2016-01-19 21:26:31 -04:00
# pragma once
2011-11-12 23:20:25 -04:00
2012-11-05 00:27:03 -04:00
// Gyro and Accelerometer calibration criteria
2013-01-10 14:42:24 -04:00
# define AP_INERTIAL_SENSOR_ACCEL_TOT_MAX_OFFSET_CHANGE 4.0f
# define AP_INERTIAL_SENSOR_ACCEL_MAX_OFFSET 250.0f
2015-06-11 04:15:57 -03:00
# define AP_INERTIAL_SENSOR_ACCEL_VIBE_FLOOR_FILT_HZ 5.0f // accel vibration floor filter hz
# define AP_INERTIAL_SENSOR_ACCEL_VIBE_FILT_HZ 2.0f // accel vibration filter hz
2015-12-29 13:18:07 -04:00
# define AP_INERTIAL_SENSOR_ACCEL_PEAK_DETECT_TIMEOUT_MS 500 // peak-hold detector timeout
2012-11-05 00:27:03 -04:00
2020-10-04 00:18:30 -03:00
# include <AP_HAL/AP_HAL.h>
2013-12-08 18:50:12 -04:00
/**
maximum number of INS instances available on this platform . If more
2015-10-14 10:59:40 -03:00
than 1 then redundant sensors may be available
2013-12-08 18:50:12 -04:00
*/
2020-11-07 02:43:06 -04:00
# ifndef INS_MAX_INSTANCES
2014-07-14 07:53:59 -03:00
# define INS_MAX_INSTANCES 3
2020-11-07 02:43:06 -04:00
# endif
# define INS_MAX_BACKENDS 2*INS_MAX_INSTANCES
2020-05-29 13:28:06 -03:00
# define INS_MAX_NOTCHES 4
2020-10-04 00:18:30 -03:00
# ifndef INS_VIBRATION_CHECK_INSTANCES
# if HAL_MEM_CLASS >= HAL_MEM_CLASS_300
# define INS_VIBRATION_CHECK_INSTANCES INS_MAX_INSTANCES
# else
# define INS_VIBRATION_CHECK_INSTANCES 1
# endif
# endif
2019-07-23 05:43:18 -03:00
# define XYZ_AXIS_COUNT 3
// The maximum we need to store is gyro-rate / loop-rate, worst case ArduCopter with BMI088 is 2000/400
# define INS_MAX_GYRO_WINDOW_SAMPLES 8
2014-10-15 20:32:40 -03:00
2017-10-03 20:44:07 -03:00
# define DEFAULT_IMU_LOG_BAT_MASK 0
2021-01-07 20:46:35 -04:00
# ifndef HAL_INS_TEMPERATURE_CAL_ENABLE
# define HAL_INS_TEMPERATURE_CAL_ENABLE !HAL_MINIMIZE_FEATURES && BOARD_FLASH_SIZE > 1024
# endif
2012-10-11 21:27:19 -03:00
# include <stdint.h>
2016-01-19 21:26:31 -04:00
# include <AP_AccelCal/AP_AccelCal.h>
2015-08-11 03:28:43 -03:00
# include <AP_HAL/AP_HAL.h>
2020-03-27 19:08:30 -03:00
# include <AP_HAL/utility/RingBuffer.h>
2015-08-11 03:28:43 -03:00
# include <AP_Math/AP_Math.h>
2020-12-28 22:29:40 -04:00
# include <AP_ExternalAHRS/AP_ExternalAHRS.h>
2015-11-15 20:05:20 -04:00
# include <Filter/LowPassFilter2p.h>
2016-01-19 21:26:31 -04:00
# include <Filter/LowPassFilter.h>
2017-08-16 02:27:58 -03:00
# include <Filter/NotchFilter.h>
2019-06-17 05:44:12 -03:00
# include <Filter/HarmonicNotchFilter.h>
2021-01-09 01:23:18 -04:00
# include <AP_Math/polyfit.h>
2014-10-14 01:48:33 -03:00
class AP_InertialSensor_Backend ;
2015-08-05 13:36:14 -03:00
class AuxiliaryBus ;
2017-06-05 00:03:28 -03:00
class AP_AHRS ;
2014-10-14 01:48:33 -03:00
2015-05-06 23:08:30 -03:00
/*
2019-01-18 00:23:42 -04:00
forward declare AP_Logger class . We can ' t include logger . h
2015-05-06 23:08:30 -03:00
because of mutual dependencies
*/
2019-01-18 00:23:42 -04:00
class AP_Logger ;
2015-05-06 23:08:30 -03:00
2011-11-12 23:20:25 -04:00
/* AP_InertialSensor is an abstraction for gyro and accel measurements
* which are correctly aligned to the body axes and scaled to SI units .
2012-12-04 20:20:31 -04:00
*
* Gauss - Newton accel calibration routines borrowed from Rolfe Schmidt
* blog post describing the method : http : //chionophilous.wordpress.com/2011/10/24/accelerometer-calibration-iv-1-implementing-gauss-newton-on-an-atmega/
* original sketch available at http : //rolfeschmidt.com/mathtools/skimetrics/adxl_gn_calibration.pde
2011-11-12 23:20:25 -04:00
*/
2015-07-20 17:25:40 -03:00
class AP_InertialSensor : AP_AccelCal_Client
2011-11-12 23:20:25 -04:00
{
2014-10-14 01:48:33 -03:00
friend class AP_InertialSensor_Backend ;
2012-08-17 03:19:56 -03:00
public :
2017-12-12 21:06:12 -04:00
AP_InertialSensor ( ) ;
2017-08-08 12:17:57 -03:00
/* Do not allow copies */
AP_InertialSensor ( const AP_InertialSensor & other ) = delete ;
AP_InertialSensor & operator = ( const AP_InertialSensor & ) = delete ;
2015-07-20 17:25:40 -03:00
2019-02-10 14:29:24 -04:00
static AP_InertialSensor * get_singleton ( ) ;
2012-11-05 00:27:03 -04:00
2015-09-17 03:42:41 -03:00
enum Gyro_Calibration_Timing {
GYRO_CAL_NEVER = 0 ,
2015-10-15 03:06:34 -03:00
GYRO_CAL_STARTUP_ONLY = 1
2015-09-17 03:42:41 -03:00
} ;
2012-11-05 00:27:03 -04:00
/// Perform startup initialisation.
