro/accgyro_spi_lsm6dso.h"
51 #include "drivers/accgyro/accgyro_spi_mpu6000.h"
52 #include "drivers/accgyro/accgyro_spi_mpu6500.h"
53 #include "drivers/accgyro/accgyro_spi_mpu9250.h"
55 #ifdef USE_ACC_ADXL345
56 #include "drivers/accgyro_legacy/accgyro_adxl345.h"
57 #endif
59 #ifdef USE_ACC_BMA280
60 #include "drivers/accgyro_legacy/accgyro_bma280.h"
61 #endif
63 #ifdef USE_ACC_LSM303DLHC
64 #include "drivers/accgyro_legacy/accgyro_lsm303dlhc.h"
65 #endif
67 #ifdef USE_ACC_MMA8452
68 #include "drivers/accgyro_legacy/accgyro_mma845x.h"
69 #endif
71 #include "drivers/bus_spi.h"
73 #include "config/config.h"
74 #include "fc/runtime_config.h"
76 #include "io/beeper.h"
78 #include "pg/gyrodev.h"
79 #include "pg/pg.h"
80 #include "pg/pg_ids.h"
82 #include "sensors/boardalignment.h"
83 #include "sensors/gyro.h"
84 #include "sensors/gyro_init.h"
85 #include "sensors/sensors.h"
87 #include "acceleration_init.h"
89 #define CALIBRATING_ACC_CYCLES 400
91 FAST_DATA_ZERO_INIT accelerationRuntime_t accelerationRuntime;
93 void resetRollAndPitchTrims(rollAndPitchTrims_t *rollAndPitchTrims)
95 RESET_CONFIG_2(rollAndPitchTrims_t, rollAndPitchTrims,
96 .values.roll = 0,
97 .values.pitch = 0,
101 static void setConfigCalibrationCompleted(void)
103 accelerometerConfigMutable()->accZero.values.calibrationCompleted = 1;
106 bool accHasBeenCalibrated(void)
108 return accelerometerConfig()->accZero.values.calibrationCompleted;
111 void accResetRollAndPitchTrims(void)
113 resetRollAndPitchTrims(&accelerometerConfigMutable()->accelerometerTrims);
116 static void resetFlightDynamicsTrims(flightDynamicsTrims_t *accZero)
118 accZero->values.roll = 0;
119 accZero->values.pitch = 0;
120 accZero->values.yaw = 0;
121 accZero->values.calibrationCompleted = 0;
124 void pgResetFn_accelerometerConfig(accelerometerConfig_t *instance)
126 RESET_CONFIG_2(accelerometerConfig_t, instance,
127 .acc_lpf_hz = 10,
128 .acc_hardware = ACC_DEFAULT,
129 .acc_high_fsr = false,
131 resetRollAndPitchTrims(&instance->accelerometerTrims);
132 resetFlightDynamicsTrims(&instance->accZero);
135 PG_REGISTER_WITH_RESET_FN(accelerometerConfig_t, accelerometerConfig, PG_ACCELEROMETER_CONFIG, 2);
137 extern uint16_t InflightcalibratingA;
138 extern bool AccInflightCalibrationMeasurementDone;
139 extern bool AccInflightCalibrationSavetoEEProm;
140 extern bool AccInflightCalibrationActive;
143 bool accDetect(accDev_t *dev, accelerationSensor_e accHardwareToUse)
145 accelerationSensor_e accHardware = ACC_NONE;
147 #ifdef USE_ACC_ADXL345
148 drv_adxl345_config_t acc_params;
149 #endif
151 retry:
153 switch (accHardwareToUse) {
154 case ACC_DEFAULT:
155 FALLTHROUGH;
157 #ifdef USE_ACC_ADXL345
158 case ACC_ADXL345: // ADXL345
159 acc_params.useFifo = false;
160 acc_params.dataRate = 800; // unused currently
161 if (adxl345Detect(&acc_params, dev)) {
162 accHardware = ACC_ADXL345;
163 break;
165 FALLTHROUGH;
166 #endif
168 #ifdef USE_ACC_LSM303DLHC
169 case ACC_LSM303DLHC:
170 if (lsm303dlhcAccDetect(dev)) {
171 accHardware = ACC_LSM303DLHC;
172 break;
