ardupilot/libraries/AP_Quaternion/AP_Quaternion.h

#ifndef AP_Quaternion_h
#define AP_Quaternion_h

#include <AP_Math.h>
#include <inttypes.h>
#include <AP_Compass.h>
#include <AP_GPS.h>
#include <AP_IMU.h>

#if defined(ARDUINO) && ARDUINO >= 100
	#include "Arduino.h"
#else
	#include "WProgram.h"
#endif

class AP_Quaternion
{
public:
	// Constructor
	AP_Quaternion(IMU *imu, GPS *&gps, Compass *compass = NULL) :
		_imu(imu),
		_gps(gps),
		_compass(compass)
	{
		// initial quaternion
		SEq_1 = 1;
		SEq_2 = 0;
		SEq_3 = 0;
		SEq_4 = 0;

		// reference direction of flux in earth frame
		b_x = 0;
		b_z = -1;

		// scaled gyro drift limits
		beta = sqrt(3.0f / 4.0f) * gyroMeasError;
		zeta = sqrt(3.0f / 4.0f) * gyroMeasDrift;
	}

	// Accessors
	void		set_centripetal(bool b) {_centripetal = b;}
	bool		get_centripetal(void) {return _centripetal;}
	void		set_compass(Compass *compass);

	// Methods
	void 		update(void);

	// Euler angles (radians)
	float		roll;
	float		pitch;
	float		yaw;

	// integer Euler angles (Degrees * 100)
	int32_t		roll_sensor;
	int32_t		pitch_sensor;
	int32_t		yaw_sensor;


	// compatibility methods with DCM
	void update_DCM(void) { update(); }
	void update_DCM_fast(void) { update(); }
	Vector3f get_gyro(void) {
		// notice the sign reversals here
		return Vector3f(-_gyro_corrected.x, -_gyro_corrected.y, _gyro_corrected.z);
	}
	Vector3f get_integrator(void) {
		// notice the sign reversals here
		return Vector3f(-gyro_bias.x, -gyro_bias.y, gyro_bias.z);
        }
	float get_accel_weight(void) { return 0; }
	float get_renorm_val(void) { return 0; }
	float get_health(void) { return 0; }
	void matrix_reset(void) { }
	uint8_t gyro_sat_count;
	uint8_t renorm_range_count;
	uint8_t renorm_blowup_count;
	float get_error_rp(void);
	float get_error_yaw(void);

private:
	void 		update_IMU(float deltat, Vector3f &gyro, Vector3f &accel);
	void 		update_MARG(float deltat, Vector3f &gyro, Vector3f &accel, Vector3f &mag);

	bool		_have_initial_yaw;

	// Methods
	void 		accel_adjust(void);

	// members
	Compass 	* _compass;

	// note: we use ref-to-pointer here so that our caller can change the GPS without our noticing
	//       IMU under us without our noticing.
	GPS 		*&_gps;
	IMU 		*_imu;

	// true if we are doing centripetal acceleration correction
	bool		_centripetal;

	// maximum gyroscope measurement error in rad/s (set to 10 degrees/second)
	static const float gyroMeasError = 10.0 * (M_PI/180.0);

	// maximum gyroscope drift rate in radians/s/s (set to 0.02
	// degrees/s/s, which is 1.2 degrees/s/minute)
	static const float gyroMeasDrift = 0.02 * (PI/180.0);

	float beta;
	float zeta;

	// quaternion elements
	float SEq_1, SEq_2, SEq_3, SEq_4;

	float b_x;
	float b_z;

	// estimate gyroscope biases error
	Vector3f gyro_bias;

	// the current corrected gyro vector
	Vector3f _gyro_corrected;

	// estimate of error
	float		_error_rp_sum;
	uint16_t	_error_rp_count;
	float		_error_yaw_sum;
	uint16_t	_error_yaw_count;
};

#endif
Quaternion: added an AP_Quaternion library this is for experimenting with the Madgwick quaternion system, to see if it is more or less noise sensitive than DCM 2012-03-03 00:49:38 -04:00			`#ifndef AP_Quaternion_h`
			`#define AP_Quaternion_h`

			`#include <AP_Math.h>`
			`#include <inttypes.h>`
			`#include <AP_Compass.h>`
			`#include <AP_GPS.h>`
			`#include <AP_IMU.h>`

			`#if defined(ARDUINO) && ARDUINO >= 100`
			`#include "Arduino.h"`
			`#else`
			`#include "WProgram.h"`
			`#endif`

			`class AP_Quaternion`
			`{`
			`public:`
			`// Constructor`
			`AP_Quaternion(IMU imu, GPS &gps, Compass *compass = NULL) :`
			`_imu(imu),`
			`_gps(gps),`
			`_compass(compass)`
			`{`
			`// initial quaternion`
			`SEq_1 = 1;`
			`SEq_2 = 0;`
			`SEq_3 = 0;`
			`SEq_4 = 0;`

			`// reference direction of flux in earth frame`
			`b_x = 0;`
			`b_z = -1;`

			`// scaled gyro drift limits`
			`beta = sqrt(3.0f / 4.0f) * gyroMeasError;`
			`zeta = sqrt(3.0f / 4.0f) * gyroMeasDrift;`
			`}`

			`// Accessors`
			`void set_centripetal(bool b) {_centripetal = b;}`
			`bool get_centripetal(void) {return _centripetal;}`
			`void set_compass(Compass *compass);`