///
/// Called to initialise the state of the IMU.
///
2015-09-17 03:42:41 -03:00
/// Gyros will be calibrated unless INS_GYRO_CAL is zero
2012-11-05 00:27:03 -04:00
///
/// @param style The initialisation startup style.
///
2015-12-25 23:11:33 -04:00
void init ( uint16_t sample_rate_hz ) ;
2012-11-05 00:27:03 -04:00
2014-10-14 01:48:33 -03:00
/// Register a new gyro/accel driver, allocating an instance
/// number
2016-09-03 21:51:37 -03:00
uint8_t register_gyro ( uint16_t raw_sample_rate_hz , uint32_t id ) ;
uint8_t register_accel ( uint16_t raw_sample_rate_hz , uint32_t id ) ;
2012-11-05 00:27:03 -04:00
2017-10-03 20:44:07 -03:00
// a function called by the main thread at the main loop rate:
void periodic ( ) ;
2015-05-15 18:22:25 -03:00
bool calibrate_trim ( float & trim_roll , float & trim_pitch ) ;
2012-11-05 00:27:03 -04:00
2015-03-09 03:31:55 -03:00
/// calibrating - returns true if the gyros or accels are currently being calibrated
2021-01-07 20:46:35 -04:00
bool calibrating ( ) const ;
2015-03-09 03:31:55 -03:00
2021-01-10 16:09:44 -04:00
/// calibrating - returns true if a temperature calibration is running
bool temperature_cal_running ( ) const ;
2012-11-05 00:27:03 -04:00
/// Perform cold-start initialisation for just the gyros.
///
/// @note This should not be called unless ::init has previously
/// been called, as ::init may perform other work
///
2014-10-14 01:48:33 -03:00
void init_gyro ( void ) ;
2012-11-05 00:27:03 -04:00
2020-05-21 15:29:28 -03:00
// get startup messages to output to the GCS
bool get_output_banner ( uint8_t instance_id , char * banner , uint8_t banner_len ) ;
2012-11-05 00:27:03 -04:00
/// Fetch the current gyro values
///
/// @returns vector of rotational rates in radians/sec
///
2013-12-08 18:50:12 -04:00
const Vector3f & get_gyro ( uint8_t i ) const { return _gyro [ i ] ; }
2014-10-14 01:48:33 -03:00
const Vector3f & get_gyro ( void ) const { return get_gyro ( _primary_gyro ) ; }
2012-11-05 00:27:03 -04:00
// set gyro offsets in radians/sec
2013-12-08 18:50:12 -04:00
const Vector3f & get_gyro_offsets ( uint8_t i ) const { return _gyro_offset [ i ] ; }
2014-10-14 01:48:33 -03:00
const Vector3f & get_gyro_offsets ( void ) const { return get_gyro_offsets ( _primary_gyro ) ; }
2012-11-05 00:27:03 -04:00
2015-02-17 02:54:17 -04:00
//get delta angle if available
2021-02-11 17:34:37 -04:00
bool get_delta_angle ( uint8_t i , Vector3f & delta_angle , float & delta_angle_dt ) const ;
bool get_delta_angle ( Vector3f & delta_angle , float & delta_angle_dt ) const {
return get_delta_angle ( _primary_gyro , delta_angle , delta_angle_dt ) ;
}
2016-01-19 21:26:31 -04:00
2015-02-17 02:54:17 -04:00
//get delta velocity if available
2021-02-11 17:34:37 -04:00
bool get_delta_velocity ( uint8_t i , Vector3f & delta_velocity , float & delta_velocity_dt ) const ;
bool get_delta_velocity ( Vector3f & delta_velocity , float & delta_velocity_dt ) const {
return get_delta_velocity ( _primary_accel , delta_velocity , delta_velocity_dt ) ;
}
2015-03-21 17:18:58 -03:00
2012-11-05 00:27:03 -04:00
/// Fetch the current accelerometer values
///
/// @returns vector of current accelerations in m/s/s
///
2013-12-08 18:50:12 -04:00
const Vector3f & get_accel ( uint8_t i ) const { return _accel [ i ] ; }
2014-10-14 01:48:33 -03:00
const Vector3f & get_accel ( void ) const { return get_accel ( _primary_accel ) ; }
2012-11-05 00:27:03 -04:00
2014-12-29 06:19:35 -04:00
uint32_t get_gyro_error_count ( uint8_t i ) const { return _gyro_error_count [ i ] ; }
uint32_t get_accel_error_count ( uint8_t i ) const { return _accel_error_count [ i ] ; }
2013-12-08 05:43:53 -04:00
// multi-device interface
2015-04-17 00:34:33 -03:00
bool get_gyro_health ( uint8_t instance ) const { return ( instance < _gyro_count ) ? _gyro_healthy [ instance ] : false ; }
2014-10-14 01:48:33 -03:00
bool get_gyro_health ( void ) const { return get_gyro_health ( _primary_gyro ) ; }
2014-09-01 08:20:27 -03:00
bool get_gyro_health_all ( void ) const ;
2014-10-14 01:48:33 -03:00
uint8_t get_gyro_count ( void ) const { return _gyro_count ; }
2014-10-08 08:17:31 -03:00
bool gyro_calibrated_ok ( uint8_t instance ) const { return _gyro_cal_ok [ instance ] ; }
bool gyro_calibrated_ok_all ( ) const ;
2015-08-01 03:40:40 -03:00
bool use_gyro ( uint8_t instance ) const ;
2019-04-11 06:51:25 -03:00
Gyro_Calibration_Timing gyro_calibration_timing ( ) ;
2013-12-08 05:43:53 -04:00
2015-04-17 00:34:33 -03:00
bool get_accel_health ( uint8_t instance ) const { return ( instance < _accel_count ) ? _accel_healthy [ instance ] : false ; }
2014-10-14 01:48:33 -03:00
bool get_accel_health ( void ) const { return get_accel_health ( _primary_accel ) ; }
2014-09-01 08:20:27 -03:00
bool get_accel_health_all ( void ) const ;
2016-07-01 02:35:22 -03:00
uint8_t get_accel_count ( void ) const { return _accel_count ; }
2015-05-12 03:18:25 -03:00
bool accel_calibrated_ok_all ( ) const ;
2015-08-01 03:40:40 -03:00
bool use_accel ( uint8_t instance ) const ;
2013-12-08 05:43:53 -04:00
2017-05-01 00:01:43 -03:00
// get observed sensor rates, including any internal sampling multiplier
uint16_t get_gyro_rate_hz ( uint8_t instance ) const { return uint16_t ( _gyro_raw_sample_rates [ instance ] * _gyro_over_sampling [ instance ] ) ; }
uint16_t get_accel_rate_hz ( uint8_t instance ) const { return uint16_t ( _accel_raw_sample_rates [ instance ] * _accel_over_sampling [ instance ] ) ; }
2017-08-08 12:17:57 -03:00
2019-07-23 05:43:18 -03:00
// FFT support access
2020-01-03 15:52:33 -04:00
# if HAL_WITH_DSP
2019-07-23 05:43:18 -03:00
