mirror of https://github.com/ArduPilot/ardupilot
414 lines
15 KiB
C++
414 lines
15 KiB
C++
/*
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APM_AHRS.cpp
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This program is free software: you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation, either version 3 of the License, or
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(at your option) any later version.
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This program is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with this program. If not, see <http://www.gnu.org/licenses/>.
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*/
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#include "AP_AHRS.h"
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#include "AP_AHRS_View.h"
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#include <AP_HAL/AP_HAL.h>
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extern const AP_HAL::HAL& hal;
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// table of user settable parameters
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const AP_Param::GroupInfo AP_AHRS::var_info[] = {
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// index 0 and 1 are for old parameters that are no longer not used
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// @Param: GPS_GAIN
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// @DisplayName: AHRS GPS gain
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// @Description: This controls how much to use the GPS to correct the attitude. This should never be set to zero for a plane as it would result in the plane losing control in turns. For a plane please use the default value of 1.0.
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// @Range: 0.0 1.0
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// @Increment: .01
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// @User: Advanced
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AP_GROUPINFO("GPS_GAIN", 2, AP_AHRS, gps_gain, 1.0f),
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// @Param: GPS_USE
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// @DisplayName: AHRS use GPS for navigation
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// @Description: This controls whether to use dead-reckoning or GPS based navigation. If set to 0 then the GPS won't be used for navigation, and only dead reckoning will be used. A value of zero should never be used for normal flight. Currently this affects only the DCM-based AHRS: the EKF uses GPS whenever it is available.
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// @Values: 0:Disabled,1:Enabled
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// @User: Advanced
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AP_GROUPINFO("GPS_USE", 3, AP_AHRS, _gps_use, 1),
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// @Param: YAW_P
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// @DisplayName: Yaw P
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// @Description: This controls the weight the compass or GPS has on the heading. A higher value means the heading will track the yaw source (GPS or compass) more rapidly.
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// @Range: 0.1 0.4
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// @Increment: .01
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// @User: Advanced
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AP_GROUPINFO("YAW_P", 4, AP_AHRS, _kp_yaw, 0.2f),
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// @Param: RP_P
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// @DisplayName: AHRS RP_P
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// @Description: This controls how fast the accelerometers correct the attitude
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// @Range: 0.1 0.4
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// @Increment: .01
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// @User: Advanced
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AP_GROUPINFO("RP_P", 5, AP_AHRS, _kp, 0.2f),
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// @Param: WIND_MAX
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// @DisplayName: Maximum wind
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// @Description: This sets the maximum allowable difference between ground speed and airspeed. This allows the plane to cope with a failing airspeed sensor. A value of zero means to use the airspeed as is.
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// @Range: 0 127
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// @Units: m/s
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// @Increment: 1
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// @User: Advanced
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AP_GROUPINFO("WIND_MAX", 6, AP_AHRS, _wind_max, 0.0f),
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// NOTE: 7 was BARO_USE
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// @Param: TRIM_X
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// @DisplayName: AHRS Trim Roll
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// @Description: Compensates for the roll angle difference between the control board and the frame. Positive values make the vehicle roll right.
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// @Units: rad
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// @Range: -0.1745 +0.1745
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// @Increment: 0.01
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// @User: Standard
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// @Param: TRIM_Y
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// @DisplayName: AHRS Trim Pitch
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// @Description: Compensates for the pitch angle difference between the control board and the frame. Positive values make the vehicle pitch up/back.
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// @Units: rad
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// @Range: -0.1745 +0.1745
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// @Increment: 0.01
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// @User: Standard
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// @Param: TRIM_Z
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// @DisplayName: AHRS Trim Yaw
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// @Description: Not Used
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// @Units: rad
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// @Range: -0.1745 +0.1745
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// @Increment: 0.01
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// @User: Advanced
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AP_GROUPINFO("TRIM", 8, AP_AHRS, _trim, 0),
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// @Param: ORIENTATION
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// @DisplayName: Board Orientation
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// @Description: Overall board orientation relative to the standard orientation for the board type. This rotates the IMU and compass readings to allow the board to be oriented in your vehicle at any 90 or 45 degree angle. This option takes affect on next boot. After changing you will need to re-level your vehicle.