			`// Methods`
fixed deltat in quaternion 2012-03-03 01:00:57 -04:00			`void update(void);`
Quaternion: added an AP_Quaternion library this is for experimenting with the Madgwick quaternion system, to see if it is more or less noise sensitive than DCM 2012-03-03 00:49:38 -04:00
			`// Euler angles (radians)`
			`float roll;`
			`float pitch;`
			`float yaw;`

			`// integer Euler angles (Degrees * 100)`
			`int32_t roll_sensor;`
			`int32_t pitch_sensor;`
			`int32_t yaw_sensor;`


AP_Quaternion: added DCM compatibility interfaces useful for getting the code going quickly 2012-03-03 03:32:50 -04:00			`// compatibility methods with DCM`
			`void update_DCM(void) { update(); }`
			`void update_DCM_fast(void) { update(); }`
Quaternion: fix the gyro bias in centripetal and remove smoothing the centripetal code needs to take account of the current gyro bias. It turned out that the accel and gyro smoothing was causing significant control lag, and we're better off just letting the quaternion code handle it via its own smoothing parameters 2012-03-04 20:27:45 -04:00			`Vector3f get_gyro(void) {`
			`// notice the sign reversals here`
			`return Vector3f(-_gyro_corrected.x, -_gyro_corrected.y, _gyro_corrected.z);`
			`}`
			`Vector3f get_integrator(void) {`
			`// notice the sign reversals here`
			`return Vector3f(-gyro_bias.x, -gyro_bias.y, gyro_bias.z);`
			`}`
AP_Quaternion: added DCM compatibility interfaces useful for getting the code going quickly 2012-03-03 03:32:50 -04:00			`float get_accel_weight(void) { return 0; }`
			`float get_renorm_val(void) { return 0; }`
			`float get_health(void) { return 0; }`
			`void matrix_reset(void) { }`
			`uint8_t gyro_sat_count;`
			`uint8_t renorm_range_count;`
			`uint8_t renorm_blowup_count;`
Quaternion: added in reporting of gyro drift and rp/yaw errors 2012-03-03 08:32:31 -04:00			`float get_error_rp(void);`
			`float get_error_yaw(void);`
AP_Quaternion: added DCM compatibility interfaces useful for getting the code going quickly 2012-03-03 03:32:50 -04:00
Quaternion: added an AP_Quaternion library this is for experimenting with the Madgwick quaternion system, to see if it is more or less noise sensitive than DCM 2012-03-03 00:49:38 -04:00			`private:`
			`void update_IMU(float deltat, Vector3f &gyro, Vector3f &accel);`
			`void update_MARG(float deltat, Vector3f &gyro, Vector3f &accel, Vector3f &mag);`

			`bool _have_initial_yaw;`

			`// Methods`
			`void accel_adjust(void);`

			`// members`
			`Compass * _compass;`

			`// note: we use ref-to-pointer here so that our caller can change the GPS without our noticing`
			`// IMU under us without our noticing.`
			`GPS *&_gps;`
			`IMU *_imu;`

			`// true if we are doing centripetal acceleration correction`
			`bool _centripetal;`

Quaternion: fix the gyro bias in centripetal and remove smoothing the centripetal code needs to take account of the current gyro bias. It turned out that the accel and gyro smoothing was causing significant control lag, and we're better off just letting the quaternion code handle it via its own smoothing parameters 2012-03-04 20:27:45 -04:00			`// maximum gyroscope measurement error in rad/s (set to 10 degrees/second)`
			`static const float gyroMeasError = 10.0 * (M_PI/180.0);`
Quaternion: added an AP_Quaternion library this is for experimenting with the Madgwick quaternion system, to see if it is more or less noise sensitive than DCM 2012-03-03 00:49:38 -04:00
Quaternion: fix the gyro bias in centripetal and remove smoothing the centripetal code needs to take account of the current gyro bias. It turned out that the accel and gyro smoothing was causing significant control lag, and we're better off just letting the quaternion code handle it via its own smoothing parameters 2012-03-04 20:27:45 -04:00			`// maximum gyroscope drift rate in radians/s/s (set to 0.02`
			`// degrees/s/s, which is 1.2 degrees/s/minute)`
Quaternion: tweak the quaternion gains a bit 2012-03-03 07:19:30 -04:00			`static const float gyroMeasDrift = 0.02 * (PI/180.0);`
Quaternion: added an AP_Quaternion library this is for experimenting with the Madgwick quaternion system, to see if it is more or less noise sensitive than DCM 2012-03-03 00:49:38 -04:00
			`float beta;`
			`float zeta;`

			`// quaternion elements`
			`float SEq_1, SEq_2, SEq_3, SEq_4;`

			`float b_x;`
			`float b_z;`

			`// estimate gyroscope biases error`
			`Vector3f gyro_bias;`
AP_Quaternion: added DCM compatibility interfaces useful for getting the code going quickly 2012-03-03 03:32:50 -04:00
Quaternion: fix the gyro bias in centripetal and remove smoothing the centripetal code needs to take account of the current gyro bias. It turned out that the accel and gyro smoothing was causing significant control lag, and we're better off just letting the quaternion code handle it via its own smoothing parameters 2012-03-04 20:27:45 -04:00			`// the current corrected gyro vector`
			`Vector3f _gyro_corrected;`
Quaternion: added in reporting of gyro drift and rp/yaw errors 2012-03-03 08:32:31 -04:00
			`// estimate of error`
			`float _error_rp_sum;`
			`uint16_t _error_rp_count;`
			`float _error_yaw_sum;`
			`uint16_t _error_yaw_count;`
Quaternion: added an AP_Quaternion library this is for experimenting with the Madgwick quaternion system, to see if it is more or less noise sensitive than DCM 2012-03-03 00:49:38 -04:00			`};`

			`#endif`