/* This program is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see . This class inherits from AC_AttitudeControl_Multi and provides functionality specific to tailsitter quadplanes. 1) "body-frame" roll control mode for all tailsitters 2) a relax_attitude_controller method needed for coping with vectored tailsitters */ #include "AC_AttitudeControl_TS.h" void AC_AttitudeControl_TS::relax_attitude_controllers(bool exclude_pitch) { // If exclude_pitch: relax roll and yaw rate controller outputs only, // leaving pitch controller active to let TVBS motors tilt up while in throttle_wait if (exclude_pitch) { // Get the current attitude quaternion Quaternion current_attitude; _ahrs.get_quat_body_to_ned(current_attitude); Vector3f current_eulers; current_attitude.to_euler(current_eulers.x, current_eulers.y, current_eulers.z); // set target attitude to zero pitch with (approximate) current roll and yaw // by rotating the current_attitude quaternion by the error in desired pitch Quaternion pitch_rotation; pitch_rotation.from_axis_angle(Vector3f(0, -1, 0), current_eulers.y); _attitude_target = current_attitude * pitch_rotation; _attitude_target.normalize(); _attitude_target.to_euler(_euler_angle_target.x, _euler_angle_target.y, _euler_angle_target.z); _attitude_ang_error = current_attitude.inverse() * _attitude_target; // Initialize the roll and yaw angular rate variables to the current rate _ang_vel_target = _ahrs.get_gyro(); ang_vel_to_euler_rate(_attitude_target, _ang_vel_target, _euler_rate_target); _ang_vel_body.x = _ahrs.get_gyro().x; _ang_vel_body.z = _ahrs.get_gyro().z; // Reset the roll and yaw I terms get_rate_roll_pid().reset_I(); get_rate_yaw_pid().reset_I(); } else { // relax all attitude controllers AC_AttitudeControl::relax_attitude_controllers(); } } // Command euler yaw rate and pitch angle with roll angle specified in body frame // (used only by tailsitter quadplanes) // If plane_controls is true, swap the effects of roll and yaw as euler pitch approaches 90 degrees void AC_AttitudeControl_TS::input_euler_rate_yaw_euler_angle_pitch_bf_roll(bool plane_controls, float body_roll_cd, float euler_pitch_cd, float euler_yaw_rate_cds) { // Convert from centidegrees on public interface to radians float euler_yaw_rate = radians(euler_yaw_rate_cds*0.01f); float euler_pitch = radians(constrain_float(euler_pitch_cd * 0.01f, -90.0f, 90.0f)); float body_roll = radians(-body_roll_cd * 0.01f); const float cpitch = cosf(euler_pitch); const float spitch = fabsf(sinf(euler_pitch)); // Compute attitude error Quaternion attitude_body; Quaternion error_quat; _ahrs.get_quat_body_to_ned(attitude_body); error_quat = attitude_body.inverse() * _attitude_target; Vector3f att_error; error_quat.to_axis_angle(att_error); // update heading float yaw_rate = euler_yaw_rate; if (plane_controls) { yaw_rate = (euler_yaw_rate * spitch) + (body_roll * cpitch); } // limit yaw error float yaw_error = fabsf(att_error.z); float error_ratio = yaw_error / M_PI_2; if (error_ratio > 1) { yaw_rate /= (error_ratio * error_ratio); } _euler_angle_target.z = wrap_PI(_euler_angle_target.z + yaw_rate * _dt); // init attitude target to desired euler yaw and pitch with zero roll _attitude_target.from_euler(0, euler_pitch, _euler_angle_target.z); // apply body-frame yaw/roll (this is roll/yaw for a tailsitter in forward flight) // rotate body_roll axis by |sin(pitch angle)| Quaternion bf_roll_Q; bf_roll_Q.from_axis_angle(Vector3f(0, 0, spitch * body_roll)); // rotate body_yaw axis by cos(pitch angle) Quaternion bf_yaw_Q; if (plane_controls) { bf_yaw_Q.from_axis_angle(Vector3f(cpitch, 0, 0), euler_yaw_rate); } else { bf_yaw_Q.from_axis_angle(Vector3f(-cpitch * body_roll, 0, 0)); } _attitude_target = _attitude_target * bf_roll_Q * bf_yaw_Q; // _euler_angle_target roll and pitch: Note: roll/yaw will be indeterminate when pitch is near +/-90 // These should be used only for logging target eulers, with the caveat noted above. // Also note that _attitude_target.from_euler() should only be used in special circumstances // such as when attitude is specified directly in terms of Euler angles. // _euler_angle_target.x = _attitude_target.get_euler_roll(); // _euler_angle_target.y = euler_pitch; // Set rate feedforward requests to zero _euler_rate_target.zero(); _ang_vel_target.zero(); // Compute attitude error error_quat = attitude_body.inverse() * _attitude_target; error_quat.to_axis_angle(att_error); // Compute the angular velocity target from the attitude error _ang_vel_body = update_ang_vel_target_from_att_error(att_error); }