const Vector3f & get_raw_gyro ( void ) const { return _gyro_raw [ _primary_gyro ] ; }
2020-03-27 19:08:30 -03:00
FloatBuffer & get_raw_gyro_window ( uint8_t instance , uint8_t axis ) { return _gyro_window [ instance ] [ axis ] ; }
FloatBuffer & get_raw_gyro_window ( uint8_t axis ) { return get_raw_gyro_window ( _primary_gyro , axis ) ; }
2019-07-23 05:43:18 -03:00
uint16_t get_raw_gyro_rate_hz ( ) const { return get_raw_gyro_rate_hz ( _primary_gyro ) ; }
uint16_t get_raw_gyro_rate_hz ( uint8_t instance ) const { return _gyro_raw_sample_rates [ _primary_gyro ] ; }
2020-01-03 15:52:33 -04:00
# endif
2019-07-23 05:43:18 -03:00
bool set_gyro_window_size ( uint16_t size ) ;
2012-11-05 00:27:03 -04:00
// get accel offsets in m/s/s
2013-12-08 18:50:12 -04:00
const Vector3f & get_accel_offsets ( uint8_t i ) const { return _accel_offset [ i ] ; }
2014-10-14 01:48:33 -03:00
const Vector3f & get_accel_offsets ( void ) const { return get_accel_offsets ( _primary_accel ) ; }
2012-11-05 00:27:03 -04:00
// get accel scale
2013-12-08 18:50:12 -04:00
const Vector3f & get_accel_scale ( uint8_t i ) const { return _accel_scale [ i ] ; }
2014-10-14 01:48:33 -03:00
const Vector3f & get_accel_scale ( void ) const { return get_accel_scale ( _primary_accel ) ; }
2012-08-17 03:19:56 -03:00
2016-10-07 19:11:10 -03:00
// return a 3D vector defining the position offset of the IMU accelerometer in metres relative to the body frame origin
2016-10-27 01:06:11 -03:00
const Vector3f & get_imu_pos_offset ( uint8_t instance ) const {
2016-10-07 19:11:10 -03:00
return _accel_pos [ instance ] ;
}
2016-10-27 01:06:11 -03:00
const Vector3f & get_imu_pos_offset ( void ) const {
2016-10-07 19:11:10 -03:00
return _accel_pos [ _primary_accel ] ;
}
2015-03-16 23:32:54 -03:00
// return the temperature if supported. Zero is returned if no
// temperature is available
float get_temperature ( uint8_t instance ) const { return _temperature [ instance ] ; }
2012-11-05 00:27:03 -04:00
/* get_delta_time returns the time period in seconds
2012-08-30 04:48:36 -03:00
* overwhich the sensor data was collected
2012-08-17 03:19:56 -03:00
*/
2017-12-04 01:33:36 -04:00
float get_delta_time ( ) const { return MIN ( _delta_time , _loop_delta_t_max ) ; }
2012-08-17 03:19:56 -03:00
// return the maximum gyro drift rate in radians/s/s. This
// depends on what gyro chips are being used
2014-10-14 01:48:33 -03:00
float get_gyro_drift_rate ( void ) const { return ToRad ( 0.5f / 60 ) ; }
2012-03-08 03:10:27 -04:00
2014-10-14 01:48:33 -03:00
// update gyro and accel values from accumulated samples
void update ( void ) ;
// wait for a sample to be available
void wait_for_sample ( void ) ;
2013-10-08 03:28:39 -03:00
2012-11-05 00:27:03 -04:00
// class level parameters
static const struct AP_Param : : GroupInfo var_info [ ] ;
2013-01-13 01:03:13 -04:00
// set overall board orientation
2018-03-08 22:26:39 -04:00
void set_board_orientation ( enum Rotation orientation , Matrix3f * custom_rotation = nullptr ) {
2013-01-13 01:03:13 -04:00
_board_orientation = orientation ;
2018-03-08 22:26:39 -04:00
_custom_rotation = custom_rotation ;
2013-01-13 01:03:13 -04:00
}
2020-05-21 15:29:28 -03:00
// return the selected loop rate at which samples are made avilable
uint16_t get_loop_rate_hz ( void ) const { return _loop_rate ; }
2014-10-16 17:52:21 -03:00
2015-12-25 22:34:34 -04:00
// return the main loop delta_t in seconds
float get_loop_delta_t ( void ) const { return _loop_delta_t ; }
2016-01-19 21:26:31 -04:00
2014-10-14 01:48:33 -03:00
bool healthy ( void ) const { return get_gyro_health ( ) & & get_accel_health ( ) ; }
2012-11-05 00:27:03 -04:00
2015-04-16 20:41:54 -03:00
uint8_t get_primary_accel ( void ) const { return _primary_accel ; }
uint8_t get_primary_gyro ( void ) const { return _primary_gyro ; }
2013-12-09 05:02:04 -04:00
2019-06-17 05:44:12 -03:00
// Update the harmonic notch frequency
void update_harmonic_notch_freq_hz ( float scaled_freq ) ;
2020-05-29 13:28:06 -03:00
// Update the harmonic notch frequencies
void update_harmonic_notch_frequencies_hz ( uint8_t num_freqs , const float scaled_freq [ ] ) ;
2019-06-17 05:44:12 -03:00
2014-10-15 20:32:40 -03:00
// enable HIL mode
void set_hil_mode ( void ) { _hil_mode = true ; }
2015-03-11 22:19:31 -03:00
// get the gyro filter rate in Hz
2019-05-25 07:59:57 -03:00
uint16_t get_gyro_filter_hz ( void ) const { return _gyro_filter_cutoff ; }
2015-03-11 22:19:31 -03:00
// get the accel filter rate in Hz
2019-05-25 07:59:57 -03:00
uint16_t get_accel_filter_hz ( void ) const { return _accel_filter_cutoff ; }
2015-03-11 22:19:31 -03:00
2019-06-17 05:44:12 -03:00
// harmonic notch current center frequency
2020-05-29 13:28:06 -03:00
float get_gyro_dynamic_notch_center_freq_hz ( void ) const { return _calculated_harmonic_notch_freq_hz [ 0 ] ; }
// set of harmonic notch current center frequencies
const float * get_gyro_dynamic_notch_center_frequencies_hz ( void ) const { return _calculated_harmonic_notch_freq_hz ; }
// number of harmonic notch current center frequencies
uint8_t get_num_gyro_dynamic_notch_center_frequencies ( void ) const { return _num_calculated_harmonic_notch_frequencies ; }
2019-06-17 05:44:12 -03:00
// harmonic notch reference center frequency
float get_gyro_harmonic_notch_center_freq_hz ( void ) const { return _harmonic_notch_filter . center_freq_hz ( ) ; }
// harmonic notch reference scale factor
float get_gyro_harmonic_notch_reference ( void ) const { return _harmonic_notch_filter . reference ( ) ; }
2019-10-12 14:37:07 -03:00
// harmonic notch tracking mode