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// @Values: 0:None,1:Yaw45,2:Yaw90,3:Yaw135,4:Yaw180,5:Yaw225,6:Yaw270,7:Yaw315,8:Roll180,9:Roll180Yaw45,10:Roll180Yaw90,11:Roll180Yaw135,12:Pitch180,13:Roll180Yaw225,14:Roll180Yaw270,15:Roll180Yaw315,16:Roll90,17:Roll90Yaw45,18:Roll90Yaw90,19:Roll90Yaw135,20:Roll270,21:Roll270Yaw45,22:Roll270Yaw90,23:Roll270Yaw136,24:Pitch90,25:Pitch270,26:Pitch180Yaw90,27:Pitch180Yaw270,28:Roll90Pitch90,29:Roll180Pitch90,30:Roll270Pitch90,31:Roll90Pitch180,32:Roll270Pitch180,33:Roll90Pitch270,34:Roll180Pitch270,35:Roll270Pitch270,36:Roll90Pitch180Yaw90,37:Roll90Yaw270
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// @User: Advanced
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AP_GROUPINFO("ORIENTATION", 9, AP_AHRS, _board_orientation, 0),
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// @Param: COMP_BETA
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// @DisplayName: AHRS Velocity Complementary Filter Beta Coefficient
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// @Description: This controls the time constant for the cross-over frequency used to fuse AHRS (airspeed and heading) and GPS data to estimate ground velocity. Time constant is 0.1/beta. A larger time constant will use GPS data less and a small time constant will use air data less.
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// @Range: 0.001 0.5
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// @Increment: .01
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// @User: Advanced
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AP_GROUPINFO("COMP_BETA", 10, AP_AHRS, beta, 0.1f),
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// @Param: GPS_MINSATS
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// @DisplayName: AHRS GPS Minimum satellites
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// @Description: Minimum number of satellites visible to use GPS for velocity based corrections attitude correction. This defaults to 6, which is about the point at which the velocity numbers from a GPS become too unreliable for accurate correction of the accelerometers.
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// @Range: 0 10
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// @Increment: 1
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// @User: Advanced
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AP_GROUPINFO("GPS_MINSATS", 11, AP_AHRS, _gps_minsats, 6),
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// NOTE: index 12 was for GPS_DELAY, but now removed, fixed delay
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// of 1 was found to be the best choice
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// 13 was the old EKF_USE
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#if AP_AHRS_NAVEKF_AVAILABLE
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// @Param: EKF_TYPE
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// @DisplayName: Use NavEKF Kalman filter for attitude and position estimation
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// @Description: This controls which NavEKF Kalman filter version is used for attitude and position estimation
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// @Values: 0:Disabled,2:Enable EKF2,3:Enable EKF3
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// @User: Advanced
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AP_GROUPINFO("EKF_TYPE", 14, AP_AHRS, _ekf_type, 2),
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#endif
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AP_GROUPEND
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};
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// return a smoothed and corrected gyro vector using the latest ins data (which may not have been consumed by the EKF yet)
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Vector3f AP_AHRS::get_gyro_latest(void) const
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{
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const uint8_t primary_gyro = get_primary_gyro_index();
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return get_ins().get_gyro(primary_gyro) + get_gyro_drift();
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}
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// return airspeed estimate if available
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bool AP_AHRS::airspeed_estimate(float *airspeed_ret) const
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{
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if (airspeed_sensor_enabled()) {
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*airspeed_ret = _airspeed->get_airspeed();
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if (_wind_max > 0 && AP::gps().status() >= AP_GPS::GPS_OK_FIX_2D) {
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// constrain the airspeed by the ground speed
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// and AHRS_WIND_MAX
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const float gnd_speed = AP::gps().ground_speed();
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float true_airspeed = *airspeed_ret * get_EAS2TAS();
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true_airspeed = constrain_float(true_airspeed,
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gnd_speed - _wind_max,
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gnd_speed + _wind_max);
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*airspeed_ret = true_airspeed / get_EAS2TAS();
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}
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return true;
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}
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return false;
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}
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// set_trim
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void AP_AHRS::set_trim(Vector3f new_trim)
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{
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Vector3f trim;
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trim.x = constrain_float(new_trim.x, ToRad(-AP_AHRS_TRIM_LIMIT), ToRad(AP_AHRS_TRIM_LIMIT));
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trim.y = constrain_float(new_trim.y, ToRad(-AP_AHRS_TRIM_LIMIT), ToRad(AP_AHRS_TRIM_LIMIT));
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_trim.set_and_save(trim);
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}
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// add_trim - adjust the roll and pitch trim up to a total of 10 degrees
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void AP_AHRS::add_trim(float roll_in_radians, float pitch_in_radians, bool save_to_eeprom)
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{
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Vector3f trim = _trim.get();
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// add new trim
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trim.x = constrain_float(trim.x + roll_in_radians, ToRad(-AP_AHRS_TRIM_LIMIT), ToRad(AP_AHRS_TRIM_LIMIT));
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trim.y = constrain_float(trim.y + pitch_in_radians, ToRad(-AP_AHRS_TRIM_LIMIT), ToRad(AP_AHRS_TRIM_LIMIT));
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// set new trim values
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_trim.set(trim);
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// save to eeprom
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if( save_to_eeprom ) {
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_trim.save();
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}
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}
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// return a ground speed estimate in m/s
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Vector2f AP_AHRS::groundspeed_vector(void)
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{
