ardupilot/libraries/AP_Baro/AP_Baro_Wind.cpp

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#include "AP_Baro.h"
#include <AP_AHRS/AP_AHRS.h>
#if HAL_BARO_WIND_COMP_ENABLED
// table of compensation coefficient parameters for one baro
const AP_Param::GroupInfo AP_Baro::WindCoeff::var_info[] = {
// @Param: ENABLE
// @DisplayName: Wind coefficient enable
// @Description: This enables the use of wind coefficients for barometer compensation
// @Values: 0:Disabled, 1:Enabled
// @User: Advanced
AP_GROUPINFO_FLAGS("ENABLE", 1, WindCoeff, enable, 0, AP_PARAM_FLAG_ENABLE),
// @Param: FWD
// @DisplayName: Pressure error coefficient in positive X direction (forward)
// @Description: This is the ratio of static pressure error to dynamic pressure generated by a positive wind relative velocity along the X body axis. If the baro height estimate rises during forwards flight, then this will be a negative number. Multirotors can use this feature only if using EKF3 and if the EK3_DRAG_BCOEF_X and EK3_DRAG_BCOEF_Y parameters have been tuned.
// @Range: -1.0 1.0
// @Increment: 0.05
// @User: Advanced
AP_GROUPINFO("FWD", 2, WindCoeff, xp, 0.0),
// @Param: BCK
// @DisplayName: Pressure error coefficient in negative X direction (backwards)
// @Description: This is the ratio of static pressure error to dynamic pressure generated by a negative wind relative velocity along the X body axis. If the baro height estimate rises during backwards flight, then this will be a negative number. Multirotors can use this feature only if using EKF3 and if the EK3_DRAG_BCOEF_X and EK3_DRAG_BCOEF_Y parameters have been tuned.
// @Range: -1.0 1.0
// @Increment: 0.05
// @User: Advanced
AP_GROUPINFO("BCK", 3, WindCoeff, xn, 0.0),
// @Param: RGT
// @DisplayName: Pressure error coefficient in positive Y direction (right)
// @Description: This is the ratio of static pressure error to dynamic pressure generated by a positive wind relative velocity along the Y body axis. If the baro height estimate rises during sideways flight to the right, then this should be a negative number. Multirotors can use this feature only if using EKF3 and if the EK3_DRAG_BCOEF_X and EK3_DRAG_BCOEF_Y parameters have been tuned.
// @Range: -1.0 1.0
// @Increment: 0.05
// @User: Advanced
AP_GROUPINFO("RGT", 4, WindCoeff, yp, 0.0),
// @Param: LFT
// @DisplayName: Pressure error coefficient in negative Y direction (left)
// @Description: This is the ratio of static pressure error to dynamic pressure generated by a negative wind relative velocity along the Y body axis. If the baro height estimate rises during sideways flight to the left, then this should be a negative number. Multirotors can use this feature only if using EKF3 and if the EK3_DRAG_BCOEF_X and EK3_DRAG_BCOEF_Y parameters have been tuned.
// @Range: -1.0 1.0
// @Increment: 0.05
// @User: Advanced
AP_GROUPINFO("LFT", 5, WindCoeff, yn, 0.0),
// @Param: UP
// @DisplayName: Pressure error coefficient in positive Z direction (up)
// @Description: This is the ratio of static pressure error to dynamic pressure generated by a positive wind relative velocity along the Z body axis. If the baro height estimate rises above truth height during climbing flight (or forward flight with a high forwards lean angle), then this should be a negative number. Multirotors can use this feature only if using EKF3 and if the EK3_DRAG_BCOEF_X and EK3_DRAG_BCOEF_Y parameters have been tuned.
// @Range: -1.0 1.0
// @Increment: 0.05
// @User: Advanced
AP_GROUPINFO("UP", 6, WindCoeff, zp, 0.0),
// @Param: DN
// @DisplayName: Pressure error coefficient in negative Z direction (down)
// @Description: This is the ratio of static pressure error to dynamic pressure generated by a negative wind relative velocity along the Z body axis. If the baro height estimate rises above truth height during descending flight (or forward flight with a high backwards lean angle, eg braking manoeuvre), then this should be a negative number. Multirotors can use this feature only if using EKF3 and if the EK3_DRAG_BCOEF_X and EK3_DRAG_BCOEF_Y parameters have been tuned.
// @Range: -1.0 1.0
// @Increment: 0.05
// @User: Advanced
AP_GROUPINFO("DN", 7, WindCoeff, zn, 0.0),
AP_GROUPEND
};
/*
return pressure correction for wind based on GND_WCOEF parameters
*/
float AP_Baro::wind_pressure_correction(uint8_t instance)
{
const WindCoeff &wcoef = sensors[instance].wind_coeff;
if (!wcoef.enable) {
return 0;
}
// correct for static pressure position errors
Vector3f airspeed_vec_bf;
if (!AP::ahrs().airspeed_vector_true(airspeed_vec_bf)) {
return 0;
}
float error = 0.0;
const float kp = 0.5 * SSL_AIR_DENSITY * get_air_density_ratio();
const float sqxp = sq(airspeed_vec_bf.x) * kp;
const float sqyp = sq(airspeed_vec_bf.y) * kp;
const float sqzp = sq(airspeed_vec_bf.z) * kp;
if (is_positive(airspeed_vec_bf.x)) {
sensors[instance].dynamic_pressure.x = sqxp;
error += wcoef.xp * sqxp;
} else {
sensors[instance].dynamic_pressure.x = -sqxp;
error += wcoef.xn * sqxp;
}
if (is_positive(airspeed_vec_bf.y)) {
sensors[instance].dynamic_pressure.y = sqyp;
error += wcoef.yp * sqyp;
} else {
sensors[instance].dynamic_pressure.y = -sqyp;
error += wcoef.yn * sqyp;
}
if (is_positive(airspeed_vec_bf.z)) {
sensors[instance].dynamic_pressure.z = sqzp;
error += wcoef.zp * sqzp;
} else {
sensors[instance].dynamic_pressure.z = -sqzp;
error += wcoef.zn * sqzp;
}
return error;
}
#endif // HAL_BARO_WIND_COMP_ENABLED