mirror of https://github.com/ArduPilot/ardupilot
761 lines
38 KiB
C++
761 lines
38 KiB
C++
#include "AC_AttitudeControl.h"
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#include <AP_HAL/AP_HAL.h>
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#include <AP_Math/AP_Math.h>
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// table of user settable parameters
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const AP_Param::GroupInfo AC_AttitudeControl::var_info[] = {
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// 0, 1 were RATE_RP_MAX, RATE_Y_MAX
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// @Param: SLEW_YAW
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// @DisplayName: Yaw target slew rate
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// @Description: Maximum rate the yaw target can be updated in Loiter, RTL, Auto flight modes
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// @Units: Centi-Degrees/Sec
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// @Range: 500 18000
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// @Increment: 100
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// @User: Advanced
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AP_GROUPINFO("SLEW_YAW", 2, AC_AttitudeControl, _slew_yaw, AC_ATTITUDE_CONTROL_SLEW_YAW_DEFAULT_CDS),
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// 3 was for ACCEL_RP_MAX
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// @Param: ACCEL_Y_MAX
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// @DisplayName: Acceleration Max for Yaw
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// @Description: Maximum acceleration in yaw axis
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// @Units: Centi-Degrees/Sec/Sec
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// @Range: 0 72000
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// @Values: 0:Disabled, 18000:Slow, 36000:Medium, 54000:Fast
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// @Increment: 1000
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// @User: Advanced
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AP_GROUPINFO("ACCEL_Y_MAX", 4, AC_AttitudeControl, _accel_yaw_max, AC_ATTITUDE_CONTROL_ACCEL_Y_MAX_DEFAULT_CDSS),
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// @Param: RATE_FF_ENAB
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// @DisplayName: Rate Feedforward Enable
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// @Description: Controls whether body-frame rate feedfoward is enabled or disabled
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// @Values: 0:Disabled, 1:Enabled
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// @User: Advanced
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AP_GROUPINFO("RATE_FF_ENAB", 5, AC_AttitudeControl, _rate_bf_ff_enabled, AC_ATTITUDE_CONTROL_RATE_BF_FF_DEFAULT),
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// @Param: ACCEL_R_MAX
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// @DisplayName: Acceleration Max for Roll
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// @Description: Maximum acceleration in roll axis
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// @Units: Centi-Degrees/Sec/Sec
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// @Range: 0 180000
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// @Increment: 1000
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// @Values: 0:Disabled, 72000:Slow, 108000:Medium, 162000:Fast
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// @User: Advanced
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AP_GROUPINFO("ACCEL_R_MAX", 6, AC_AttitudeControl, _accel_roll_max, AC_ATTITUDE_CONTROL_ACCEL_RP_MAX_DEFAULT_CDSS),
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// @Param: ACCEL_P_MAX
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// @DisplayName: Acceleration Max for Pitch
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// @Description: Maximum acceleration in pitch axis
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// @Units: Centi-Degrees/Sec/Sec
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// @Range: 0 180000
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// @Increment: 1000
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// @Values: 0:Disabled, 72000:Slow, 108000:Medium, 162000:Fast
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// @User: Advanced
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AP_GROUPINFO("ACCEL_P_MAX", 7, AC_AttitudeControl, _accel_pitch_max, AC_ATTITUDE_CONTROL_ACCEL_RP_MAX_DEFAULT_CDSS),
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// IDs 8,9,10,11 RESERVED (in use on Solo)
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// @Param: ANGLE_BOOST
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// @DisplayName: Angle Boost
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// @Description: Angle Boost increases output throttle as the vehicle leans to reduce loss of altitude
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// @Values: 0:Disabled, 1:Enabled
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// @User: Advanced
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AP_GROUPINFO("ANGLE_BOOST", 12, AC_AttitudeControl, _angle_boost_enabled, 1),
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// @Param: ANG_RLL_P
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// @DisplayName: Roll axis angle controller P gain
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// @Description: Roll axis angle controller P gain. Converts the error between the desired roll angle and actual angle to a desired roll rate
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// @Range: 3.000 12.000
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// @User: Standard
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AP_SUBGROUPINFO(_p_angle_roll, "ANG_RLL_", 13, AC_AttitudeControl, AC_P),
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// @Param: ANG_PIT_P
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// @DisplayName: Pitch axis angle controller P gain
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// @Description: Pitch axis angle controller P gain. Converts the error between the desired pitch angle and actual angle to a desired pitch rate
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// @Range: 3.000 12.000
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// @User: Standard
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AP_SUBGROUPINFO(_p_angle_pitch, "ANG_PIT_", 14, AC_AttitudeControl, AC_P),
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// @Param: ANG_YAW_P
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// @DisplayName: Yaw axis angle controller P gain
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// @Description: Yaw axis angle controller P gain. Converts the error between the desired yaw angle and actual angle to a desired yaw rate
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// @Range: 3.000 6.000
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// @User: Standard
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AP_SUBGROUPINFO(_p_angle_yaw, "ANG_YAW_", 15, AC_AttitudeControl, AC_P),
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// @Param: ANG_LIM_TC
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// @DisplayName: Angle Limit (to maintain altitude) Time Constant
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// @Description: Angle Limit (to maintain altitude) Time Constant
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// @Range: 0.5 10.0
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// @User: Advanced
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AP_GROUPINFO("ANG_LIM_TC", 16, AC_AttitudeControl, _angle_limit_tc, AC_ATTITUDE_CONTROL_ANGLE_LIMIT_TC_DEFAULT),
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AP_GROUPEND
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};
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// Set output throttle and disable stabilization
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void AC_AttitudeControl::set_throttle_out_unstabilized(float throttle_in, bool reset_attitude_control, float filter_cutoff)
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{
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_throttle_in = throttle_in;
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_motors.set_throttle_filter_cutoff(filter_cutoff);
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if (reset_attitude_control) {
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relax_attitude_controllers();
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}
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_motors.set_throttle(throttle_in);
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_angle_boost = 0.0f;
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}
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// Ensure attitude controller have zero errors to relax rate controller output
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void AC_AttitudeControl::relax_attitude_controllers()
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{
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// TODO add _ahrs.get_quaternion()
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_attitude_target_quat.from_rotation_matrix(_ahrs.get_rotation_body_to_ned());
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_attitude_target_ang_vel = _ahrs.get_gyro();
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_attitude_target_euler_angle = Vector3f(_ahrs.roll, _ahrs.pitch, _ahrs.yaw);
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// Set reference angular velocity used in angular velocity controller equal
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// to the input angular velocity and reset the angular velocity integrators.