2019-11-17 01:16:18 -04:00
HarmonicNotchDynamicMode get_gyro_harmonic_notch_tracking_mode ( void ) const { return _harmonic_notch_filter . tracking_mode ( ) ; }
2019-10-12 14:37:07 -03:00
2019-07-23 05:43:18 -03:00
// harmonic notch harmonics
uint8_t get_gyro_harmonic_notch_harmonics ( void ) const { return _harmonic_notch_filter . harmonics ( ) ; }
2020-05-29 13:28:06 -03:00
// harmonic notch options
bool has_harmonic_option ( HarmonicNotchFilterParams : : Options option ) {
return _harmonic_notch_filter . hasOption ( option ) ;
}
2017-06-27 01:42:45 -03:00
// indicate which bit in LOG_BITMASK indicates raw logging enabled
void set_log_raw_bit ( uint32_t log_raw_bit ) { _log_raw_bit = log_raw_bit ; }
2015-05-06 23:08:30 -03:00
2015-06-11 04:15:57 -03:00
// calculate vibration levels and check for accelerometer clipping (called by a backends)
void calc_vibration_and_clipping ( uint8_t instance , const Vector3f & accel , float dt ) ;
// retrieve latest calculated vibration levels
2015-07-30 04:58:06 -03:00
Vector3f get_vibration_levels ( ) const { return get_vibration_levels ( _primary_accel ) ; }
Vector3f get_vibration_levels ( uint8_t instance ) const ;
2015-06-11 04:15:57 -03:00
// retrieve and clear accelerometer clipping count
uint32_t get_accel_clip_count ( uint8_t instance ) const ;
2015-07-29 16:34:48 -03:00
// check for vibration movement. True when all axis show nearly zero movement
bool is_still ( ) ;
2019-11-17 01:26:22 -04:00
// return true if harmonic notch enabled
bool gyro_harmonic_notch_enabled ( void ) const { return _harmonic_notch_filter . enabled ( ) ; }
2015-06-15 05:13:06 -03:00
/*
HIL set functions . The minimum for HIL is set_accel ( ) and
set_gyro ( ) . The others are option for higher fidelity log
playback
*/
void set_accel ( uint8_t instance , const Vector3f & accel ) ;
void set_gyro ( uint8_t instance , const Vector3f & gyro ) ;
void set_delta_time ( float delta_time ) ;
void set_delta_velocity ( uint8_t instance , float deltavt , const Vector3f & deltav ) ;
2016-04-26 02:50:46 -03:00
void set_delta_angle ( uint8_t instance , const Vector3f & deltaa , float deltaat ) ;
2015-06-15 05:13:06 -03:00
2015-10-02 15:45:21 -03:00
AuxiliaryBus * get_auxiliary_bus ( int16_t backend_id ) { return get_auxiliary_bus ( backend_id , 0 ) ; }
AuxiliaryBus * get_auxiliary_bus ( int16_t backend_id , uint8_t instance ) ;
2015-08-05 13:36:14 -03:00
2015-10-13 15:33:20 -03:00
void detect_backends ( void ) ;
2015-12-29 13:18:07 -04:00
// accel peak hold detector
void set_accel_peak_hold ( uint8_t instance , const Vector3f & accel ) ;
2015-12-30 23:23:04 -04:00
float get_accel_peak_hold_neg_x ( ) const { return _peak_hold_state . accel_peak_hold_neg_x ; }
2015-12-29 13:18:07 -04:00
2015-07-20 17:25:40 -03:00
//Returns accel calibrator interface object pointer
AP_AccelCal * get_acal ( ) const { return _acal ; }
// Returns body fixed accelerometer level data averaged during accel calibration's first step
bool get_fixed_mount_accel_cal_sample ( uint8_t sample_num , Vector3f & ret ) const ;
// Returns primary accelerometer level data averaged during accel calibration's first step
bool get_primary_accel_cal_sample_avg ( uint8_t sample_num , Vector3f & ret ) const ;
// Returns newly calculated trim values if calculated
bool get_new_trim ( float & trim_roll , float & trim_pitch ) ;
// initialise and register accel calibrator
// called during the startup of accel cal
void acal_init ( ) ;
// update accel calibrator
void acal_update ( ) ;
2015-12-29 00:32:06 -04:00
2017-06-05 00:03:28 -03:00
// simple accel calibration
2018-03-17 09:03:13 -03:00
MAV_RESULT simple_accel_cal ( ) ;
2017-11-27 01:54:55 -04:00
2015-12-29 00:32:06 -04:00
bool accel_cal_requires_reboot ( ) const { return _accel_cal_requires_reboot ; }
2017-04-28 21:26:58 -03:00
// return time in microseconds of last update() call
uint32_t get_last_update_usec ( void ) const { return _last_update_usec ; }
2017-08-08 12:17:57 -03:00
2019-04-18 01:24:01 -03:00
// for killing an IMU for testing purposes
void kill_imu ( uint8_t imu_idx , bool kill_it ) ;
2017-10-03 20:44:07 -03:00
enum IMU_SENSOR_TYPE {
IMU_SENSOR_TYPE_ACCEL = 0 ,
IMU_SENSOR_TYPE_GYRO = 1 ,
} ;
class BatchSampler {
public :
BatchSampler ( const AP_InertialSensor & imu ) :
type ( IMU_SENSOR_TYPE_ACCEL ) ,
_imu ( imu ) {
AP_Param : : setup_object_defaults ( this , var_info ) ;
} ;
void init ( ) ;
void sample ( uint8_t instance , IMU_SENSOR_TYPE _type , uint64_t sample_us , const Vector3f & sample ) ;
// a function called by the main thread at the main loop rate:
void periodic ( ) ;
2018-03-18 20:28:33 -03:00
bool doing_sensor_rate_logging ( ) const { return _doing_sensor_rate_logging ; }
2019-05-17 12:57:43 -03:00
bool doing_post_filter_logging ( ) const { return _doing_post_filter_logging ; }
2018-03-18 20:28:33 -03:00
2017-10-03 20:44:07 -03:00
// class level parameters
static const struct AP_Param : : GroupInfo var_info [ ] ;
// Parameters
AP_Int16 _required_count ;
AP_Int8 _sensor_mask ;
2018-03-18 20:28:33 -03:00
AP_Int8 _batch_options_mask ;
2019-01-18 00:23:42 -04:00
// Parameters controlling pushing data to AP_Logger:
2018-03-18 20:28:33 -03:00
// Each DF message is ~ 108 bytes in size, so we use about 1kB/s of
// logging bandwidth with a 100ms interval. If we are taking
// 1024 samples then we need to send 32 packets, so it will
// take ~3 seconds to push a complete batch to the log. If
// you are running a on an FMU with three IMUs then you
// will loop back around to the first sensor after about
// twenty seconds.
