forked from Archive/PX4-Autopilot
338 lines
14 KiB
C++
338 lines
14 KiB
C++
/****************************************************************************
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*
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* Copyright (c) 2015 Estimation and Control Library (ECL). All rights reserved.
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*
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* Redistribution and use in source and binary forms, with or without
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* modification, are permitted provided that the following conditions
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* are met:
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*
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* 1. Redistributions of source code must retain the above copyright
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* notice, this list of conditions and the following disclaimer.
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* 2. Redistributions in binary form must reproduce the above copyright
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* notice, this list of conditions and the following disclaimer in
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* the documentation and/or other materials provided with the
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* distribution.
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* 3. Neither the name ECL nor the names of its contributors may be
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* used to endorse or promote products derived from this software
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* without specific prior written permission.
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*
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* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
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* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
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* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
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* FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
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* COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
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* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
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* BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS
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* OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
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* AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
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* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN
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* ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
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* POSSIBILITY OF SUCH DAMAGE.
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*
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****************************************************************************/
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/**
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* @file ekf.h
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* Class for core functions for ekf attitude and position estimator.
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*
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* @author Roman Bast <bapstroman@gmail.com>
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* @author Paul Riseborough <p_riseborough@live.com.au>
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*
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*/
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#include "estimator_interface.h"
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#include "geo.h"
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class Ekf : public EstimatorInterface
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{
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public:
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Ekf();
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~Ekf();
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// initialise variables to sane values (also interface class)
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bool init(uint64_t timestamp);
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// should be called every time new data is pushed into the filter
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bool update();
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// gets the innovations of velocity and position measurements
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// 0-2 vel, 3-5 pos
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void get_vel_pos_innov(float vel_pos_innov[6]);
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// gets the innovations of the earth magnetic field measurements
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void get_mag_innov(float mag_innov[3]);
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// gets the innovations of the heading measurement
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void get_heading_innov(float *heading_innov);
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// gets the innovation variances of velocity and position measurements
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// 0-2 vel, 3-5 pos
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void get_vel_pos_innov_var(float vel_pos_innov_var[6]);
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// gets the innovation variances of the earth magnetic field measurements
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void get_mag_innov_var(float mag_innov_var[3]);
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// gets the innovations of airspeed measurement
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void get_airspeed_innov(float *airspeed_innov);
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// gets the innovation variance of the airspeed measurement
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void get_airspeed_innov_var(float *airspeed_innov_var);
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// gets the innovation variance of the heading measurement
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void get_heading_innov_var(float *heading_innov_var);
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// gets the innovation variance of the flow measurement
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void get_flow_innov_var(float flow_innov_var[2]);
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// gets the innovation of the flow measurement
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void get_flow_innov(float flow_innov[2]);
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// gets the innovation variance of the HAGL measurement
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void get_hagl_innov_var(float *hagl_innov_var);
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// gets the innovation of the HAGL measurement
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void get_hagl_innov(float *hagl_innov);
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// get the state vector at the delayed time horizon
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void get_state_delayed(float *state);
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// get the diagonal elements of the covariance matrix
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void get_covariances(float *covariances);
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// ask estimator for sensor data collection decision and do any preprocessing if required, returns true if not defined
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bool collect_gps(uint64_t time_usec, struct gps_message *gps);
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bool collect_imu(imuSample &imu);
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// get the ekf WGS-84 origin position and height and the system time it was last set
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void get_ekf_origin(uint64_t *origin_time, map_projection_reference_s *origin_pos, float *origin_alt);
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// get the 1-sigma horizontal and vertical position uncertainty of the ekf WGS-84 position
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void get_ekf_accuracy(float *ekf_eph, float *ekf_epv, bool *dead_reckoning);
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void get_vel_var(Vector3f &vel_var);