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// This zeros the output of the angular velocity controller.
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_rate_target_ang_vel = _ahrs.get_gyro();
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get_rate_roll_pid().reset_I();
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get_rate_pitch_pid().reset_I();
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get_rate_yaw_pid().reset_I();
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}
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void AC_AttitudeControl::reset_rate_controller_I_terms()
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{
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get_rate_roll_pid().reset_I();
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get_rate_pitch_pid().reset_I();
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get_rate_yaw_pid().reset_I();
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}
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// The attitude controller works around the concept of the desired attitude, target attitude
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// and measured attitude. The desired attitude is the attitude input into the attitude controller
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// that expresses where the higher level code would like the aircraft to move to. The target attitude is moved
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// to the desired attitude with jerk, acceleration, and velocity limits. The target angular velocities are fed
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// directly into the rate controllers. The angular error between the measured attitude and the target attitude is
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// fed into the angle controller and the output of the angle controller summed at the input of the rate controllers.
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// By feeding the target angular velocity directly into the rate controllers the measured and target attitudes
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// remain very close together.
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//
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// All input functions below follow the same procedure
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// 1. define the desired attitude the aircraft should attempt to achieve using the input variables
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// 2. using the desired attitude and input variables, define the target angular velocity so that it should
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// move the target attitude towards the desired attitude
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// 3. if _rate_bf_ff_enabled & _use_ff_and_input_shaping are not being used then make the target attitude
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// and target angular velocities equal to the desired attitude and desired angular velocities.
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// 4. ensure _attitude_target_quat, _attitude_target_euler_angle, _attitude_target_euler_rate and
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// _attitude_target_ang_vel have been defined. This ensures input modes can be changed without discontinuity.
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// 5. attitude_controller_run_quat is then run to pass the target angular velocities to the rate controllers and
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// integrate them into the target attitude. Any errors between the target attitude and the measured attitude are
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// corrected by first correcting the thrust vector until the angle between the target thrust vector measured
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// trust vector drops below 2*AC_ATTITUDE_THRUST_ERROR_ANGLE. At this point the heading is also corrected.
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// Command a Quaternion attitude with feedforward and smoothing
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void AC_AttitudeControl::input_quaternion(Quaternion attitude_desired_quat, float smoothing_gain)
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{
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// calculate the attitude target euler angles
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_attitude_target_quat.to_euler(_attitude_target_euler_angle.x, _attitude_target_euler_angle.y, _attitude_target_euler_angle.z);
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// ensure smoothing gain can not cause overshoot
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smoothing_gain = constrain_float(smoothing_gain,1.0f,1/_dt);
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Quaternion attitude_error_quat = _attitude_target_quat.inverse() * attitude_desired_quat;
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Vector3f attitude_error_angle;
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attitude_error_quat.to_axis_angle(attitude_error_angle);
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if (_rate_bf_ff_enabled & _use_ff_and_input_shaping) {
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// When acceleration limiting and feedforward are enabled, the sqrt controller is used to compute an euler
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// angular velocity that will cause the euler angle to smoothly stop at the input angle with limited deceleration
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// and an exponential decay specified by smoothing_gain at the end.
