mirror of https://github.com/ArduPilot/ardupilot
337 lines
12 KiB
C++
337 lines
12 KiB
C++
/*
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APM_DCM_FW.cpp - DCM AHRS Library, fixed wing version, for Ardupilot Mega
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Code by Doug Weibel, Jordi Muñoz and Jose Julio. DIYDrones.com
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This library works with the ArduPilot Mega and "Oilpan"
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This library is free software; you can redistribute it and/or
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modify it under the terms of the GNU Lesser General Public
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License as published by the Free Software Foundation; either
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version 2.1 of the License, or (at your option) any later version.
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Methods:
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update_DCM(_G_Dt) : Updates the AHRS by integrating the rotation matrix over time _G_Dt using the IMU object data
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get_gyro() : Returns gyro vector corrected for bias
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get_accel() : Returns accelerometer vector
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get_dcm_matrix() : Returns dcm matrix
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*/
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#include <AP_DCM.h>
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#define OUTPUTMODE 1 // This is just used for debugging, remove later
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#define ToRad(x) (x*0.01745329252) // *pi/180
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#define ToDeg(x) (x*57.2957795131) // *180/pi
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//#define Kp_ROLLPITCH 0.05967 // .0014 * 418/9.81 Pitch&Roll Drift Correction Proportional Gain
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//#define Ki_ROLLPITCH 0.00001278 // 0.0000003 * 418/9.81 Pitch&Roll Drift Correction Integrator Gain
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//#define Ki_ROLLPITCH 0.0 // 0.0000003 * 418/9.81 Pitch&Roll Drift Correction Integrator Gain
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//#define Kp_YAW 0.8 // Yaw Drift Correction Porportional Gain
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#define Ki_YAW 0.00004 // Yaw Drift CorrectionIntegrator Gain
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#define SPEEDFILT 300 // centimeters/second
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#define ADC_CONSTRAINT 900
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void
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AP_DCM::set_compass(Compass *compass)
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{
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_compass = compass;
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}
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/**************************************************/
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void
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AP_DCM::update_DCM(float _G_Dt)
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{
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_imu->update();
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_gyro_vector = _imu->get_gyro(); // Get current values for IMU sensors
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_accel_vector = _imu->get_accel(); // Get current values for IMU sensors
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matrix_update(_G_Dt); // Integrate the DCM matrix
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normalize(); // Normalize the DCM matrix
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drift_correction(); // Perform drift correction
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euler_angles(); // Calculate pitch, roll, yaw for stabilization and navigation
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}
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/**************************************************/
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//For Debugging
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/*
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void
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printm(const char *l, Matrix3f &m)
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{ Serial.println(" "); Serial.println(l);
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Serial.print(m.a.x, 12); Serial.print(" "); Serial.print(m.a.y, 12); Serial.print(" "); Serial.println(m.a.z, 12);
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Serial.print(m.b.x, 12); Serial.print(" "); Serial.print(m.b.y, 12); Serial.print(" "); Serial.println(m.b.z, 12);
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Serial.print(m.c.x, 12); Serial.print(" "); Serial.print(m.c.y, 12); Serial.print(" "); Serial.println(m.c.z, 12);
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Serial.print(*(uint32_t *)&(m.a.x), HEX); Serial.print(" "); Serial.print(*(uint32_t *)&(m.a.y), HEX); Serial.print(" "); Serial.println(*(uint32_t *)&(m.a.z), HEX);
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Serial.print(*(uint32_t *)&(m.b.x), HEX); Serial.print(" "); Serial.print(*(uint32_t *)&(m.b.y), HEX); Serial.print(" "); Serial.println(*(uint32_t *)&(m.b.z), HEX);
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Serial.print(*(uint32_t *)&(m.c.x), HEX); Serial.print(" "); Serial.print(*(uint32_t *)&(m.c.y), HEX); Serial.print(" "); Serial.println(*(uint32_t *)&(m.c.z), HEX);
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}
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*/
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/**************************************************/
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void
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AP_DCM::matrix_update(float _G_Dt)
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{
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Matrix3f update_matrix;
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Matrix3f temp_matrix;
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//Record when you saturate any of the gyros.
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if((fabs(_gyro_vector.x) >= radians(300)) ||
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(fabs(_gyro_vector.y) >= radians(300)) ||
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(fabs(_gyro_vector.z) >= radians(300))){
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gyro_sat_count++;
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}
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_omega_integ_corr = _gyro_vector + _omega_I; // Used for _centripetal correction (theoretically better than _omega)
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_omega = _omega_integ_corr + _omega_P; // Equation 16, adding proportional and integral correction terms
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if(_centripetal){
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accel_adjust(); // Remove _centripetal acceleration.