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// Generate estimate of ground speed vector using air data system
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Vector2f gndVelADS;
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Vector2f gndVelGPS;
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float airspeed;
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const bool gotAirspeed = airspeed_estimate_true(&airspeed);
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const bool gotGPS = (AP::gps().status() >= AP_GPS::GPS_OK_FIX_2D);
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if (gotAirspeed) {
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const Vector3f wind = wind_estimate();
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const Vector2f wind2d(wind.x, wind.y);
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const Vector2f airspeed_vector(cosf(yaw) * airspeed, sinf(yaw) * airspeed);
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gndVelADS = airspeed_vector - wind2d;
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}
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// Generate estimate of ground speed vector using GPS
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if (gotGPS) {
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const float cog = radians(AP::gps().ground_course_cd()*0.01f);
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gndVelGPS = Vector2f(cosf(cog), sinf(cog)) * AP::gps().ground_speed();
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}
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// If both ADS and GPS data is available, apply a complementary filter
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if (gotAirspeed && gotGPS) {
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// The LPF is applied to the GPS and the HPF is applied to the air data estimate
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// before the two are summed
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//Define filter coefficients
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// alpha and beta must sum to one
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// beta = dt/Tau, where
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// dt = filter time step (0.1 sec if called by nav loop)
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// Tau = cross-over time constant (nominal 2 seconds)
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// More lag on GPS requires Tau to be bigger, less lag allows it to be smaller
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// To-Do - set Tau as a function of GPS lag.
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const float alpha = 1.0f - beta;
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// Run LP filters
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_lp = gndVelGPS * beta + _lp * alpha;
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// Run HP filters
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_hp = (gndVelADS - _lastGndVelADS) + _hp * alpha;
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// Save the current ADS ground vector for the next time step
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_lastGndVelADS = gndVelADS;
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// Sum the HP and LP filter outputs
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return _hp + _lp;
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}
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// Only ADS data is available return ADS estimate
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if (gotAirspeed && !gotGPS) {
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return gndVelADS;
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}
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// Only GPS data is available so return GPS estimate
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if (!gotAirspeed && gotGPS) {
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return gndVelGPS;
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}
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return Vector2f(0.0f, 0.0f);
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}
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/*
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calculate sin and cos of roll/pitch/yaw from a body_to_ned rotation matrix
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*/
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void AP_AHRS::calc_trig(const Matrix3f &rot,
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float &cr, float &cp, float &cy,
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float &sr, float &sp, float &sy) const
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{
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Vector2f yaw_vector(rot.a.x, rot.b.x);
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if (fabsf(yaw_vector.x) > 0 ||
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fabsf(yaw_vector.y) > 0) {
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yaw_vector.normalize();
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}
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sy = constrain_float(yaw_vector.y, -1.0f, 1.0f);
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cy = constrain_float(yaw_vector.x, -1.0f, 1.0f);
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// sanity checks
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if (yaw_vector.is_inf() || yaw_vector.is_nan()) {
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sy = 0.0f;
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cy = 1.0f;
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}
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const float cx2 = rot.c.x * rot.c.x;
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if (cx2 >= 1.0f) {
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cp = 0;
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cr = 1.0f;
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} else {
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cp = safe_sqrt(1 - cx2);
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cr = rot.c.z / cp;
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}
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cp = constrain_float(cp, 0.0f, 1.0f);
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cr = constrain_float(cr, -1.0f, 1.0f); // this relies on constrain_float() of infinity doing the right thing
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sp = -rot.c.x;
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if (!is_zero(cp)) {
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sr = rot.c.y / cp;
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}
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if (is_zero(cp) || isinf(cr) || isnan(cr) || isinf(sr) || isnan(sr)) {
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float r, p, y;
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rot.to_euler(&r, &p, &y);
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cr = cosf(r);
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sr = sinf(r);
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}
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}
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// update_trig - recalculates _cos_roll, _cos_pitch, etc based on latest attitude
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// should be called after _dcm_matrix is updated
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void AP_AHRS::update_trig(void)
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{
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if (_last_trim != _trim.get()) {
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_last_trim = _trim.get();
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_rotation_autopilot_body_to_vehicle_body.from_euler(_last_trim.x, _last_trim.y, 0.0f);
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_rotation_vehicle_body_to_autopilot_body = _rotation_autopilot_body_to_vehicle_body.transposed();