174 FALLTHROUGH;
175 #endif
177 #ifdef USE_ACC_MPU6050
178 case ACC_MPU6050: // MPU6050
179 if (mpu6050AccDetect(dev)) {
180 accHardware = ACC_MPU6050;
181 break;
183 FALLTHROUGH;
184 #endif
186 #ifdef USE_ACC_MMA8452
187 case ACC_MMA8452: // MMA8452
188 if (mma8452Detect(dev)) {
189 accHardware = ACC_MMA8452;
190 break;
192 FALLTHROUGH;
193 #endif
195 #ifdef USE_ACC_BMA280
196 case ACC_BMA280: // BMA280
197 if (bma280Detect(dev)) {
198 accHardware = ACC_BMA280;
199 break;
201 FALLTHROUGH;
202 #endif
204 #ifdef USE_ACC_SPI_MPU6000
205 case ACC_MPU6000:
206 if (mpu6000SpiAccDetect(dev)) {
207 accHardware = ACC_MPU6000;
208 break;
210 FALLTHROUGH;
211 #endif
213 #ifdef USE_ACC_SPI_MPU9250
214 case ACC_MPU9250:
215 if (mpu9250SpiAccDetect(dev)) {
216 accHardware = ACC_MPU9250;
217 break;
219 FALLTHROUGH;
220 #endif
222 case ACC_MPU6500:
223 case ACC_ICM20601:
224 case ACC_ICM20602:
225 case ACC_ICM20608G:
226 #if defined(USE_ACC_MPU6500) || defined(USE_ACC_SPI_MPU6500)
227 #ifdef USE_ACC_SPI_MPU6500
228 if (mpu6500AccDetect(dev) || mpu6500SpiAccDetect(dev)) {
229 #else
230 if (mpu6500AccDetect(dev)) {
231 #endif
232 switch (dev->mpuDetectionResult.sensor) {
233 case MPU_9250_SPI:
234 accHardware = ACC_MPU9250;
235 break;
236 case ICM_20601_SPI:
237 accHardware = ACC_ICM20601;
238 break;
239 case ICM_20602_SPI:
240 accHardware = ACC_ICM20602;
241 break;
242 case ICM_20608_SPI:
243 accHardware = ACC_ICM20608G;
244 break;
245 default:
246 accHardware = ACC_MPU6500;
248 break;
250 #endif
251 FALLTHROUGH;
253 #ifdef USE_ACC_SPI_ICM20649
254 case ACC_ICM20649:
255 if (icm20649SpiAccDetect(dev)) {
256 accHardware = ACC_ICM20649;
257 break;
259 FALLTHROUGH;
260 #endif
262 #ifdef USE_ACC_SPI_ICM20689
263 case ACC_ICM20689:
264 if (icm20689SpiAccDetect(dev)) {
265 accHardware = ACC_ICM20689;
266 break;
268 FALLTHROUGH;
269 #endif
271 #if defined(USE_ACC_SPI_ICM42605) || defined(USE_ACC_SPI_ICM42688P)
272 case ACC_ICM42605:
273 case ACC_ICM42688P:
274 if (icm426xxSpiAccDetect(dev)) {
275 switch (dev->mpuDetectionResult.sensor) {
276 case ICM_42605_SPI:
277 accHardware = ACC_ICM42605;
278 break;
279 case ICM_42688P_SPI:
280 accHardware = ACC_ICM42688P;
281 break;
282 default:
283 accHardware = ACC_NONE;
284 break;
286 break;
288 FALLTHROUGH;
289 #endif
291 #ifdef USE_ACCGYRO_BMI160
292 case ACC_BMI160:
293 if (bmi160SpiAccDetect(dev)) {
294 accHardware = ACC_BMI160;
295 break;
297 FALLTHROUGH;
298 #endif
300 #ifdef USE_ACCGYRO_BMI270
301 case ACC_BMI270:
302 if (bmi270SpiAccDetect(dev)) {
303 accHardware = ACC_BMI270;
304 break;
306 FALLTHROUGH;
307 #endif
309 #ifdef USE_ACCGYRO_LSM6DSO
310 case ACC_LSM6DSO:
311 if (lsm6dsoSpiAccDetect(dev)) {
312 accHardware = ACC_LSM6DSO;
313 break;
315 FALLTHROUGH;
316 #endif
318 #ifdef USE_FAKE_ACC
319 case ACC_FAKE:
320 if (fakeAccDetect(dev)) {
321 accHardware = ACC_FAKE;
322 break;
324 FALLTHROUGH;
325 #endif
327 default:
328 case ACC_NONE: // disable ACC
329 accHardware = ACC_NONE;
330 break;
333 // Found anything? Check if error or ACC is really missing.