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}
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#if OUTPUTMODE == 1
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update_matrix.a.x = 0;
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update_matrix.a.y = -_G_Dt * _omega.z; // -delta Theta z
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update_matrix.a.z = _G_Dt * _omega.y; // delta Theta y
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update_matrix.b.x = _G_Dt * _omega.z; // delta Theta z
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update_matrix.b.y = 0;
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update_matrix.b.z = -_G_Dt * _omega.x; // -delta Theta x
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update_matrix.c.x = -_G_Dt * _omega.y; // -delta Theta y
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update_matrix.c.y = _G_Dt * _omega.x; // delta Theta x
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update_matrix.c.z = 0;
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#else // Uncorrected data (no drift correction)
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update_matrix.a.x = 0;
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update_matrix.a.y = -_G_Dt * _gyro_vector.z;
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update_matrix.a.z = _G_Dt * _gyro_vector.y;
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update_matrix.b.x = _G_Dt * _gyro_vector.z;
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update_matrix.b.y = 0;
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update_matrix.b.z = -_G_Dt * _gyro_vector.x;
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update_matrix.c.x = -_G_Dt * _gyro_vector.y;
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update_matrix.c.y = _G_Dt * _gyro_vector.x;
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update_matrix.c.z = 0;
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#endif
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temp_matrix = _dcm_matrix * update_matrix;
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_dcm_matrix = _dcm_matrix + temp_matrix; // Equation 17
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}
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/**************************************************/
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void
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AP_DCM::accel_adjust(void)
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{
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Vector3f veloc, temp;
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veloc.x = _gps->ground_speed / 100; // We are working with acceleration in m/s^2 units
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// We are working with a modified version of equation 26 as our IMU object reports acceleration in the positive axis direction as positive
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//_accel_vector -= _omega_integ_corr % _veloc; // Equation 26 This line is giving the compiler a problem so we break it up below
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temp.x = 0;
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temp.y = _omega_integ_corr.z * veloc.x; // only computing the non-zero terms
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temp.z = -1.0f * _omega_integ_corr.y * veloc.x; // After looking at the compiler issue lets remove _veloc and simlify
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_accel_vector -= temp;
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}
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/*************************************************
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Direction Cosine Matrix IMU: Theory
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William Premerlani and Paul Bizard
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Numerical errors will gradually reduce the orthogonality conditions expressed by equation 5
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to approximations rather than identities. In effect, the axes in the two frames of reference no
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longer describe a rigid body. Fortunately, numerical error accumulates very slowly, so it is a
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simple matter to stay ahead of it.
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We call the process of enforcing the orthogonality conditions ÒrenormalizationÓ.
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*/
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void
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AP_DCM::normalize(void)
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{
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float error = 0;
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Vector3f temporary[3];
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int problem = 0;
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error = _dcm_matrix.a * _dcm_matrix.b; // eq.18
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temporary[0] = _dcm_matrix.b;
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temporary[1] = _dcm_matrix.a;
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temporary[0] = _dcm_matrix.a - (temporary[0] * (0.5f * error)); // eq.19
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temporary[1] = _dcm_matrix.b - (temporary[1] * (0.5f * error)); // eq.19
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temporary[2] = temporary[0] % temporary[1]; // c= a x b // eq.20
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_dcm_matrix.a = renorm(temporary[0], problem);
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_dcm_matrix.b = renorm(temporary[1], problem);
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_dcm_matrix.c = renorm(temporary[2], problem);
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if (problem == 1) { // Our solution is blowing up and we will force back to initial condition. Hope we are not upside down!
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_dcm_matrix.a.x = 1.0f;
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_dcm_matrix.a.y = 0.0f;
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_dcm_matrix.a.z = 0.0f;
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_dcm_matrix.b.x = 0.0f;
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_dcm_matrix.b.y = 1.0f;
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_dcm_matrix.b.z = 0.0f;
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_dcm_matrix.c.x = 0.0f;
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_dcm_matrix.c.y = 0.0f;
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_dcm_matrix.c.z = 1.0f;
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}
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}
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/**************************************************/
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Vector3f
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AP_DCM::renorm(Vector3f const &a, int &problem)
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{
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float renorm_val;
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renorm_val = a * a;
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if (renorm_val < 1.5625f && renorm_val > 0.64f) { // Check if we are OK to use Taylor expansion
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renorm_val = 0.5 * (3 - renorm_val); // eq.21
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} else if (renorm_val < 100.0f && renorm_val > 0.01f) {
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renorm_val = 1.0 / sqrt(renorm_val);
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renorm_sqrt_count++;
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} else {
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problem = 1;
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renorm_blowup_count++;
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}
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return(a * renorm_val);
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}
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/**************************************************/
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void
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AP_DCM::drift_correction(void)
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{
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//Compensation the Roll, Pitch and Yaw drift.
