mirror of https://github.com/ArduPilot/ardupilot
262 lines
9.3 KiB
C++
262 lines
9.3 KiB
C++
#pragma once
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#include "AP_Compass_config.h"
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#if COMPASS_CAL_ENABLED
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#include <AP_Math/AP_Math.h>
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#define COMPASS_CAL_NUM_SPHERE_PARAMS 4
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#define COMPASS_CAL_NUM_ELLIPSOID_PARAMS 9
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#define COMPASS_CAL_NUM_SAMPLES 300 // number of samples required before fitting begins
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class CompassCalibrator {
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public:
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CompassCalibrator();
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// start or stop the calibration
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void start(bool retry, float delay, uint16_t offset_max, uint8_t compass_idx, float tolerance);
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void stop();
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// Update point sample
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void new_sample(const Vector3f& sample);
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// set compass's initial orientation and whether it should be automatically fixed (if required)
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void set_orientation(enum Rotation orientation, bool is_external, bool fix_orientation, bool always_45_deg);
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// running is true if actively calculating offsets, diagonals or offdiagonals
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bool running();
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// failed is true if either of the failure states are hit
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bool failed();
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// update the state machine and calculate offsets, diagonals and offdiagonals
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void update();
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// compass calibration states - these correspond to the mavlink
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// MAG_CAL_STATUS enumeration
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enum class Status {
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NOT_STARTED = 0,
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WAITING_TO_START = 1,
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RUNNING_STEP_ONE = 2,
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RUNNING_STEP_TWO = 3,
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SUCCESS = 4,
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FAILED = 5,
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BAD_ORIENTATION = 6,
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BAD_RADIUS = 7,
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};
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// get completion mask for mavlink reporting (a bitmask of faces/directions for which we have compass samples)
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typedef uint8_t completion_mask_t[10];
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// Structure accessed for cal status update via mavlink
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struct State {
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Status status;
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uint8_t attempt;
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float completion_pct;
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completion_mask_t completion_mask;
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} cal_state;
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// Structure accessed after calibration is finished/failed
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struct Report {
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Status status;
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float fitness;
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Vector3f ofs;
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Vector3f diag;
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Vector3f offdiag;
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float orientation_confidence;
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Rotation original_orientation;
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Rotation orientation;
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float scale_factor;
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bool check_orientation;
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} cal_report;
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// Structure setup to set calibration run settings
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struct Settings {
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float tolerance;
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bool check_orientation;
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enum Rotation orientation;
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enum Rotation orig_orientation;
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bool is_external;
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bool fix_orientation;
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uint16_t offset_max;
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uint8_t attempt;
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bool retry;
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float delay_start_sec;
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uint32_t start_time_ms;
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uint8_t compass_idx;
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bool always_45_deg;
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} cal_settings;
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// Get calibration result
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const Report get_report();
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// Get current Calibration state
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const State get_state();
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protected:
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// convert index to rotation, this allows to skip some rotations
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// protected so CompassCalibrator_index_test can see it
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Rotation auto_rotation_index(uint8_t n) const;
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// return true if this is a right angle rotation
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bool right_angle_rotation(Rotation r) const;
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private:
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// results
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class param_t {
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public:
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float* get_sphere_params() {
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return &radius;
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}
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float* get_ellipsoid_params() {
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return &offset.x;
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}
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float radius; // magnetic field strength calculated from samples
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Vector3f offset; // offsets
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Vector3f diag; // diagonal scaling
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Vector3f offdiag; // off diagonal scaling
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float scale_factor; // scaling factor to compensate for radius error
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};
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// compact class for approximate attitude, to save memory
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class AttitudeSample {
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public:
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Matrix3f get_rotmat() const;
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void set_from_ahrs();
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private:
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int8_t roll;
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int8_t pitch;
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int8_t yaw;
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};
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// compact class to hold compass samples, to save memory
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class CompassSample {
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public:
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Vector3f get() const;
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void set(const Vector3f &in);
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AttitudeSample att;