334 if (accHardware == ACC_NONE && accHardwareToUse != ACC_DEFAULT && accHardwareToUse != ACC_NONE) {
335 // Nothing was found and we have a forced sensor that isn't present.
336 accHardwareToUse = ACC_DEFAULT;
337 goto retry;
340 if (accHardware == ACC_NONE) {
341 return false;
344 detectedSensors[SENSOR_INDEX_ACC] = accHardware;
345 sensorsSet(SENSOR_ACC);
346 return true;
349 void accInitFilters(void)
351 // Only set the lowpass cutoff if the ACC sample rate is detected otherwise
352 // the filter initialization is not defined (sample rate = 0)
353 accelerationRuntime.accLpfCutHz = (acc.sampleRateHz) ? accelerometerConfig()->acc_lpf_hz : 0;
354 if (accelerationRuntime.accLpfCutHz) {
355 const uint32_t accSampleTimeUs = 1e6 / acc.sampleRateHz;
356 for (int axis = 0; axis < XYZ_AXIS_COUNT; axis++) {
357 biquadFilterInitLPF(&accelerationRuntime.accFilter[axis], accelerationRuntime.accLpfCutHz, accSampleTimeUs);
362 bool accInit(uint16_t accSampleRateHz)
364 memset(&acc, 0, sizeof(acc));
365 // copy over the common gyro mpu settings
366 acc.dev.gyro = gyroActiveDev();
367 acc.dev.mpuDetectionResult = *gyroMpuDetectionResult();
368 acc.dev.acc_high_fsr = accelerometerConfig()->acc_high_fsr;
370 // Copy alignment from active gyro, as all production boards use acc-gyro-combi chip.
371 // Exceptions are STM32F3DISCOVERY and STM32F411DISCOVERY, and (may be) handled in future enhancement.
373 sensor_align_e alignment = gyroDeviceConfig(0)->alignment;
374 const sensorAlignment_t* customAlignment = &gyroDeviceConfig(0)->customAlignment;
376 #ifdef USE_MULTI_GYRO
377 if (gyroConfig()->gyro_to_use == GYRO_CONFIG_USE_GYRO_2) {
378 alignment = gyroDeviceConfig(1)->alignment;
380 customAlignment = &gyroDeviceConfig(1)->customAlignment;
382 #endif
383 acc.dev.accAlign = alignment;
384 buildRotationMatrixFromAlignment(customAlignment, &acc.dev.rotationMatrix);
386 if (!accDetect(&acc.dev, accelerometerConfig()->acc_hardware)) {
387 return false;
389 acc.dev.acc_1G = 256; // set default
390 acc.dev.initFn(&acc.dev); // driver initialisation
391 acc.dev.acc_1G_rec = 1.0f / acc.dev.acc_1G;
393 acc.sampleRateHz = accSampleRateHz;
394 accInitFilters();
395 return true;
398 void accStartCalibration(void)
400 accelerationRuntime.calibratingA = CALIBRATING_ACC_CYCLES;
403 bool accIsCalibrationComplete(void)
405 return accelerationRuntime.calibratingA == 0;
408 static bool isOnFinalAccelerationCalibrationCycle(void)
410 return accelerationRuntime.calibratingA == 1;
413 static bool isOnFirstAccelerationCalibrationCycle(void)
415 return accelerationRuntime.calibratingA == CALIBRATING_ACC_CYCLES;
418 void performAcclerationCalibration(rollAndPitchTrims_t *rollAndPitchTrims)
420 static int32_t a[3];
422 for (int axis = 0; axis < 3; axis++) {
424 // Reset a[axis] at start of calibration
425 if (isOnFirstAccelerationCalibrationCycle()) {
426 a[axis] = 0;
429 // Sum up CALIBRATING_ACC_CYCLES readings
430 a[axis] += acc.accADC[axis];
432 // Reset global variables to prevent other code from using un-calibrated data
433 acc.accADC[axis] = 0;
434 accelerationRuntime.accelerationTrims->raw[axis] = 0;
437 if (isOnFinalAccelerationCalibrationCycle()) {
438 // Calculate average, shift Z down by acc_1G and store values in EEPROM at end of calibration
