px4-firmware/EKF/estimator_base.h

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/**
 * @file estimator_base.h
 * Definition of base class for attitude estimators
 *
 * @author Roman Bast <bapstroman@gmail.com>
 *
 */

#include <stdint.h>
#include <matrix/matrix/math.hpp>
#include <lib/geo/geo.h>
#include "RingBuffer.h"

struct gps_message {
	uint64_t time_usec;
	int32_t lat;			// Latitude in 1E-7 degrees
	int32_t lon;			// Longitude in 1E-7 degrees
	int32_t alt;			// Altitude in 1E-3 meters (millimeters) above MSL
	uint8_t fix_type;		// 0-1: no fix, 2: 2D fix, 3: 3D fix, 4: RTCM code differential, 5: Real-Time
	float eph;			// GPS HDOP horizontal dilution of position in m
	float epv;			// GPS VDOP horizontal dilution of position in m
	uint64_t time_usec_vel;	// Timestamp for velocity informations
	float vel_m_s;			// GPS ground speed (m/s)
	float vel_ned[3];		// GPS ground speed NED
	bool vel_ned_valid;		// GPS ground speed is valid
};

class EstimatorBase
{
public:
	EstimatorBase();
	~EstimatorBase();

	virtual bool update() = 0;

	// set delta angle imu data
	void setIMUData(uint64_t time_usec, uint64_t delta_ang_dt, uint64_t delta_vel_dt, float *delta_ang, float *delta_vel);

	// set magnetometer data
	void setMagData(uint64_t time_usec, float *data);

	// set gps data
	void setGpsData(uint64_t time_usec, struct gps_message *gps);

	// set baro data
	void setBaroData(uint64_t time_usec, float *data);

	// set airspeed data
	void setAirspeedData(uint64_t time_usec, float *data);

	// set range data
	void setRangeData(uint64_t time_usec, float *data);

	// set optical flow data
	void setOpticalFlowData(uint64_t time_usec, float *data);

protected:

	typedef matrix::Vector<float, 2> Vector2f;
	typedef matrix::Vector<float, 3> Vector3f;
	typedef matrix::Quaternion<float> Quaternion;
	typedef matrix::Matrix<float, 3, 3> Matrix3f;

	struct stateSample {
		Vector3f    ang_error;
		Vector3f    vel;
		Vector3f    pos;
		Vector3f    gyro_bias;
		Vector3f    gyro_scale;
		float       accel_z_bias;
		Vector3f    mag_I;
		Vector3f    mag_B;
		Vector2f    wind_vel;
		Quaternion  quat_nominal;
	} _state;

	struct outputSample {
		Quaternion  quat_nominal;
		Vector3f    vel;
		Vector3f    pos;
		uint64_t 	time_us;
	};

	struct imuSample {
		Vector3f    delta_ang;
		Vector3f    delta_vel;
		float       delta_ang_dt;
		float       delta_vel_dt;
		uint64_t    time_us;
	};

	struct gpsSample {
		Vector2f    pos;
		float       hgt;
		Vector3f    vel;
		uint64_t    time_us;
	};

	struct magSample {
		Vector3f    mag;
		uint64_t    time_us;
	};

	struct baroSample {
		float       hgt;
		uint64_t    time_us;
	};

	struct rangeSample {
		float       rng;
		uint64_t    time_us;
	};

	struct airspeedSample {
		float       airspeed;
		uint64_t    time_us;
	};

	struct flowSample {
		Vector2f    flowRadXY;
		Vector2f    flowRadXYcomp;
		uint64_t    time_us;
	};

	struct {
		uint32_t mag_delay_ms;
		uint32_t baro_delay_ms;
		uint32_t gps_delay_ms;
		uint32_t airspeed_delay_ms;
		float 	requiredEph;
		float 	requiredEpv;

		float gyro_noise;
		float accel_noise;

		// process noise
		float gyro_bias_p_noise;
		float accel_bias_p_noise;
		float gyro_scale_p_noise;
		float mag_p_noise;
		float wind_vel_p_noise;

		float gps_vel_noise;
		float gps_pos_noise;
		float baro_noise;

		float mag_heading_noise;	// measurement noise used for simple heading fusion
		float mag_declination_deg;	// magnetic declination in degrees
		float heading_innov_gate;	// innovation gate for heading innovation test

	} _params;

	static const uint8_t OBS_BUFFER_LENGTH = 10;
	static const uint8_t IMU_BUFFER_LENGTH = 30;
	static const unsigned FILTER_UPDATE_PERRIOD_MS = 10;

	float _dt_imu_avg;
	uint64_t _imu_time_last;

	imuSample _imu_sample_delayed;
	imuSample _imu_down_sampled;
	Quaternion
	_q_down_sampled;

	magSample _mag_sample_delayed;
	baroSample _baro_sample_delayed;
	gpsSample _gps_sample_delayed;
	rangeSample _range_sample_delayed;
	airspeedSample _airspeed_sample_delayed;
	flowSample _flow_sample_delayed;

	outputSample _output_sample_delayed;
	outputSample _output_new;
	imuSample _imu_sample_new;

	struct map_projection_reference_s _posRef;
	float _gps_alt_ref;


	uint64_t _imu_ticks;

	bool _imu_updated = false;
	bool _start_predict_enabled = false;
	bool _initialised = false;
	bool _gps_initialised = false;
	bool _gps_speed_valid = false;

	bool _mag_healthy = false;		// computed by mag innovation test

	bool _in_air = true;			// indicates if the vehicle is in the air

	RingBuffer<imuSample> _imu_buffer;
	RingBuffer<gpsSample> _gps_buffer;
	RingBuffer<magSample> _mag_buffer;
	RingBuffer<baroSample> _baro_buffer;
	RingBuffer<rangeSample> _range_buffer;
	RingBuffer<airspeedSample> _airspeed_buffer;
	RingBuffer<flowSample> 	_flow_buffer;
	RingBuffer<outputSample> _output_buffer;

	uint64_t _time_last_imu;
	uint64_t _time_last_gps;
	uint64_t _time_last_mag;
	uint64_t _time_last_baro;
	uint64_t _time_last_range;
	uint64_t _time_last_airspeed;

	// flags capturing information about severe nummerical problems for various fusions
	struct {
		bool bad_mag_x:1;
		bool bad_mag_y:1;
		bool bad_mag_z:1;
		bool bad_airspeed:1;
		bool bad_sideslip:1;
	} _fault_status;


	void initialiseVariables(uint64_t timestamp);

	void initialiseGPS(struct gps_message *gps);

	bool gps_is_good(struct gps_message *gps);

public:
	void printIMU(struct imuSample *data);
	void printStoredIMU();
	void printQuaternion(Quaternion &q);
	void print_imu_avg_time();
	void printMag(struct magSample *data);
	void printStoredMag();
	void printBaro(struct baroSample *data);
	void printStoredBaro();
	void printGps(struct gpsSample *data);
	void printStoredGps();

	void copy_quaternion(float *quat) {
		for (unsigned i = 0; i < 4; i++) {
			quat[i] = _output_new.quat_nominal(i);
		}
	}
	void copy_velocity(float *vel) {
		for (unsigned i = 0; i < 3; i++) {
			vel[i] = _output_new.vel(i);
		}
	}
	void copy_position(float *pos) {
		for (unsigned i = 0; i < 3; i++) {
			pos[i] = _output_new.pos(i);
		}
	}
	void copy_timestamp(uint64_t *time_us) {
		*time_us = _imu_time_last;
	}
};