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//float mag_heading_x;
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//float mag_heading_y;
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float error_course;
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float accel_magnitude;
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float accel_weight;
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float integrator_magnitude;
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//static float scaled_omega_P[3];
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//static float scaled_omega_I[3];
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static bool in_motion = false;
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Matrix3f rot_mat;
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//*****Roll and Pitch***************
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// Calculate the magnitude of the accelerometer vector
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accel_magnitude = _accel_vector.length() / 9.80665f;
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// Dynamic weighting of accelerometer info (reliability filter)
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// Weight for accelerometer info (<0.5G = 0.0, 1G = 1.0 , >1.5G = 0.0)
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accel_weight = constrain(1 - 3 * fabs(1 - accel_magnitude), 0, 1); // upped to (<0.66G = 0.0, 1G = 1.0 , >1.33G = 0.0)
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// We monitor the amount that the accelerometer based drift correction is deweighted for performance reporting
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_health = constrain(_health+(0.02 * (accel_weight - .5)), 0, 1);
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// adjust the ground of reference
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_error_roll_pitch = _dcm_matrix.c % _accel_vector; // Equation 27 *** sign changed from prev implementation???
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// error_roll_pitch are in Accel m/s^2 units
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// Limit max error_roll_pitch to limit max omega_P and omega_I
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_error_roll_pitch.x = constrain(_error_roll_pitch.x, -1.17f, 1.17f);
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_error_roll_pitch.y = constrain(_error_roll_pitch.y, -1.17f, 1.17f);
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_error_roll_pitch.z = constrain(_error_roll_pitch.z, -1.17f, 1.17f);
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_omega_P = _error_roll_pitch * (_kp_roll_pitch * accel_weight);
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_omega_I += _error_roll_pitch * (_ki_roll_pitch * accel_weight);
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//*****YAW***************
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if (_compass) {
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// We make the gyro YAW drift correction based on compass magnetic heading
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error_course = (_dcm_matrix.a.x * _compass->heading_y) - (_dcm_matrix.b.x * _compass->heading_x); // Equation 23, Calculating YAW error
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} else {
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// Use GPS Ground course to correct yaw gyro drift
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if (_gps->ground_speed >= SPEEDFILT) {
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_course_over_ground_x = cos(ToRad(_gps->ground_course/100.0));
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_course_over_ground_y = sin(ToRad(_gps->ground_course/100.0));
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if(in_motion) {
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error_course = (_dcm_matrix.a.x * _course_over_ground_y) - (_dcm_matrix.b.x * _course_over_ground_x); // Equation 23, Calculating YAW error
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} else {
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float cos_psi_err, sin_psi_err;
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// This is the case for when we first start moving and reset the DCM so that yaw matches the gps ground course
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// This is just to get a reasonable estimate faster
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yaw = atan2(_dcm_matrix.b.x, _dcm_matrix.a.x);
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cos_psi_err = cos(ToRad(_gps->ground_course/100.0) - yaw);
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sin_psi_err = sin(ToRad(_gps->ground_course/100.0) - yaw);
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// Rxx = cos psi err, Rxy = - sin psi err, Rxz = 0
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// Ryx = sin psi err, Ryy = cos psi err, Ryz = 0
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// Rzx = Rzy = 0, Rzz = 1
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rot_mat.a.x = cos_psi_err;
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rot_mat.a.y = -sin_psi_err;
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rot_mat.b.x = sin_psi_err;
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rot_mat.b.y = cos_psi_err;
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rot_mat.a.z = 0;
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rot_mat.b.z = 0;
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rot_mat.c.x = 0;
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rot_mat.c.y = 0;
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rot_mat.c.z = 1.0;
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_dcm_matrix = rot_mat * _dcm_matrix;
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in_motion = true;
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error_course = 0;
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}
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} else {
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error_course = 0;
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in_motion = false;
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}
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}
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_error_yaw = _dcm_matrix.c * error_course; // Equation 24, Applys the yaw correction to the XYZ rotation of the aircraft, depeding the position.
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_omega_P += _error_yaw * _kp_yaw; // Adding yaw correction to proportional correction vector.
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_omega_I += _error_yaw * Ki_YAW; // adding yaw correction to integrator correction vector.
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// Here we will place a limit on the integrator so that the integrator cannot ever exceed half the saturation limit of the gyros
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integrator_magnitude = _omega_I.length();
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if (integrator_magnitude > radians(300)) {
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_omega_I *= (0.5f * radians(300) / integrator_magnitude); // Why do we have this discontinuous? EG, why the 0.5?
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}
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//Serial.print("*");
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}
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/**************************************************/
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void
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AP_DCM::euler_angles(void)
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{
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#if (OUTPUTMODE == 2) // Only accelerometer info (debugging purposes)
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roll = atan2(_accel_vector.y, -_accel_vector.z); // atan2(acc_y, acc_z)
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pitch = asin((_accel_vector.x) / (double)9.81); // asin(acc_x)
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yaw = 0;
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#else
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pitch = -asin(_dcm_matrix.c.x);
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roll = atan2(_dcm_matrix.c.y, _dcm_matrix.c.z);
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yaw = atan2(_dcm_matrix.b.x, _dcm_matrix.a.x);
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#endif
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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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float
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AP_DCM::get_health(void)
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{
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return _health;
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}
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