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_attitude_target_ang_vel.x = input_shaping_angle(attitude_error_angle.x, smoothing_gain, get_accel_roll_max_radss(), _attitude_target_ang_vel.x);
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_attitude_target_ang_vel.y = input_shaping_angle(attitude_error_angle.y, smoothing_gain, get_accel_pitch_max_radss(), _attitude_target_ang_vel.y);
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_attitude_target_ang_vel.z = input_shaping_angle(attitude_error_angle.z, smoothing_gain, get_accel_yaw_max_radss(), _attitude_target_ang_vel.z);
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// Convert body-frame angular velocity into euler angle derivative of desired attitude
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ang_vel_to_euler_rate(_attitude_target_euler_angle, _attitude_target_ang_vel, _attitude_target_euler_rate);
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} else {
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_attitude_target_quat = attitude_desired_quat;
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// Set rate feedforward requests to zero
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_attitude_target_euler_rate = Vector3f(0.0f, 0.0f, 0.0f);
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_attitude_target_ang_vel = Vector3f(0.0f, 0.0f, 0.0f);
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}
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// Call quaternion attitude controller
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attitude_controller_run_quat();
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}
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// Command an euler roll and pitch angle and an euler yaw rate with angular velocity feedforward and smoothing
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void AC_AttitudeControl::input_euler_angle_roll_pitch_euler_rate_yaw(float euler_roll_angle_cd, float euler_pitch_angle_cd, float euler_yaw_rate_cds, float smoothing_gain)
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{
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// Convert from centidegrees on public interface to radians
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float euler_roll_angle = radians(euler_roll_angle_cd*0.01f);
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float euler_pitch_angle = radians(euler_pitch_angle_cd*0.01f);
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float euler_yaw_rate = radians(euler_yaw_rate_cds*0.01f);
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// calculate the attitude target euler angles
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_attitude_target_quat.to_euler(_attitude_target_euler_angle.x, _attitude_target_euler_angle.y, _attitude_target_euler_angle.z);
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// ensure smoothing gain can not cause overshoot
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smoothing_gain = constrain_float(smoothing_gain,1.0f,1/_dt);
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// Add roll trim to compensate tail rotor thrust in heli (will return zero on multirotors)
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euler_roll_angle += get_roll_trim_rad();
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if (_rate_bf_ff_enabled & _use_ff_and_input_shaping) {
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// translate the roll pitch and yaw acceleration limits to the euler axis
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Vector3f euler_accel = euler_accel_limit(_attitude_target_euler_angle, Vector3f(get_accel_roll_max_radss(), get_accel_pitch_max_radss(), get_accel_yaw_max_radss()));
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// When acceleration limiting and feedforward are enabled, the sqrt controller is used to compute an euler
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// angular velocity that will cause the euler angle to smoothly stop at the input angle with limited deceleration
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// and an exponential decay specified by smoothing_gain at the end.
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_attitude_target_euler_rate.x = input_shaping_angle(euler_roll_angle-_attitude_target_euler_angle.x, smoothing_gain, euler_accel.x, _attitude_target_euler_rate.x);
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_attitude_target_euler_rate.y = input_shaping_angle(euler_pitch_angle-_attitude_target_euler_angle.y, smoothing_gain, euler_accel.y, _attitude_target_euler_rate.y);
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// When yaw acceleration limiting is enabled, the yaw input shaper constrains angular acceleration about the yaw axis, slewing
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// the output rate towards the input rate.
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_attitude_target_euler_rate.z = input_shaping_ang_vel(_attitude_target_euler_rate.z, euler_yaw_rate, euler_accel.z);
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// Convert euler angle derivative of desired attitude into a body-frame angular velocity vector for feedforward
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euler_rate_to_ang_vel(_attitude_target_euler_angle, _attitude_target_euler_rate, _attitude_target_ang_vel);
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} else {
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// When feedforward is not enabled, the target euler angle is input into the target and the feedforward rate is zeroed.
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_attitude_target_euler_angle.x = euler_roll_angle;
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_attitude_target_euler_angle.y = euler_pitch_angle;
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_attitude_target_euler_angle.z += euler_yaw_rate*_dt;
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// Compute quaternion target attitude
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_attitude_target_quat.from_euler(_attitude_target_euler_angle.x, _attitude_target_euler_angle.y, _attitude_target_euler_angle.z);
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// Set rate feedforward requests to zero
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_attitude_target_euler_rate = Vector3f(0.0f, 0.0f, 0.0f);
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_attitude_target_ang_vel = Vector3f(0.0f, 0.0f, 0.0f);
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}
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// Call quaternion attitude controller
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attitude_controller_run_quat();
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}
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// Command an euler roll, pitch and yaw angle with angular velocity feedforward and smoothing
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void AC_AttitudeControl::input_euler_angle_roll_pitch_yaw(float euler_roll_angle_cd, float euler_pitch_angle_cd, float euler_yaw_angle_cd, bool slew_yaw, float smoothing_gain)
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{
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// Convert from centidegrees on public interface to radians
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float euler_roll_angle = radians(euler_roll_angle_cd*0.01f);
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float euler_pitch_angle = radians(euler_pitch_angle_cd*0.01f);
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float euler_yaw_angle = radians(euler_yaw_angle_cd*0.01f);
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// calculate the attitude target euler angles
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_attitude_target_quat.to_euler(_attitude_target_euler_angle.x, _attitude_target_euler_angle.y, _attitude_target_euler_angle.z);
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// ensure smoothing gain can not cause overshoot
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smoothing_gain = constrain_float(smoothing_gain,1.0f,1/_dt);
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// Add roll trim to compensate tail rotor thrust in heli (will return zero on multirotors)
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euler_roll_angle += get_roll_trim_rad();
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if (_rate_bf_ff_enabled & _use_ff_and_input_shaping) {
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// translate the roll pitch and yaw acceleration limits to the euler axis
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Vector3f euler_accel = euler_accel_limit(_attitude_target_euler_angle, Vector3f(get_accel_roll_max_radss(), get_accel_pitch_max_radss(), get_accel_yaw_max_radss()));
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// When acceleration limiting and feedforward are enabled, the sqrt controller is used to compute an euler
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// angular velocity that will cause the euler angle to smoothly stop at the input angle with limited deceleration
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// and an exponential decay specified by smoothing_gain at the end.