AP_Int16 samples_per_msg ;
AP_Int8 push_interval_ms ;
2017-10-03 20:44:07 -03:00
// end Parameters
private :
2018-03-18 20:28:33 -03:00
enum batch_opt_t {
BATCH_OPT_SENSOR_RATE = ( 1 < < 0 ) ,
2019-05-17 12:57:43 -03:00
BATCH_OPT_POST_FILTER = ( 1 < < 1 ) ,
2018-03-18 20:28:33 -03:00
} ;
2017-10-03 20:44:07 -03:00
void rotate_to_next_sensor ( ) ;
2018-03-18 20:28:33 -03:00
void update_doing_sensor_rate_logging ( ) ;
2017-10-03 20:44:07 -03:00
bool should_log ( uint8_t instance , IMU_SENSOR_TYPE type ) ;
void push_data_to_log ( ) ;
uint64_t measurement_started_us ;
bool initialised : 1 ;
bool isbh_sent : 1 ;
2018-03-18 20:28:33 -03:00
bool _doing_sensor_rate_logging : 1 ;
2019-05-17 12:57:43 -03:00
bool _doing_post_filter_logging : 1 ;
2017-10-03 20:44:07 -03:00
uint8_t instance : 3 ; // instance we are sending data for
AP_InertialSensor : : IMU_SENSOR_TYPE type : 1 ;
uint16_t isb_seqnum ;
int16_t * data_x ;
int16_t * data_y ;
int16_t * data_z ;
uint16_t data_write_offset ; // units: samples
uint16_t data_read_offset ; // units: samples
uint32_t last_sent_ms ;
// all samples are multiplied by this
2018-03-18 20:28:33 -03:00
uint16_t multiplier ; // initialised as part of init()
2017-10-03 20:44:07 -03:00
const AP_InertialSensor & _imu ;
} ;
BatchSampler batchsampler { * this } ;
2020-12-28 22:29:40 -04:00
# if HAL_EXTERNAL_AHRS_ENABLED
// handle external AHRS data
void handle_external ( const AP_ExternalAHRS : : ins_data_message_t & pkt ) ;
# endif
2021-01-16 00:59:35 -04:00
# if HAL_INS_TEMPERATURE_CAL_ENABLE
/*
get a string representation of parameters that should be made
persistent across changes of firmware type
*/
void get_persistent_params ( ExpandingString & str ) const ;
# endif
2021-02-10 20:49:08 -04:00
// force save of current calibration as valid
void force_save_calibration ( void ) ;
2014-10-14 01:48:33 -03:00
private :
// load backend drivers
2016-11-10 00:30:48 -04:00
bool _add_backend ( AP_InertialSensor_Backend * backend ) ;
2015-08-05 10:01:52 -03:00
void _start_backends ( ) ;
2015-10-02 15:45:21 -03:00
AP_InertialSensor_Backend * _find_backend ( int16_t backend_id , uint8_t instance ) ;
2012-10-11 21:27:19 -03:00
2015-03-10 20:16:04 -03:00
// gyro initialisation
2014-10-14 01:48:33 -03:00
void _init_gyro ( ) ;
2012-11-05 00:27:03 -04:00
2012-12-04 20:20:31 -04:00
// Calibration routines borrowed from Rolfe Schmidt
// blog post describing the method: http://chionophilous.wordpress.com/2011/10/24/accelerometer-calibration-iv-1-implementing-gauss-newton-on-an-atmega/
// original sketch available at http://rolfeschmidt.com/mathtools/skimetrics/adxl_gn_calibration.pde
2015-05-15 18:18:09 -03:00
bool _calculate_trim ( const Vector3f & accel_sample , float & trim_roll , float & trim_pitch ) ;
2012-11-05 00:27:03 -04:00
2016-09-03 21:18:09 -03:00
// save gyro calibration values to eeprom
void _save_gyro_calibration ( ) ;
2012-11-05 00:27:03 -04:00
2014-10-14 01:48:33 -03:00
// backend objects
2014-10-15 20:32:40 -03:00
AP_InertialSensor_Backend * _backends [ INS_MAX_BACKENDS ] ;
2012-11-05 00:27:03 -04:00
2014-10-14 01:48:33 -03:00
// number of gyros and accel drivers. Note that most backends
// provide both accel and gyro data, so will increment both
// counters on initialisation
uint8_t _gyro_count ;
uint8_t _accel_count ;
2014-10-16 17:27:01 -03:00
uint8_t _backend_count ;
2013-11-06 22:53:59 -04:00
2020-05-21 15:29:28 -03:00
// the selected loop rate at which samples are made available
uint16_t _loop_rate ;
2015-12-25 22:34:34 -04:00
float _loop_delta_t ;
2017-12-04 01:33:36 -04:00
float _loop_delta_t_max ;
2016-01-19 21:26:31 -04:00
2014-10-14 01:48:33 -03:00
// Most recent accelerometer reading
Vector3f _accel [ INS_MAX_INSTANCES ] ;
2015-02-17 02:54:17 -04:00
Vector3f _delta_velocity [ INS_MAX_INSTANCES ] ;
2015-03-21 17:18:58 -03:00
float _delta_velocity_dt [ INS_MAX_INSTANCES ] ;
2015-02-17 02:54:17 -04:00
bool _delta_velocity_valid [ INS_MAX_INSTANCES ] ;
2015-09-08 11:42:28 -03:00
// delta velocity accumulator
Vector3f _delta_velocity_acc [ INS_MAX_INSTANCES ] ;
// time accumulator for delta velocity accumulator
float _delta_velocity_acc_dt [ INS_MAX_INSTANCES ] ;
2014-10-14 01:48:33 -03:00
2015-11-15 20:05:20 -04:00
// Low Pass filters for gyro and accel