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}
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calc_trig(get_rotation_body_to_ned(),
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_cos_roll, _cos_pitch, _cos_yaw,
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_sin_roll, _sin_pitch, _sin_yaw);
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}
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/*
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update the centi-degree values
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*/
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void AP_AHRS::update_cd_values(void)
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{
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roll_sensor = degrees(roll) * 100;
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pitch_sensor = degrees(pitch) * 100;
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yaw_sensor = degrees(yaw) * 100;
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if (yaw_sensor < 0)
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yaw_sensor += 36000;
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}
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/*
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create a rotated view of AP_AHRS
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*/
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AP_AHRS_View *AP_AHRS::create_view(enum Rotation rotation)
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{
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if (_view != nullptr) {
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// can only have one
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return nullptr;
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}
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_view = new AP_AHRS_View(*this, rotation);
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return _view;
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}
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/*
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* Update AOA and SSA estimation based on airspeed, velocity vector and wind vector
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*
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* Based on:
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* "On estimation of wind velocity, angle-of-attack and sideslip angle of small UAVs using standard sensors" by
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* Tor A. Johansen, Andrea Cristofaro, Kim Sorensen, Jakob M. Hansen, Thor I. Fossen
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*
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* "Multi-Stage Fusion Algorithm for Estimation of Aerodynamic Angles in Mini Aerial Vehicle" by
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* C.Ramprasadh and Hemendra Arya
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*
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* "ANGLE OF ATTACK AND SIDESLIP ESTIMATION USING AN INERTIAL REFERENCE PLATFORM" by
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* JOSEPH E. ZEIS, JR., CAPTAIN, USAF
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*/
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void AP_AHRS::update_AOA_SSA(void)
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{
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#if APM_BUILD_TYPE(APM_BUILD_ArduPlane)
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const uint32_t now = AP_HAL::millis();
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if (now - _last_AOA_update_ms < 50) {
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// don't update at more than 20Hz
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return;
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}
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_last_AOA_update_ms = now;
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Vector3f aoa_velocity, aoa_wind;
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// get velocity and wind
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if (get_velocity_NED(aoa_velocity) == false) {
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return;
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}
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aoa_wind = wind_estimate();
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// Rotate vectors to the body frame and calculate velocity and wind
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const Matrix3f &rot = get_rotation_body_to_ned();
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aoa_velocity = rot.mul_transpose(aoa_velocity);
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aoa_wind = rot.mul_transpose(aoa_wind);
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// calculate relative velocity in body coordinates
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aoa_velocity = aoa_velocity - aoa_wind;
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const float vel_len = aoa_velocity.length();
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// do not calculate if speed is too low
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if (vel_len < 2.0) {
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_AOA = 0;
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_SSA = 0;
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return;
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}
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// Calculate AOA and SSA
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if (aoa_velocity.x > 0) {
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_AOA = degrees(atanf(aoa_velocity.z / aoa_velocity.x));
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} else {
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_AOA = 0;
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}
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_SSA = degrees(safe_asin(aoa_velocity.y / vel_len));
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#endif
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}
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// return current AOA
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float AP_AHRS::getAOA(void)
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{
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update_AOA_SSA();
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return _AOA;
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}
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// return calculated SSA
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float AP_AHRS::getSSA(void)
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{
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update_AOA_SSA();
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return _SSA;
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}
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// rotate a 2D vector from earth frame to body frame
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Vector2f AP_AHRS::rotate_earth_to_body2D(const Vector2f &ef) const
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{
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return Vector2f(ef.x * _cos_yaw + ef.y * _sin_yaw,
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-ef.x * _sin_yaw + ef.y * _cos_yaw);
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}
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// rotate a 2D vector from earth frame to body frame
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Vector2f AP_AHRS::rotate_body_to_earth2D(const Vector2f &bf) const
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{
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return Vector2f(bf.x * _cos_yaw - bf.y * _sin_yaw,
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bf.x * _sin_yaw + bf.y * _cos_yaw);
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}
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