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_attitude_target_euler_rate.x = input_shaping_angle(euler_roll_angle-_attitude_target_euler_angle.x, smoothing_gain, euler_accel.x, _attitude_target_euler_rate.x);
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_attitude_target_euler_rate.y = input_shaping_angle(euler_pitch_angle-_attitude_target_euler_angle.y, smoothing_gain, euler_accel.y, _attitude_target_euler_rate.y);
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_attitude_target_euler_rate.z = input_shaping_angle(euler_yaw_angle-_attitude_target_euler_angle.z, smoothing_gain, euler_accel.z, _attitude_target_euler_rate.z);
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if (slew_yaw) {
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_attitude_target_euler_rate.z = constrain_float(_attitude_target_euler_rate.z, -get_slew_yaw_rads(), get_slew_yaw_rads());
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}
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// Convert euler angle derivative of desired attitude into a body-frame angular velocity vector for feedforward
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euler_rate_to_ang_vel(_attitude_target_euler_angle, _attitude_target_euler_rate, _attitude_target_ang_vel);
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} else {
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// When feedforward is not enabled, the target euler angle is input into the target and the feedforward rate is zeroed.
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_attitude_target_euler_angle.x = euler_roll_angle;
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_attitude_target_euler_angle.y = euler_pitch_angle;
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if (slew_yaw) {
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// Compute constrained angle error
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float angle_error = constrain_float(wrap_PI(euler_yaw_angle-_attitude_target_euler_angle.z), -get_slew_yaw_rads()*_dt, get_slew_yaw_rads()*_dt);
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// Update attitude target from constrained angle error
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_attitude_target_euler_angle.z = wrap_PI(angle_error + _attitude_target_euler_angle.z);
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} else {
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_attitude_target_euler_angle.z = euler_yaw_angle;
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}
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// Compute quaternion target attitude
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_attitude_target_quat.from_euler(_attitude_target_euler_angle.x, _attitude_target_euler_angle.y, _attitude_target_euler_angle.z);
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// Set rate feedforward requests to zero
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_attitude_target_euler_rate = Vector3f(0.0f, 0.0f, 0.0f);
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_attitude_target_ang_vel = Vector3f(0.0f, 0.0f, 0.0f);
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}
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// Call quaternion attitude controller
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attitude_controller_run_quat();
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}
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// Command an euler roll, pitch, and yaw rate with angular velocity feedforward and smoothing
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void AC_AttitudeControl::input_euler_rate_roll_pitch_yaw(float euler_roll_rate_cds, float euler_pitch_rate_cds, float euler_yaw_rate_cds)
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{
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// Convert from centidegrees on public interface to radians
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float euler_roll_rate = radians(euler_roll_rate_cds*0.01f);
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float euler_pitch_rate = radians(euler_pitch_rate_cds*0.01f);
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float euler_yaw_rate = radians(euler_yaw_rate_cds*0.01f);
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// calculate the attitude target euler angles
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_attitude_target_quat.to_euler(_attitude_target_euler_angle.x, _attitude_target_euler_angle.y, _attitude_target_euler_angle.z);
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if (_rate_bf_ff_enabled & _use_ff_and_input_shaping) {
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// translate the roll pitch and yaw acceleration limits to the euler axis
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Vector3f euler_accel = euler_accel_limit(_attitude_target_euler_angle, Vector3f(get_accel_roll_max_radss(), get_accel_pitch_max_radss(), get_accel_yaw_max_radss()));
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// When acceleration limiting is enabled, the input shaper constrains angular acceleration, slewing
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// the output rate towards the input rate.
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_attitude_target_euler_rate.x = input_shaping_ang_vel(_attitude_target_euler_rate.x, euler_roll_rate, euler_accel.x);
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_attitude_target_euler_rate.y = input_shaping_ang_vel(_attitude_target_euler_rate.y, euler_pitch_rate, euler_accel.y);
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_attitude_target_euler_rate.z = input_shaping_ang_vel(_attitude_target_euler_rate.z, euler_yaw_rate, euler_accel.z);
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// Convert euler angle derivative of desired attitude into a body-frame angular velocity vector for feedforward
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euler_rate_to_ang_vel(_attitude_target_euler_angle, _attitude_target_euler_rate, _attitude_target_ang_vel);
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} else {
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// When feedforward is not enabled, the target euler angle is input into the target and the feedforward rate is zeroed.
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// Pitch angle is restricted to +- 85.0 degrees to avoid gimbal lock discontinuities.