LowPassFilter2pVector3f _accel_filter [ INS_MAX_INSTANCES ] ;
LowPassFilter2pVector3f _gyro_filter [ INS_MAX_INSTANCES ] ;
Vector3f _accel_filtered [ INS_MAX_INSTANCES ] ;
Vector3f _gyro_filtered [ INS_MAX_INSTANCES ] ;
2020-01-03 15:52:33 -04:00
# if HAL_WITH_DSP
2019-07-23 05:43:18 -03:00
// Thread-safe public version of _last_raw_gyro
Vector3f _gyro_raw [ INS_MAX_INSTANCES ] ;
2020-03-27 19:08:30 -03:00
FloatBuffer _gyro_window [ INS_MAX_INSTANCES ] [ XYZ_AXIS_COUNT ] ;
2019-07-23 05:43:18 -03:00
uint16_t _gyro_window_size ;
2020-01-03 15:52:33 -04:00
# endif
2015-11-15 20:05:20 -04:00
bool _new_accel_data [ INS_MAX_INSTANCES ] ;
bool _new_gyro_data [ INS_MAX_INSTANCES ] ;
2016-01-19 21:26:31 -04:00
2017-08-16 02:27:58 -03:00
// optional notch filter on gyro
2019-05-17 12:57:43 -03:00
NotchFilterParams _notch_filter ;
NotchFilterVector3f _gyro_notch_filter [ INS_MAX_INSTANCES ] ;
2017-08-16 02:27:58 -03:00
2019-06-17 05:44:12 -03:00
// optional harmonic notch filter on gyro
HarmonicNotchFilterParams _harmonic_notch_filter ;
HarmonicNotchFilterVector3f _gyro_harmonic_notch_filter [ INS_MAX_INSTANCES ] ;
// the current center frequency for the notch
2020-05-29 13:28:06 -03:00
float _calculated_harmonic_notch_freq_hz [ INS_MAX_NOTCHES ] ;
uint8_t _num_calculated_harmonic_notch_frequencies ;
2019-06-17 05:44:12 -03:00
2014-10-14 01:48:33 -03:00
// Most recent gyro reading
2013-12-08 18:50:12 -04:00
Vector3f _gyro [ INS_MAX_INSTANCES ] ;
2015-02-17 02:54:17 -04:00
Vector3f _delta_angle [ INS_MAX_INSTANCES ] ;
2016-01-16 00:41:19 -04:00
float _delta_angle_dt [ INS_MAX_INSTANCES ] ;
2015-02-17 02:54:17 -04:00
bool _delta_angle_valid [ INS_MAX_INSTANCES ] ;
2016-01-16 00:41:19 -04:00
// time accumulator for delta angle accumulator
float _delta_angle_acc_dt [ INS_MAX_INSTANCES ] ;
2015-09-10 09:34:01 -03:00
Vector3f _delta_angle_acc [ INS_MAX_INSTANCES ] ;
Vector3f _last_delta_angle [ INS_MAX_INSTANCES ] ;
Vector3f _last_raw_gyro [ INS_MAX_INSTANCES ] ;
2012-11-05 00:27:03 -04:00
2018-03-18 20:28:33 -03:00
// bitmask indicating if a sensor is doing sensor-rate sampling:
uint8_t _accel_sensor_rate_sampling_enabled ;
uint8_t _gyro_sensor_rate_sampling_enabled ;
// multipliers for data supplied via sensor-rate logging:
uint16_t _accel_raw_sampling_multiplier [ INS_MAX_INSTANCES ] ;
uint16_t _gyro_raw_sampling_multiplier [ INS_MAX_INSTANCES ] ;
2016-09-03 21:51:37 -03:00
// IDs to uniquely identify each sensor: shall remain
// the same across reboots
AP_Int32 _accel_id [ INS_MAX_INSTANCES ] ;
AP_Int32 _gyro_id [ INS_MAX_INSTANCES ] ;
2012-11-05 00:27:03 -04:00
// accelerometer scaling and offsets
2014-10-14 01:48:33 -03:00
AP_Vector3f _accel_scale [ INS_MAX_INSTANCES ] ;
AP_Vector3f _accel_offset [ INS_MAX_INSTANCES ] ;
AP_Vector3f _gyro_offset [ INS_MAX_INSTANCES ] ;
2012-11-29 16:15:12 -04:00
2016-10-07 19:11:10 -03:00
// accelerometer position offset in body frame
AP_Vector3f _accel_pos [ INS_MAX_INSTANCES ] ;
2015-06-09 17:47:16 -03:00
// accelerometer max absolute offsets to be used for calibration
2015-06-29 21:51:43 -03:00
float _accel_max_abs_offsets [ INS_MAX_INSTANCES ] ;
2015-06-09 17:47:16 -03:00
2015-09-10 08:56:34 -03:00
// accelerometer and gyro raw sample rate in units of Hz
2017-04-30 21:53:41 -03:00
float _accel_raw_sample_rates [ INS_MAX_INSTANCES ] ;
float _gyro_raw_sample_rates [ INS_MAX_INSTANCES ] ;
2017-05-01 00:01:43 -03:00
// how many sensors samples per notify to the backend
uint8_t _accel_over_sampling [ INS_MAX_INSTANCES ] ;
uint8_t _gyro_over_sampling [ INS_MAX_INSTANCES ] ;
2017-04-30 21:53:41 -03:00
// last sample time in microseconds. Use for deltaT calculations
// on non-FIFO sensors
uint64_t _accel_last_sample_us [ INS_MAX_INSTANCES ] ;
uint64_t _gyro_last_sample_us [ INS_MAX_INSTANCES ] ;
// sample times for checking real sensor rate for FIFO sensors
uint16_t _sample_accel_count [ INS_MAX_INSTANCES ] ;
uint32_t _sample_accel_start_us [ INS_MAX_INSTANCES ] ;
uint16_t _sample_gyro_count [ INS_MAX_INSTANCES ] ;
uint32_t _sample_gyro_start_us [ INS_MAX_INSTANCES ] ;
2015-03-16 23:32:54 -03:00
// temperatures for an instance if available
float _temperature [ INS_MAX_INSTANCES ] ;
2012-11-29 16:15:12 -04:00