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private:
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int16_t x;
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int16_t y;
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int16_t z;
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};
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// set status including any required initialisation
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bool set_status(Status status);
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// consume point raw sample from intermediate structure
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void pull_sample();
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// returns true if sample should be added to buffer
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bool accept_sample(const Vector3f &sample, uint16_t skip_index = UINT16_MAX);
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bool accept_sample(const CompassSample &sample, uint16_t skip_index = UINT16_MAX);
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// returns true if fit is acceptable
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bool fit_acceptable() const;
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// clear sample buffer and reset offsets and scaling to their defaults
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void reset_state();
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// initialize fitness before starting a fit
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void initialize_fit();
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// true if enough samples have been collected and fitting has begun (aka runniong())
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bool _fitting() const;
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// thins out samples between step one and step two
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void thin_samples();
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// calc the fitness of a single sample vs a set of parameters (offsets, diagonals, off diagonals)
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float calc_residual(const Vector3f& sample, const param_t& params) const;
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// calc the fitness of the parameters (offsets, diagonals, off diagonals) vs all the samples collected
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// returns 1.0e30f if the sample buffer is empty
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float calc_mean_squared_residuals(const param_t& params) const;
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// calculate initial offsets by simply taking the average values of the samples
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void calc_initial_offset();
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// run sphere fit to calculate diagonals and offdiagonals
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void calc_sphere_jacob(const Vector3f& sample, const param_t& params, float* ret) const;
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void run_sphere_fit();
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// run ellipsoid fit to calculate diagonals and offdiagonals
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void calc_ellipsoid_jacob(const Vector3f& sample, const param_t& params, float* ret) const;
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void run_ellipsoid_fit();
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// update the completion mask based on a single sample
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void update_completion_mask(const Vector3f& sample);
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// reset and updated the completion mask using all samples in the sample buffer
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void update_completion_mask();
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// calculate compass orientation
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Vector3f calculate_earth_field(CompassSample &sample, enum Rotation r);
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bool calculate_orientation();
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// fix radius to compensate for sensor scaling errors
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bool fix_radius();
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// update methods to read write intermediate structures, called inside thread
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inline void update_cal_status();
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inline void update_cal_report();
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inline void update_cal_settings();
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// running method for use in thread
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bool _running() const;
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uint8_t _compass_idx; // index of the compass providing data
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Status _status; // current state of calibrator
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// values provided by caller
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float _delay_start_sec; // seconds to delay start of calibration (provided by caller)
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bool _retry; // true if calibration should be restarted on failured (provided by caller)
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float _tolerance = 5.0; // worst acceptable RMS tolerance (aka fitness). see set_tolerance()
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uint16_t _offset_max; // maximum acceptable offsets (provided by caller)
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// behavioral state
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uint32_t _start_time_ms; // system time start() function was last called
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uint8_t _attempt; // number of attempts have been made to calibrate
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completion_mask_t _completion_mask; // bitmask of directions in which we have samples
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CompassSample *_sample_buffer; // buffer of sensor values
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uint16_t _samples_collected; // number of samples in buffer
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uint16_t _samples_thinned; // number of samples removed by the thin_samples() call (called before step 2 begins)
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// fit state
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class param_t _params; // latest calibration outputs
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uint16_t _fit_step; // step during RUNNING_STEP_ONE/TWO which performs sphere fit and ellipsoid fit
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float _fitness; // fitness (mean squared residuals) of current parameters
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float _initial_fitness; // fitness before latest "fit" was attempted (used to determine if fit was an improvement)
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float _sphere_lambda; // sphere fit's lambda
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float _ellipsoid_lambda; // ellipsoid fit's lambda
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// variables for orientation checking
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enum Rotation _orientation; // latest detected orientation
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enum Rotation _orig_orientation; // original orientation provided by caller
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enum Rotation _orientation_solution; // latest solution
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bool _is_external; // true if compass is external (provided by caller)
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bool _check_orientation; // true if orientation should be automatically checked
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bool _fix_orientation; // true if orientation should be fixed if necessary
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bool _always_45_deg; // true if orientation should consider 45deg with equal tolerance
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float _orientation_confidence; // measure of confidence in automatic orientation detection
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CompassSample _last_sample;
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Status _requested_status;
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bool _status_set_requested;
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bool _new_sample;
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// Semaphore for state related intermediate structures
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HAL_Semaphore state_sem;
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// Semaphore for intermediate structure for point sample collection
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HAL_Semaphore sample_sem;
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};
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#endif // COMPASS_CAL_ENABLED
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