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_attitude_target_euler_angle.x = wrap_PI(_attitude_target_euler_angle.x + euler_roll_rate*_dt);
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_attitude_target_euler_angle.y = constrain_float(_attitude_target_euler_angle.y + euler_pitch_rate*_dt, radians(-85.0f), radians(85.0f));
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_attitude_target_euler_angle.z = wrap_2PI(_attitude_target_euler_angle.z + euler_yaw_rate*_dt);
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// Set rate feedforward requests to zero
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_attitude_target_euler_rate = Vector3f(0.0f, 0.0f, 0.0f);
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_attitude_target_ang_vel = Vector3f(0.0f, 0.0f, 0.0f);
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// Compute quaternion target attitude
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_attitude_target_quat.from_euler(_attitude_target_euler_angle.x, _attitude_target_euler_angle.y, _attitude_target_euler_angle.z);
|
|
}
|
|
|
|
// Call quaternion attitude controller
|
|
attitude_controller_run_quat();
|
|
}
|
|
|
|
// Command an angular velocity with angular velocity feedforward and smoothing
|
|
void AC_AttitudeControl::input_rate_bf_roll_pitch_yaw(float roll_rate_bf_cds, float pitch_rate_bf_cds, float yaw_rate_bf_cds)
|
|
{
|
|
// Convert from centidegrees on public interface to radians
|
|
float roll_rate_rads = radians(roll_rate_bf_cds*0.01f);
|
|
float pitch_rate_rads = radians(pitch_rate_bf_cds*0.01f);
|
|
float yaw_rate_rads = radians(yaw_rate_bf_cds*0.01f);
|
|
|
|
// calculate the attitude target euler angles
|
|
_attitude_target_quat.to_euler(_attitude_target_euler_angle.x, _attitude_target_euler_angle.y, _attitude_target_euler_angle.z);
|
|
|
|
if (_rate_bf_ff_enabled & _use_ff_and_input_shaping) {
|
|
// Compute acceleration-limited euler rates
|
|
// When acceleration limiting is enabled, the input shaper constrains angular acceleration about the axis, slewing
|
|
// the output rate towards the input rate.
|
|
_attitude_target_ang_vel.x = input_shaping_ang_vel(_attitude_target_ang_vel.x, roll_rate_rads, get_accel_roll_max_radss());
|
|
_attitude_target_ang_vel.y = input_shaping_ang_vel(_attitude_target_ang_vel.y, pitch_rate_rads, get_accel_pitch_max_radss());
|
|
_attitude_target_ang_vel.z = input_shaping_ang_vel(_attitude_target_ang_vel.z, yaw_rate_rads, get_accel_yaw_max_radss());
|
|
|
|
// Convert body-frame angular velocity into euler angle derivative of desired attitude
|
|
ang_vel_to_euler_rate(_attitude_target_euler_angle, _attitude_target_ang_vel, _attitude_target_euler_rate);
|
|
} else {
|
|
// When feedforward is not enabled, the quaternion is calculated and is input into the target and the feedforward rate is zeroed.
|
|
Quaternion attitude_target_update_quat;
|
|
attitude_target_update_quat.from_axis_angle(Vector3f(roll_rate_rads * _dt, pitch_rate_rads * _dt, yaw_rate_rads * _dt));
|
|
_attitude_target_quat = _attitude_target_quat * attitude_target_update_quat;
|
|
_attitude_target_quat.normalize();
|
|
|
|
// Set rate feedforward requests to zero
|
|
_attitude_target_euler_rate = Vector3f(0.0f, 0.0f, 0.0f);
|
|
_attitude_target_ang_vel = Vector3f(0.0f, 0.0f, 0.0f);
|
|
}
|
|
|
|
// Call quaternion attitude controller
|
|
attitude_controller_run_quat();
|
|
}
|
|
|
|
// Calculates the body frame angular velocities to follow the target attitude
|
|
void AC_AttitudeControl::attitude_controller_run_quat()
|
|
{
|
|
// Retrieve quaternion vehicle attitude
|
|
// TODO add _ahrs.get_quaternion()
|
|
Quaternion attitude_vehicle_quat;
|
|
attitude_vehicle_quat.from_rotation_matrix(_ahrs.get_rotation_body_to_ned());
|
|
|
|
// Compute attitude error
|
|
Vector3f attitude_error_vector;
|
|
thrust_heading_rotation_angles(_attitude_target_quat, attitude_vehicle_quat, attitude_error_vector, _thrust_error_angle);
|
|
|
|
// Compute the angular velocity target from the attitude error
|
|
_rate_target_ang_vel = update_ang_vel_target_from_att_error(attitude_error_vector);
|
|
|
|
// Add feedforward term that attempts to ensure that roll and pitch errors rotate with the body frame rather than the reference frame.