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void get_pos_var(Vector3f &pos_var);
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// return true if the global position estimate is valid
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bool global_position_is_valid();
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// return true if the etimate is valid
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// return the estimated terrain vertical position relative to the NED origin
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bool get_terrain_vert_pos(float *ret);
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void get_accel_bias(float *bias) {*bias = _state.accel_z_bias;}
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private:
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static const uint8_t _k_num_states = 24;
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const float _k_earth_rate = 0.000072921f;
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const float _gravity_mss = 9.80665f;
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stateSample _state; // state struct of the ekf running at the delayed time horizon
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bool _filter_initialised; // true when the EKF sttes and covariances been initialised
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bool _earth_rate_initialised; // true when we know the earth rotatin rate (requires GPS)
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bool _fuse_height; // baro height data should be fused
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bool _fuse_pos; // gps position data should be fused
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bool _fuse_hor_vel; // gps horizontal velocity measurement should be fused
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bool _fuse_vert_vel; // gps vertical velocity measurement should be fused
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bool _fuse_flow; // flow measurement should be fused
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bool _fuse_hagl_data; // if true then range data will be fused to estimate terrain height
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uint64_t _time_last_fake_gps; // last time in us at which we have faked gps measurement for static mode
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uint64_t _time_last_pos_fuse; // time the last fusion of horizontal position measurements was performed (usec)
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uint64_t _time_last_vel_fuse; // time the last fusion of velocity measurements was performed (usec)
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uint64_t _time_last_hgt_fuse; // time the last fusion of height measurements was performed (usec)
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uint64_t _time_last_of_fuse; // time the last fusion of optical flow measurements were performed (usec)
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Vector2f _last_known_posNE; // last known local NE position vector (m)
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float _last_disarmed_posD; // vertical position recorded at arming (m)
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Vector3f _earth_rate_NED; // earth rotation vector (NED) in rad/s
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matrix::Dcm<float> _R_to_earth; // transformation matrix from body frame to earth frame from last EKF predition
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float P[_k_num_states][_k_num_states]; // state covariance matrix
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float KH[_k_num_states][_k_num_states]; // intermediate variable for the covariance update
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float KHP[_k_num_states][_k_num_states]; // intermediate variable for the covariance update
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float _vel_pos_innov[6]; // innovations: 0-2 vel, 3-5 pos
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float _vel_pos_innov_var[6]; // innovation variances: 0-2 vel, 3-5 pos
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float _mag_innov[3]; // earth magnetic field innovations
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float _mag_innov_var[3]; // earth magnetic field innovation variance
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float _airspeed_innov; // airspeed measurement innovation
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float _airspeed_innov_var; // airspeed measurement innovation variance
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float _heading_innov; // heading measurement innovation
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float _heading_innov_var; // heading measurement innovation variance
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Vector3f _tilt_err_vec; // Vector of the most recent attitude error correction from velocity and position fusion
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float _tilt_err_length_filt; // filtered length of _tilt_err_vec
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// optical flow processing
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float _flow_innov[2]; // flow measurement innovation
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float _flow_innov_var[2]; // flow innovation variance
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Vector3f _flow_gyro_bias; // bias errors in optical flow sensor rate gyro outputs
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Vector3f _imu_del_ang_of; // bias corrected delta angle measurements accumulated across the same time frame as the optical flow rates
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float _delta_time_of; // time in sec that _imu_del_ang_of was accumulated over
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float _mag_declination; // magnetic declination used by reset and fusion functions (rad)
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// complementary filter states
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Vector3f _delta_angle_corr; // delta angle correction vector
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Vector3f _delta_vel_corr; // delta velocity correction vector
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Vector3f _vel_corr; // velocity correction vector
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imuSample _imu_down_sampled; // down sampled imu data (sensor rate -> filter update rate)
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Quaternion _q_down_sampled; // down sampled quaternion (tracking delta angles between ekf update steps)
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// variables used for the GPS quality checks
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float _gpsDriftVelN; // GPS north position derivative (m/s)
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float _gpsDriftVelE; // GPS east position derivative (m/s)
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float _gps_drift_velD; // GPS down position derivative (m/s)
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float _gps_velD_diff_filt; // GPS filtered Down velocity (m/s)
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float _gps_velN_filt; // GPS filtered North velocity (m/s)
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float _gps_velE_filt; // GPS filtered East velocity (m/s)
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uint64_t _last_gps_fail_us; // last system time in usec that the GPS failed it's checks
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// Variables used to publish the WGS-84 location of the EKF local NED origin
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uint64_t _last_gps_origin_time_us; // time the origin was last set (uSec)
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float _gps_alt_ref; // WGS-84 height (m)
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// Variables used to initialise the filter states
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uint32_t _hgt_counter; // number of height samples taken
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float _hgt_filt_state; // filtered height measurement
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uint32_t _mag_counter; // number of magnetometer samples taken
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uint64_t _time_last_mag; // measurement time of last magnetomter sample
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Vector3f _mag_filt_state; // filtered magnetometer measurement
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Vector3f _delVel_sum; // summed delta velocity
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float _hgt_sensor_offset; // height that needs to be subtracted from the primary height sensor so that it reads zero height at the origin (m)
