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233 lines
4.7 KiB
233 lines
4.7 KiB
/* sensors.c */ |
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#include "mpu6050.h" |
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#include "dcm.h" |
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#include "fisqrt.h" |
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#include "watchdog.h" |
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#include "status.h" |
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#include "abs.h" |
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#include "panic.h" |
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#include "uart.h" |
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#include "log.h" |
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#include "stick.h" |
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bool (*sensor_start_fns[])(void) = { |
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mpu6050_start_sample, |
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}; |
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#define SENSOR_START_FNS (sizeof(sensor_start_fns)/sizeof(sensor_start_fns[0])) |
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static unsigned int next_sensor; |
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static bool sensors_zero; |
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static bool sensors_update; |
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static unsigned int sensors_discard; |
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static unsigned int sensors_generation; |
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float sensors_gyro_roll; |
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float sensors_gyro_pitch; |
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float sensors_gyro_yaw; |
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float sensors_temp; |
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float sensors_accel_x; |
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float sensors_accel_y; |
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float sensors_accel_z; |
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float gyro_yaw_zero; |
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float gyro_pitch_zero; |
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float gyro_roll_zero; |
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void sensors_write_log(void); |
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void sensors_process(void); |
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#define TWO_PI 6.28318531f |
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#define DEG_TO_RAD (TWO_PI/360.0f) |
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/* The gyro has to stay within this limit in each axis in order to arm */ |
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#define GYRO_RATE_THRESHOLD (0.01 / DEG_TO_RAD) |
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#define GYRO_ZERO_COUNT 1000 |
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void sensors_dump(void); |
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bool sensors_init(void) |
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{ |
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next_sensor = 0; |
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if (!mpu6050_init()) |
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return FALSE; |
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return TRUE; |
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} |
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bool sensors_next_sample(void) |
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{ |
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bool result; |
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result = (sensor_start_fns[next_sensor])(); |
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if (next_sensor >= SENSOR_START_FNS) |
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next_sensor = 0; |
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return result; |
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} |
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void sensors_sample_done(void) |
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{ |
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if (next_sensor == 0) { |
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sensors_write_log(); |
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return; |
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} |
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if (!sensors_next_sample()) |
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panic(PANIC_SENSOR_FAIL); |
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} |
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bool sensors_start_sample(void) |
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{ |
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next_sensor = 0; |
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return sensors_next_sample(); |
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} |
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void sensors_write_gyro_data(float roll, float pitch, float yaw) |
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{ |
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#if 0 |
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sensors_gyro_roll = roll - gyro_roll_zero; |
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sensors_gyro_pitch = pitch - gyro_pitch_zero; |
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sensors_gyro_yaw = yaw - gyro_yaw_zero; |
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#else |
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sensors_gyro_roll = roll; |
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sensors_gyro_pitch = pitch; |
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sensors_gyro_yaw = yaw; |
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#endif |
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} |
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void sensors_write_accel_data(float x, float y, float z) |
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{ |
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sensors_accel_x = x; |
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sensors_accel_y = y; |
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sensors_accel_z = z; |
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} |
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void sensors_write_temp_data(float temp) |
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{ |
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sensors_temp = temp; |
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/* XXX HACK find a better place for this call */ |
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sensors_process(); |
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} |
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#define LOG_SIGNATURE_SENSORS 0xDA7ADA7A |
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#define LOG_SIGNATURE_SENSORS2 0xDA7AF173 |
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void sensors_write_log(void) |
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{ |
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#if 0 |
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log_put_uint(LOG_SIGNATURE_SENSORS); |
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log_put_float(sensors_accel_x); |
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log_put_float(sensors_accel_y); |
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log_put_float(sensors_accel_z); |
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log_put_float(sensors_gyro_roll); |
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log_put_float(sensors_gyro_pitch); |
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log_put_float(sensors_gyro_yaw); |
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log_put_float(sensors_temp); |
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#else |
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/* XXX this just about comes out in the right place, but by luck */ |
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log_put_uint(LOG_SIGNATURE_SENSORS2); |
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#endif |
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} |
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void sensors_start_zero(void) |
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{ |
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sensors_zero = TRUE; |
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sensors_update = FALSE; |
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sensors_discard = 100; |
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sensors_generation = 0; |
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putstr("Starting zero\r\n"); |
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mpu6050_start_zero(); |
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} |
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void sensors_process(void) |
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{ |
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if (sensors_update) { |
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#if 1 |
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dcm_update(-sensors_gyro_pitch, -sensors_gyro_roll, |
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-sensors_gyro_yaw); |
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#else |
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dcm_update(0.0, 0.0, 0.0); |
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#endif |
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if (!status_armed()) { |
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if ( (abs(sensors_gyro_roll) < GYRO_RATE_THRESHOLD) && |
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(abs(sensors_gyro_pitch) < GYRO_RATE_THRESHOLD) && |
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(abs(sensors_gyro_yaw) < GYRO_RATE_THRESHOLD)) { |
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status_set_ready(STATUS_MODULE_GYRO_RATE, TRUE); |
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} else { |
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status_set_ready(STATUS_MODULE_GYRO_RATE, FALSE); |
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} |
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} |
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sensors_generation++; |
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#if SEND_DCM |
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if ((sensors_generation % 40) == 0) { |
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dcm_send_packet(); |
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sensors_dump(); |
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} |
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#endif |
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} else if (sensors_zero) { |
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if (sensors_discard) { |
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sensors_discard--; |
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} else { |
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gyro_yaw_zero += sensors_gyro_yaw; |
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gyro_pitch_zero += sensors_gyro_pitch; |
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gyro_roll_zero += sensors_gyro_roll; |
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sensors_generation++; |
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if (sensors_generation >= GYRO_ZERO_COUNT) { |
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sensors_zero = FALSE; |
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sensors_update = TRUE; |
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sensors_generation = 0; |
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gyro_yaw_zero /= GYRO_ZERO_COUNT; |
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gyro_pitch_zero /= GYRO_ZERO_COUNT; |
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gyro_roll_zero /= GYRO_ZERO_COUNT; |
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putstr("Zero finished\r\n"); |
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status_set_ready(STATUS_MODULE_GYRO_ZERO, TRUE); |
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} |
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} |
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} |
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watchdog_kick(WATCHDOG_GYRO); |
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#if 1 |
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dcm_drift_correction(-sensors_accel_y, -sensors_accel_x, |
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-sensors_accel_z); |
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#endif |
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#if 0 |
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dcm_drift_correction(sensors_accel_x, sensors_accel_y, |
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sensors_accel_z); |
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#endif |
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watchdog_kick(WATCHDOG_ACCEL); |
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stick_input(); |
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} |
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void sensors_dump(void) |
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{ |
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putstr("("); |
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putint_s((int)(sensors_accel_x * 1000.0)); |
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putstr(","); |
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putint_s((int)(sensors_accel_y * 1000.0)); |
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putstr(","); |
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putint_s((int)(sensors_accel_z * 1000.0)); |
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putstr(")"); |
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putstr("("); |
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putint_s((int)(sensors_gyro_roll * 1000.0)); |
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putstr(","); |
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putint_s((int)(sensors_gyro_pitch * 1000.0)); |
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putstr(","); |
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putint_s((int)(sensors_gyro_yaw * 1000.0)); |
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putstr(")"); |
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putstr("("); |
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putint_s((int)(sensors_temp * 1000.0)); |
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putstr(")\r\n"); |
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}
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