px4-firmware/EKF/terrain_estimator.cpp

206 lines
7.0 KiB
C++

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/**
* @file terrain_estimator.cpp
* Function for fusing rangefinder measurements to estimate terrain vertical position/
*
* @author Paul Riseborough <p_riseborough@live.com.au>
*
*/
#include "ekf.h"
#include "mathlib.h"
bool Ekf::initHagl()
{
// get most recent range measurement from buffer
rangeSample latest_measurement = _range_buffer.get_newest();
if ((_time_last_imu - latest_measurement.time_us) < 2e5 && _R_rng_to_earth_2_2 > 0.7071f) {
// if we have a fresh measurement, use it to initialise the terrain estimator
_terrain_vpos = _state.pos(2) + latest_measurement.rng * _R_rng_to_earth_2_2;
// initialise state variance to variance of measurement
_terrain_var = sq(_params.range_noise);
// success
return true;
} else if (!_control_status.flags.in_air) {
// if on ground we assume a ground clearance
_terrain_vpos = _state.pos(2) + _params.rng_gnd_clearance;
// Use the ground clearance value as our uncertainty
_terrain_var = sq(_params.rng_gnd_clearance);
// ths is a guess
return false;
} else {
// no information - cannot initialise
return false;
}
}
void Ekf::runTerrainEstimator()
{
// Perform a continuity check on range finder data
checkRangeDataContinuity();
// Perform initialisation check
if (!_terrain_initialised) {
_terrain_initialised = initHagl();
} else {
// predict the state variance growth where the state is the vertical position of the terrain underneath the vehicle
// process noise due to errors in vehicle height estimate
_terrain_var += sq(_imu_sample_delayed.delta_vel_dt * _params.terrain_p_noise);
// process noise due to terrain gradient
_terrain_var += sq(_imu_sample_delayed.delta_vel_dt * _params.terrain_gradient) * (sq(_state.vel(0)) + sq(_state.vel(
1)));
// limit the variance to prevent it becoming badly conditioned
_terrain_var = math::constrain(_terrain_var, 0.0f, 1e4f);
// Fuse range finder data if available
if (_range_data_ready && !_rng_stuck) {
fuseHagl();
// update range sensor angle parameters in case they have changed
// we do this here to avoid doing those calculations at a high rate
_sin_tilt_rng = sinf(_params.rng_sens_pitch);
_cos_tilt_rng = cosf(_params.rng_sens_pitch);
}
//constrain _terrain_vpos to be a minimum of _params.rng_gnd_clearance larger than _state.pos(2)
if (_terrain_vpos - _state.pos(2) < _params.rng_gnd_clearance) {
_terrain_vpos = _params.rng_gnd_clearance + _state.pos(2);
}
}
}
void Ekf::fuseHagl()
{
// If the vehicle is excessively tilted, do not try to fuse range finder observations
if (_R_rng_to_earth_2_2 > 0.7071f) {
// get a height above ground measurement from the range finder assuming a flat earth
float meas_hagl = _range_sample_delayed.rng * _R_rng_to_earth_2_2;
// predict the hagl from the vehicle position and terrain height
float pred_hagl = _terrain_vpos - _state.pos(2);
// calculate the innovation
_hagl_innov = pred_hagl - meas_hagl;
// calculate the observation variance adding the variance of the vehicles own height uncertainty
float obs_variance = fmaxf(P[9][9], 0.0f) + sq(_params.range_noise) + sq(_params.range_noise_scaler * _range_sample_delayed.rng);
// calculate the innovation variance - limiting it to prevent a badly conditioned fusion
_hagl_innov_var = fmaxf(_terrain_var + obs_variance, obs_variance);
// perform an innovation consistency check and only fuse data if it passes
float gate_size = fmaxf(_params.range_innov_gate, 1.0f);
_terr_test_ratio = sq(_hagl_innov) / (sq(gate_size) * _hagl_innov_var);
if (_terr_test_ratio <= 1.0f) {
// calculate the Kalman gain
float gain = _terrain_var / _hagl_innov_var;
// correct the state
_terrain_vpos -= gain * _hagl_innov;
// correct the variance
_terrain_var = fmaxf(_terrain_var * (1.0f - gain), 0.0f);
// record last successful fusion event
_time_last_hagl_fuse = _time_last_imu;
_innov_check_fail_status.flags.reject_hagl = false;
} else {
_innov_check_fail_status.flags.reject_hagl = true;
}
} else {
_innov_check_fail_status.flags.reject_hagl = true;
return;
}
}
// return true if the terrain estimate is valid
bool Ekf::get_terrain_valid()
{
if (_terrain_initialised && _range_data_continuous && !_rng_stuck &&
!_innov_check_fail_status.flags.reject_hagl) {
return true;
} else {
return false;
}
}
// get the estimated vertical position of the terrain relative to the NED origin
void Ekf::get_terrain_vert_pos(float *ret)
{
memcpy(ret, &_terrain_vpos, sizeof(float));
}
void Ekf::get_hagl_innov(float *hagl_innov)
{
memcpy(hagl_innov, &_hagl_innov, sizeof(_hagl_innov));
}
void Ekf::get_hagl_innov_var(float *hagl_innov_var)
{
memcpy(hagl_innov_var, &_hagl_innov_var, sizeof(_hagl_innov_var));
}
// check that the range finder data is continuous
void Ekf::checkRangeDataContinuity()
{
// update range data continuous flag (2Hz ie 500 ms)
/* Timing in micro seconds */
/* Apply a 1.0 sec low pass filter to the time delta from the last range finder updates */
_dt_last_range_update_filt_us = _dt_last_range_update_filt_us * (1.0f - _dt_update) + _dt_update *
(_time_last_imu - _time_last_range);
_dt_last_range_update_filt_us = fminf(_dt_last_range_update_filt_us, 1e6f);
if (_dt_last_range_update_filt_us < 5e5f) {
_range_data_continuous = true;
} else {
_range_data_continuous = false;
}
}