439 accelerationRuntime.accelerationTrims->raw[X] = (a[X] + (CALIBRATING_ACC_CYCLES / 2)) / CALIBRATING_ACC_CYCLES;
440 accelerationRuntime.accelerationTrims->raw[Y] = (a[Y] + (CALIBRATING_ACC_CYCLES / 2)) / CALIBRATING_ACC_CYCLES;
441 accelerationRuntime.accelerationTrims->raw[Z] = (a[Z] + (CALIBRATING_ACC_CYCLES / 2)) / CALIBRATING_ACC_CYCLES - acc.dev.acc_1G;
443 resetRollAndPitchTrims(rollAndPitchTrims);
444 setConfigCalibrationCompleted();
446 saveConfigAndNotify();
449 accelerationRuntime.calibratingA--;
452 void performInflightAccelerationCalibration(rollAndPitchTrims_t *rollAndPitchTrims)
454 static int32_t b[3];
455 static int16_t accZero_saved[3] = { 0, 0, 0 };
456 static rollAndPitchTrims_t angleTrim_saved = { { 0, 0 } };
458 // Saving old zeropoints before measurement
459 if (InflightcalibratingA == 50) {
460 accZero_saved[X] = accelerationRuntime.accelerationTrims->raw[X];
461 accZero_saved[Y] = accelerationRuntime.accelerationTrims->raw[Y];
462 accZero_saved[Z] = accelerationRuntime.accelerationTrims->raw[Z];
463 angleTrim_saved.values.roll = rollAndPitchTrims->values.roll;
464 angleTrim_saved.values.pitch = rollAndPitchTrims->values.pitch;
466 if (InflightcalibratingA > 0) {
467 for (int axis = 0; axis < 3; axis++) {
468 // Reset a[axis] at start of calibration
469 if (InflightcalibratingA == 50)
470 b[axis] = 0;
471 // Sum up 50 readings
472 b[axis] += acc.accADC[axis];
473 // Clear global variables for next reading
474 acc.accADC[axis] = 0;
475 accelerationRuntime.accelerationTrims->raw[axis] = 0;
477 // all values are measured
478 if (InflightcalibratingA == 1) {
479 AccInflightCalibrationActive = false;
480 AccInflightCalibrationMeasurementDone = true;
481 beeper(BEEPER_ACC_CALIBRATION); // indicate end of calibration
482 // recover saved values to maintain current flight behaviour until new values are transferred
483 accelerationRuntime.accelerationTrims->raw[X] = accZero_saved[X];
484 accelerationRuntime.accelerationTrims->raw[Y] = accZero_saved[Y];
485 accelerationRuntime.accelerationTrims->raw[Z] = accZero_saved[Z];
486 rollAndPitchTrims->values.roll = angleTrim_saved.values.roll;
487 rollAndPitchTrims->values.pitch = angleTrim_saved.values.pitch;
489 InflightcalibratingA--;
491 // Calculate average, shift Z down by acc_1G and store values in EEPROM at end of calibration
492 if (AccInflightCalibrationSavetoEEProm) { // the aircraft is landed, disarmed and the combo has been done again
493 AccInflightCalibrationSavetoEEProm = false;
494 accelerationRuntime.accelerationTrims->raw[X] = b[X] / 50;
495 accelerationRuntime.accelerationTrims->raw[Y] = b[Y] / 50;
496 accelerationRuntime.accelerationTrims->raw[Z] = b[Z] / 50 - acc.dev.acc_1G; // for nunchuck 200=1G
498 resetRollAndPitchTrims(rollAndPitchTrims);
499 setConfigCalibrationCompleted();
501 saveConfigAndNotify();
505 void setAccelerationTrims(flightDynamicsTrims_t *accelerationTrimsToUse)
507 accelerationRuntime.accelerationTrims = accelerationTrimsToUse;
510 void applyAccelerometerTrimsDelta(rollAndPitchTrims_t *rollAndPitchTrimsDelta)
512 accelerometerConfigMutable()->accelerometerTrims.values.roll += rollAndPitchTrimsDelta->values.roll;
513 accelerometerConfigMutable()->accelerometerTrims.values.pitch += rollAndPitchTrimsDelta->values.pitch;
515 #endif