|
|
_rate_target_ang_vel.x += attitude_error_vector.y * _ahrs.get_gyro().z;
|
|
_rate_target_ang_vel.y += -attitude_error_vector.x * _ahrs.get_gyro().z;
|
|
|
|
// Add the angular velocity feedforward, rotated into vehicle frame
|
|
Quaternion attitude_target_ang_vel_quat = Quaternion(0.0f, _attitude_target_ang_vel.x, _attitude_target_ang_vel.y, _attitude_target_ang_vel.z);
|
|
Quaternion attitude_error_quat = attitude_vehicle_quat.inverse() * _attitude_target_quat;
|
|
Quaternion target_ang_vel_quat = attitude_error_quat.inverse()*attitude_target_ang_vel_quat*attitude_error_quat;
|
|
|
|
// Correct the thrust vector and smoothly add feedforward and yaw input
|
|
if(_thrust_error_angle > AC_ATTITUDE_THRUST_ERROR_ANGLE*2.0f){
|
|
_rate_target_ang_vel.z = _ahrs.get_gyro().z;
|
|
}else if(_thrust_error_angle > AC_ATTITUDE_THRUST_ERROR_ANGLE){
|
|
float flip_scalar = (1.0f - (_thrust_error_angle-AC_ATTITUDE_THRUST_ERROR_ANGLE)/AC_ATTITUDE_THRUST_ERROR_ANGLE);
|
|
_rate_target_ang_vel.x += target_ang_vel_quat.q2*flip_scalar;
|
|
_rate_target_ang_vel.y += target_ang_vel_quat.q3*flip_scalar;
|
|
_rate_target_ang_vel.z += target_ang_vel_quat.q4;
|
|
_rate_target_ang_vel.z = _ahrs.get_gyro().z*(1.0-flip_scalar) + _rate_target_ang_vel.z*flip_scalar;
|
|
} else {
|
|
_rate_target_ang_vel.x += target_ang_vel_quat.q2;
|
|
_rate_target_ang_vel.y += target_ang_vel_quat.q3;
|
|
_rate_target_ang_vel.z += target_ang_vel_quat.q4;
|
|
}
|
|
|
|
if (_rate_bf_ff_enabled & _use_ff_and_input_shaping) {
|
|
// rotate target and normalize
|
|
Quaternion attitude_target_update_quat;
|
|
attitude_target_update_quat.from_axis_angle(Vector3f(_attitude_target_ang_vel.x * _dt, _attitude_target_ang_vel.y * _dt, _attitude_target_ang_vel.z * _dt));
|
|
_attitude_target_quat = _attitude_target_quat * attitude_target_update_quat;
|
|
_attitude_target_quat.normalize();
|
|
}
|
|
}
|
|
|
|
// thrust_heading_rotation_angles - calculates two ordered rotations to move the att_from_quat quaternion to the att_to_quat quaternion.
|
|
// The first rotation corrects the thrust vector and the second rotation corrects the heading vector.
|
|
void AC_AttitudeControl::thrust_heading_rotation_angles(Quaternion& att_to_quat, const Quaternion& att_from_quat, Vector3f& att_diff_angle, float& thrust_vec_dot)
|
|
{
|
|
Matrix3f att_to_rot_matrix; // earth frame to target frame
|
|
att_to_quat.rotation_matrix(att_to_rot_matrix);
|
|
Vector3f att_to_thrust_vec = att_to_rot_matrix*Vector3f(0.0f,0.0f,1.0f);
|
|
|
|
Matrix3f att_from_rot_matrix; // earth frame to target frame
|
|
att_from_quat.rotation_matrix(att_from_rot_matrix);
|
|
Vector3f att_from_thrust_vec = att_from_rot_matrix*Vector3f(0.0f,0.0f,1.0f);
|
|
|
|
// the cross product of the desired and target thrust vector defines the rotation vector
|
|
Vector3f thrust_vec_cross = att_from_thrust_vec % att_to_thrust_vec;
|
|
|
|
// the dot product is used to calculate the angle between the target and desired thrust vectors
|
|
thrust_vec_dot = acosf(constrain_float(att_from_thrust_vec * att_to_thrust_vec,-1.0f,1.0f));
|
|
|
|
// Normalize the thrust rotation vector
|
|
float thrust_vector_length = thrust_vec_cross.length();
|
|
if(is_zero(thrust_vector_length) || is_zero(thrust_vec_dot)){
|
|
thrust_vec_cross = Vector3f(0,0,1);
|
|
thrust_vec_dot = 0.0f;
|
|
}else{
|
|
thrust_vec_cross /= thrust_vector_length;
|
|
}
|
|
Quaternion thrust_vec_correction_quat;
|
|
thrust_vec_correction_quat.from_axis_angle(thrust_vec_cross, thrust_vec_dot);
|
|
thrust_vec_correction_quat = att_from_quat.inverse()*thrust_vec_correction_quat*att_from_quat;
|
|
|
|
// calculate the remaining rotation required after thrust vector is rotated
|
|
Quaternion heading_quat = thrust_vec_correction_quat.inverse()*att_from_quat.inverse()*att_to_quat;
|
|
|
|
Vector3f rotation;
|
|
thrust_vec_correction_quat.to_axis_angle(rotation);
|
|
att_diff_angle.x = rotation.x;
|
|
att_diff_angle.y = rotation.y;
|
|
|
|
heading_quat.to_axis_angle(rotation);
|
|
att_diff_angle.z = rotation.z;
|
|
if(!is_zero(_p_angle_yaw.kP()) && fabsf(att_diff_angle.z) > AC_ATTITUDE_ACCEL_Y_CONTROLLER_MAX_RADSS/_p_angle_yaw.kP()){
|
|
att_diff_angle.z = constrain_float(wrap_PI(att_diff_angle.z), -AC_ATTITUDE_ACCEL_Y_CONTROLLER_MAX_RADSS/_p_angle_yaw.kP(), AC_ATTITUDE_ACCEL_Y_CONTROLLER_MAX_RADSS/_p_angle_yaw.kP());
|
|
heading_quat.from_axis_angle(Vector3f(0.0f,0.0f,att_diff_angle.z));
|
|
att_to_quat = att_from_quat*thrust_vec_correction_quat*heading_quat;
|
|
}
|
|
}
|
|
|
|
// calculates the velocity correction from an angle error. The angular velocity has acceleration and
|
|
// deceleration limits including basic jerk limiting using smoothing_gain
|
|
float AC_AttitudeControl::input_shaping_angle(float error_angle, float smoothing_gain, float accel_max, float target_ang_vel)
|
|
{
|
|
error_angle = wrap_PI(error_angle);
|
|
// Calculate the velocity as error approaches zero with acceleration limited by accel_max_radss
|
|
float ang_vel = sqrt_controller(error_angle, smoothing_gain, accel_max);
|
|
|
|
// Acceleration is limited directly to smooth the beginning of the curve.