// filtering frequency (0 means default)
2019-05-25 07:59:57 -03:00
AP_Int16 _accel_filter_cutoff ;
AP_Int16 _gyro_filter_cutoff ;
2015-09-17 03:42:41 -03:00
AP_Int8 _gyro_cal_timing ;
2013-01-13 01:03:13 -04:00
2015-08-01 03:40:40 -03:00
// use for attitude, velocity, position estimates
AP_Int8 _use [ INS_MAX_INSTANCES ] ;
2016-11-15 01:51:18 -04:00
// control enable of fast sampling
AP_Int8 _fast_sampling_mask ;
2020-05-21 15:29:28 -03:00
// control enable of fast sampling
AP_Int8 _fast_sampling_rate ;
2018-01-17 03:16:48 -04:00
// control enable of detected sensors
AP_Int8 _enable_mask ;
2013-01-13 01:03:13 -04:00
// board orientation from AHRS
2014-10-14 01:48:33 -03:00
enum Rotation _board_orientation ;
2018-03-08 22:26:39 -04:00
Matrix3f * _custom_rotation ;
2014-10-08 08:17:31 -03:00
2016-11-03 06:19:04 -03:00
// per-sensor orientation to allow for board type defaults at runtime
enum Rotation _gyro_orientation [ INS_MAX_INSTANCES ] ;
enum Rotation _accel_orientation [ INS_MAX_INSTANCES ] ;
2016-09-03 21:51:37 -03:00
// calibrated_ok/id_ok flags
2014-10-14 01:48:33 -03:00
bool _gyro_cal_ok [ INS_MAX_INSTANCES ] ;
2016-09-03 21:51:37 -03:00
bool _accel_id_ok [ INS_MAX_INSTANCES ] ;
2014-10-14 01:48:33 -03:00
// primary accel and gyro
uint8_t _primary_gyro ;
uint8_t _primary_accel ;
2019-07-04 07:18:14 -03:00
// mask of accels and gyros which we will be actively using
// and this should wait for in wait_for_sample()
uint8_t _gyro_wait_mask ;
uint8_t _accel_wait_mask ;
2017-06-27 01:42:45 -03:00
// bitmask bit which indicates if we should log raw accel and gyro data
uint32_t _log_raw_bit ;
2014-10-15 20:32:40 -03:00
// has wait_for_sample() found a sample?
bool _have_sample : 1 ;
// are we in HIL mode?
bool _hil_mode : 1 ;
2015-08-05 10:01:52 -03:00
bool _backends_detected : 1 ;
2021-01-07 20:46:35 -04:00
// are gyros or accels currently being calibrated
bool _calibrating_accel ;
bool _calibrating_gyro ;
2014-10-15 20:32:40 -03:00
// the delta time in seconds for the last sample
2014-10-14 01:48:33 -03:00
float _delta_time ;
2014-10-15 05:54:30 -03:00
// last time a wait_for_sample() returned a sample
uint32_t _last_sample_usec ;
2014-10-19 20:46:02 -03:00
// target time for next wait_for_sample() return
uint32_t _next_sample_usec ;
2016-01-19 21:26:31 -04:00
2014-10-15 05:54:30 -03:00
// time between samples in microseconds
uint32_t _sample_period_usec ;
2014-10-15 23:27:22 -03:00
2017-04-28 21:26:58 -03:00
// last time update() completed
uint32_t _last_update_usec ;
2014-10-15 23:27:22 -03:00
// health of gyros and accels
bool _gyro_healthy [ INS_MAX_INSTANCES ] ;
bool _accel_healthy [ INS_MAX_INSTANCES ] ;
2014-12-29 06:19:35 -04:00
uint32_t _accel_error_count [ INS_MAX_INSTANCES ] ;
uint32_t _gyro_error_count [ INS_MAX_INSTANCES ] ;
2015-05-06 23:08:30 -03:00
2015-06-11 04:15:57 -03:00
// vibration and clipping
uint32_t _accel_clip_count [ INS_MAX_INSTANCES ] ;
2015-07-30 04:58:06 -03:00
LowPassFilterVector3f _accel_vibe_floor_filter [ INS_VIBRATION_CHECK_INSTANCES ] ;
LowPassFilterVector3f _accel_vibe_filter [ INS_VIBRATION_CHECK_INSTANCES ] ;
2015-07-29 16:34:48 -03:00
2015-12-30 23:23:04 -04:00
// peak hold detector state for primary accel
struct PeakHoldState {
float accel_peak_hold_neg_x ;
uint32_t accel_peak_hold_neg_x_age ;
} _peak_hold_state ;
2015-12-29 13:18:07 -04:00
2015-07-29 16:34:48 -03:00
// threshold for detecting stillness
AP_Float _still_threshold ;
2015-06-11 04:15:57 -03:00
2015-06-15 05:13:06 -03:00
/*
state for HIL support
*/
struct {
float delta_time ;
} _hil { } ;
2015-07-20 17:25:40 -03:00
// Trim options
AP_Int8 _acc_body_aligned ;
AP_Int8 _trim_option ;
2019-02-10 14:29:24 -04:00
static AP_InertialSensor * _singleton ;
2015-07-20 17:25:40 -03:00
AP_AccelCal * _acal ;
AccelCalibrator * _accel_calibrator ;
//save accelerometer bias and scale factors
2018-11-07 07:26:38 -04:00
void _acal_save_calibrations ( ) override ;
void _acal_event_failure ( ) override ;
2015-07-20 17:25:40 -03:00
// Returns AccelCalibrator objects pointer for specified acceleromter
2018-11-07 07:26:38 -04:00
AccelCalibrator * _acal_get_calibrator ( uint8_t i ) override { return i < get_accel_count ( ) ? & ( _accel_calibrator [ i ] ) : nullptr ; }
2015-07-20 17:25:40 -03:00
