/* SITL handling This simulates a compass Andrew Tridgell November 2011 */ #include #include #include #include #include #include #include #include #include #include "desktop.h" #include "util.h" #define MAG_OFS_X 5.0 #define MAG_OFS_Y 13.0 #define MAG_OFS_Z -18.0 // declination in Canberra (degrees) #define MAG_DECLINATION 12.1 // inclination in Canberra (degrees) #define MAG_INCLINATION -66 // magnetic field strength in Canberra as observed // using an APM1 with 5883L compass #define MAG_FIELD_STRENGTH 818 extern SITL sitl; /* given a magnetic heading, and roll, pitch, yaw values, calculate consistent magnetometer components All angles are in radians */ static Vector3f heading_to_mag(float roll, float pitch, float yaw) { Vector3f Bearth, m; Matrix3f R; // Bearth is the magnetic field in Canberra. We need to adjust // it for inclination and declination Bearth(MAG_FIELD_STRENGTH, 0, 0); R.from_euler(0, -ToRad(MAG_INCLINATION), ToRad(MAG_DECLINATION)); Bearth = R * Bearth; // create a rotation matrix for the given attitude R.from_euler(roll, pitch, yaw); // convert the earth frame magnetic vector to body frame, and // apply the offsets m = R.transposed() * Bearth - Vector3f(MAG_OFS_X, MAG_OFS_Y, MAG_OFS_Z); return m + (rand_vec3f() * sitl.mag_noise); } /* setup the compass with new input all inputs are in degrees */ void sitl_update_compass(float roll, float pitch, float yaw) { extern AP_Compass_HIL compass; Vector3f m = heading_to_mag(ToRad(roll), ToRad(pitch), ToRad(yaw)); compass.setHIL(m.x, m.y, m.z); }