|
|
if (accel_max > 0) {
|
|
float delta_ang_vel = accel_max * _dt;
|
|
return constrain_float(ang_vel, target_ang_vel-delta_ang_vel, target_ang_vel+delta_ang_vel);
|
|
} else {
|
|
return ang_vel;
|
|
}
|
|
}
|
|
|
|
// limits the acceleration and deceleration of a velocity request
|
|
float AC_AttitudeControl::input_shaping_ang_vel(float target_ang_vel, float desired_ang_vel, float accel_max)
|
|
{
|
|
if (accel_max > 0.0f) {
|
|
float delta_ang_vel = accel_max * _dt;
|
|
target_ang_vel += constrain_float(desired_ang_vel - target_ang_vel, -delta_ang_vel, delta_ang_vel);
|
|
} else {
|
|
target_ang_vel = desired_ang_vel;
|
|
}
|
|
return target_ang_vel;
|
|
}
|
|
|
|
// translates body frame acceleration limits to the euler axis
|
|
Vector3f AC_AttitudeControl::euler_accel_limit(Vector3f euler_rad, Vector3f euler_accel)
|
|
{
|
|
float sin_phi = constrain_float(fabsf(sinf(euler_rad.x)), 0.1f, 1.0f);
|
|
float cos_phi = constrain_float(fabsf(cosf(euler_rad.x)), 0.1f, 1.0f);
|
|
float sin_theta = constrain_float(fabsf(sinf(euler_rad.y)), 0.1f, 1.0f);
|
|
|
|
Vector3f rot_accel;
|
|
if(is_zero(euler_accel.x) || is_zero(euler_accel.y) || is_zero(euler_accel.z) || (euler_accel.x < 0.0f) || (euler_accel.y < 0.0f) || (euler_accel.z < 0.0f)) {
|
|
rot_accel.x = euler_accel.x;
|
|
rot_accel.y = euler_accel.y;
|
|
rot_accel.z = euler_accel.z;
|
|
} else {
|
|
rot_accel.x = euler_accel.x;
|
|
rot_accel.y = MIN(euler_accel.y/cos_phi, euler_accel.z/sin_phi);
|
|
rot_accel.z = MIN(MIN(euler_accel.x/sin_theta, euler_accel.y/sin_phi), euler_accel.z/cos_phi);
|
|
}
|
|
return rot_accel;
|
|
}
|
|
|
|
// Shifts earth frame yaw target by yaw_shift_cd. yaw_shift_cd should be in centidegrees and is added to the current target heading
|
|
void AC_AttitudeControl::shift_ef_yaw_target(float yaw_shift_cd)
|
|
{
|
|
float yaw_shift = radians(yaw_shift_cd*0.01f);
|
|
Quaternion _attitude_target_update_quat;
|
|
_attitude_target_update_quat.from_axis_angle(Vector3f(0.0f, 0.0f, yaw_shift));
|
|
_attitude_target_quat = _attitude_target_update_quat*_attitude_target_quat;
|
|
}
|
|
|
|
// Convert a 321-intrinsic euler angle derivative to an angular velocity vector
|
|
void AC_AttitudeControl::euler_rate_to_ang_vel(const Vector3f& euler_rad, const Vector3f& euler_rate_rads, Vector3f& ang_vel_rads)
|
|
{
|
|
float sin_theta = sinf(euler_rad.y);
|
|
float cos_theta = cosf(euler_rad.y);
|
|
float sin_phi = sinf(euler_rad.x);
|
|
float cos_phi = cosf(euler_rad.x);
|
|
|
|
ang_vel_rads.x = euler_rate_rads.x - sin_theta * euler_rate_rads.z;
|
|
ang_vel_rads.y = cos_phi * euler_rate_rads.y + sin_phi * cos_theta * euler_rate_rads.z;
|
|
ang_vel_rads.z = -sin_phi * euler_rate_rads.y + cos_theta * cos_phi * euler_rate_rads.z;
|
|
}
|
|
|
|
// Convert an angular velocity vector to a 321-intrinsic euler angle derivative
|
|
// Returns false if the vehicle is pitched 90 degrees up or down
|
|
bool AC_AttitudeControl::ang_vel_to_euler_rate(const Vector3f& euler_rad, const Vector3f& ang_vel_rads, Vector3f& euler_rate_rads)
|
|
{
|
|
float sin_theta = sinf(euler_rad.y);
|
|
float cos_theta = cosf(euler_rad.y);
|
|
float sin_phi = sinf(euler_rad.x);
|
|
float cos_phi = cosf(euler_rad.x);
|
|
|
|
// When the vehicle pitches all the way up or all the way down, the euler angles become discontinuous. In this case, we just return false.