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gps_check_fail_status_u _gps_check_fail_status;
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// Terrain height state estimation
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float _terrain_vpos; // estimated vertical position of the terrain underneath the vehicle in local NED frame (m)
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float _terrain_var; // variance of terrain position estimate (m^2)
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float _hagl_innov; // innovation of the last height above terrain measurement (m)
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float _hagl_innov_var; // innovation variance for the last height above terrain measurement (m^2)
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uint64_t _time_last_hagl_fuse; // last system time in usec that the hagl measurement failed it's checks
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bool _terrain_initialised; // true when the terrain estimator has been intialised
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// height sensor fault status
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bool _baro_hgt_faulty; // true if valid baro data is unavailable for use
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bool _gps_hgt_faulty; // true if valid gps height data is unavailable for use
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bool _rng_hgt_faulty; // true if valid rnage finder height data is unavailable for use
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int _primary_hgt_source; // priary source of height data set at initialisation
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float _baro_hgt_offset; // number of metres the baro height origin is above the local NED origin (m)
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// update the real time complementary filter states. This includes the prediction
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// and the correction step
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void calculateOutputStates();
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// initialise filter states of both the delayed ekf and the real time complementary filter
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bool initialiseFilter(void);
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// initialise ekf covariance matrix
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void initialiseCovariance();
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// predict ekf state
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void predictState();
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// predict ekf covariance
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void predictCovariance();
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// ekf sequential fusion of magnetometer measurements
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void fuseMag();
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// fuse the first euler angle from either a 321 or 312 rotation sequence as the observation (currently measures yaw using the magnetometer)
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void fuseHeading();
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// fuse projecton of magnetometer onto horizontal plane
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void fuseMag2D();
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// fuse magnetometer declination measurement
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void fuseDeclination();
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// fuse airspeed measurement
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void fuseAirspeed();
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// fuse velocity and position measurements (also barometer height)
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void fuseVelPosHeight();
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// reset velocity states of the ekf
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bool resetVelocity();
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// fuse optical flow line of sight rate measurements
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void fuseOptFlow();
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// calculate optical flow bias errors
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void calcOptFlowBias();
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// initialise the terrain vertical position estimator
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// return true if the initialisation is successful
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bool initHagl();
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// predict the terrain vertical position state and variance
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void predictHagl();
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// update the terrain vertical position estimate using a height above ground measurement from the range finder
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void fuseHagl();
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// reset the heading and magnetic field states using the declination and magnetometer measurements
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// return true if successful
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bool resetMagHeading(Vector3f &mag_init);
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// calculate the magnetic declination to be used by the alignment and fusion processing
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void calcMagDeclination();
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// reset position states of the ekf (only vertical position)
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bool resetPosition();
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// reset height state of the ekf
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void resetHeight();
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void makeCovSymetrical();
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// limit the diagonal of the covariance matrix
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void limitCov();
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// make ekf covariance matrix symmetric
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void makeSymmetrical();
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// constrain the ekf states
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void constrainStates();
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// generic function which will perform a fusion step given a kalman gain K
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// and a scalar innovation value
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void fuse(float *K, float innovation);
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// calculate the earth rotation vector from a given latitude
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void calcEarthRateNED(Vector3f &omega, double lat_rad) const;
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// return true id the GPS quality is good enough to set an origin and start aiding
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bool gps_is_good(struct gps_message *gps);
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// Control the filter fusion modes
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void controlFusionModes();
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// Determine if we are airborne or motors are armed
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void calculateVehicleStatus();
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// return the square of two floating point numbers - used in auto coded sections
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inline float sq(float var)
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{
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return var * var;
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}
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// zero the specified range of rows in the state covariance matrix
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void zeroRows(float (&cov_mat)[_k_num_states][_k_num_states], uint8_t first, uint8_t last);
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// zero the specified range of columns in the state covariance matrix
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void zeroCols(float (&cov_mat)[_k_num_states][_k_num_states], uint8_t first, uint8_t last);
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};
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