float _trim_pitch ;
float _trim_roll ;
bool _new_trim ;
2015-12-29 00:32:06 -04:00
bool _accel_cal_requires_reboot ;
2015-04-30 06:15:36 -03:00
// sensor error count at startup (used to ignore errors within 2 seconds of startup)
uint32_t _accel_startup_error_count [ INS_MAX_INSTANCES ] ;
uint32_t _gyro_startup_error_count [ INS_MAX_INSTANCES ] ;
bool _startup_error_counts_set ;
uint32_t _startup_ms ;
2019-04-18 01:24:01 -03:00
uint8_t imu_kill_mask ;
2021-01-07 20:46:35 -04:00
# if HAL_INS_TEMPERATURE_CAL_ENABLE
2021-01-08 06:50:24 -04:00
public :
// TCal class is public for use by SITL
2021-01-07 20:46:35 -04:00
class TCal {
public :
static const struct AP_Param : : GroupInfo var_info [ ] ;
void correct_accel ( float temperature , float cal_temp , Vector3f & accel ) const ;
void correct_gyro ( float temperature , float cal_temp , Vector3f & accel ) const ;
2021-01-08 06:50:24 -04:00
void sitl_apply_accel ( float temperature , Vector3f & accel ) const ;
void sitl_apply_gyro ( float temperature , Vector3f & accel ) const ;
2021-01-09 01:23:18 -04:00
void update_accel_learning ( const Vector3f & accel ) ;
void update_gyro_learning ( const Vector3f & accel ) ;
enum class Enable : uint8_t {
Disabled = 0 ,
Enabled = 1 ,
LearnCalibration = 2 ,
} ;
// add samples for learning
void update_accel_learning ( const Vector3f & gyro , float temperature ) ;
void update_gyro_learning ( const Vector3f & accel , float temperature ) ;
// class for online learning of calibration
class Learn {
public :
2021-01-09 06:33:52 -04:00
Learn ( TCal & _tcal , float _start_temp ) ;
// state for accel/gyro (accel first)
struct LearnState {
float last_temp ;
2021-01-16 23:27:51 -04:00
uint32_t last_sample_ms ;
2021-01-09 06:33:52 -04:00
Vector3f sum ;
uint32_t sum_count ;
LowPassFilter2p < float > temp_filter ;
2021-01-17 21:29:02 -04:00
// double precision is needed for good results when we
// span a wide range of temperatures
PolyFit < 4 , double , Vector3f > pfit ;
2021-01-09 06:33:52 -04:00
} state [ 2 ] ;
void add_sample ( const Vector3f & sample , float temperature , LearnState & state ) ;
2021-01-09 01:23:18 -04:00
void finish_calibration ( float temperature ) ;
2021-01-16 23:27:51 -04:00
bool save_calibration ( float temperature ) ;
2021-01-10 16:37:08 -04:00
void reset ( float temperature ) ;
2021-01-09 06:33:52 -04:00
float start_temp ;
2021-01-10 16:26:17 -04:00
float start_tmax ;
2021-01-20 00:38:24 -04:00
uint32_t last_save_ms ;
2021-01-10 16:26:17 -04:00
2021-01-09 01:23:18 -04:00
TCal & tcal ;
uint8_t instance ( void ) const {
return tcal . instance ( ) ;
}
Vector3f accel_start ;
} ;
AP_Enum < Enable > enable ;
2021-01-10 16:09:44 -04:00
2021-01-16 00:59:35 -04:00
// get persistent params for this instance
void get_persistent_params ( ExpandingString & str ) const ;
2021-01-10 16:09:44 -04:00
private :
2021-01-07 20:46:35 -04:00
AP_Float temp_max ;
2021-01-15 21:23:17 -04:00
AP_Float temp_min ;
2021-01-07 20:46:35 -04:00
AP_Vector3f accel_coeff [ 3 ] ;
AP_Vector3f gyro_coeff [ 3 ] ;
Vector3f accel_tref ;
Vector3f gyro_tref ;
2021-01-09 01:23:18 -04:00
Learn * learn ;
2021-01-07 20:46:35 -04:00
void correct_sensor ( float temperature , float cal_temp , const AP_Vector3f coeff [ 3 ] , Vector3f & v ) const ;
Vector3f polynomial_eval ( float temperature , const AP_Vector3f coeff [ 3 ] ) const ;
2021-01-09 01:23:18 -04:00
// get instance number
uint8_t instance ( void ) const ;
2021-01-07 20:46:35 -04:00
} ;
2021-01-09 01:23:18 -04:00
// instance number for logging
uint8_t tcal_instance ( const TCal & tc ) const {
return & tc - & tcal [ 0 ] ;
}
2021-01-08 06:50:24 -04:00
private :
2021-01-07 20:46:35 -04:00
TCal tcal [ INS_MAX_INSTANCES ] ;
2021-01-16 01:40:00 -04:00
enum class TCalOptions : uint8_t {
PERSIST_TEMP_CAL = ( 1U < < 0 ) ,
PERSIST_ACCEL_CAL = ( 1U < < 1 ) ,
} ;
2021-01-07 20:46:35 -04:00
// temperature that last calibration was run at
AP_Float caltemp_accel [ INS_MAX_INSTANCES ] ;
AP_Float caltemp_gyro [ INS_MAX_INSTANCES ] ;
2021-01-16 01:40:00 -04:00
AP_Int32 tcal_options ;
2021-01-15 21:23:17 -04:00
bool tcal_learning ;
2021-01-07 20:46:35 -04:00
# endif
2011-11-12 23:20:25 -04:00
} ;
2017-11-13 03:09:43 -04:00
namespace AP {
AP_InertialSensor & ins ( ) ;
} ;