|
|
if (is_zero(cos_theta)) {
|
|
return false;
|
|
}
|
|
|
|
euler_rate_rads.x = ang_vel_rads.x + sin_phi * (sin_theta/cos_theta) * ang_vel_rads.y + cos_phi * (sin_theta/cos_theta) * ang_vel_rads.z;
|
|
euler_rate_rads.y = cos_phi * ang_vel_rads.y - sin_phi * ang_vel_rads.z;
|
|
euler_rate_rads.z = (sin_phi / cos_theta) * ang_vel_rads.y + (cos_phi / cos_theta) * ang_vel_rads.z;
|
|
return true;
|
|
}
|
|
|
|
// Update rate_target_ang_vel using attitude_error_rot_vec_rad
|
|
Vector3f AC_AttitudeControl::update_ang_vel_target_from_att_error(Vector3f attitude_error_rot_vec_rad)
|
|
{
|
|
Vector3f rate_target_ang_vel;
|
|
// Compute the roll angular velocity demand from the roll angle error
|
|
if (_use_ff_and_input_shaping) {
|
|
rate_target_ang_vel.x = sqrt_controller(attitude_error_rot_vec_rad.x, _p_angle_roll.kP(), constrain_float(get_accel_roll_max_radss()/2.0f, AC_ATTITUDE_ACCEL_RP_CONTROLLER_MIN_RADSS, AC_ATTITUDE_ACCEL_RP_CONTROLLER_MAX_RADSS));
|
|
}else{
|
|
rate_target_ang_vel.x = _p_angle_roll.kP() * attitude_error_rot_vec_rad.x;
|
|
}
|
|
|
|
// Compute the pitch angular velocity demand from the roll angle error
|
|
if (_use_ff_and_input_shaping) {
|
|
rate_target_ang_vel.y = sqrt_controller(attitude_error_rot_vec_rad.y, _p_angle_pitch.kP(), constrain_float(get_accel_pitch_max_radss()/2.0f, AC_ATTITUDE_ACCEL_RP_CONTROLLER_MIN_RADSS, AC_ATTITUDE_ACCEL_RP_CONTROLLER_MAX_RADSS));
|
|
}else{
|
|
rate_target_ang_vel.y = _p_angle_pitch.kP() * attitude_error_rot_vec_rad.y;
|
|
}
|
|
|
|
// Compute the yaw angular velocity demand from the roll angle error
|
|
if (_use_ff_and_input_shaping) {
|
|
rate_target_ang_vel.z = sqrt_controller(attitude_error_rot_vec_rad.z, _p_angle_yaw.kP(), constrain_float(get_accel_yaw_max_radss()/2.0f, AC_ATTITUDE_ACCEL_Y_CONTROLLER_MIN_RADSS, AC_ATTITUDE_ACCEL_Y_CONTROLLER_MAX_RADSS));
|
|
}else{
|
|
rate_target_ang_vel.z = _p_angle_yaw.kP() * attitude_error_rot_vec_rad.z;
|
|
}
|
|
return rate_target_ang_vel;
|
|
}
|
|
|
|
// Run the roll angular velocity PID controller and return the output
|
|
float AC_AttitudeControl::rate_target_to_motor_roll(float rate_target_rads)
|
|
{
|
|
float current_rate_rads = _ahrs.get_gyro().x;
|
|
float rate_error_rads = rate_target_rads - current_rate_rads;
|
|
|
|
// pass error to PID controller
|
|
get_rate_roll_pid().set_input_filter_d(rate_error_rads);
|
|
get_rate_roll_pid().set_desired_rate(rate_target_rads);
|
|
|
|
float integrator = get_rate_roll_pid().get_integrator();
|
|
|
|
// Ensure that integrator can only be reduced if the output is saturated
|
|
if (!_motors.limit.roll_pitch || ((integrator > 0 && rate_error_rads < 0) || (integrator < 0 && rate_error_rads > 0))) {
|
|
integrator = get_rate_roll_pid().get_i();
|
|
}
|
|
|
|
// Compute output in range -1 ~ +1
|
|
float output = get_rate_roll_pid().get_p() + integrator + get_rate_roll_pid().get_d();
|
|
|
|
// Constrain output
|
|
return constrain_float(output, -1.0f, 1.0f);
|
|
}
|
|
|
|
// Run the pitch angular velocity PID controller and return the output
|
|
float AC_AttitudeControl::rate_target_to_motor_pitch(float rate_target_rads)
|
|
{
|
|
float current_rate_rads = _ahrs.get_gyro().y;
|
|
float rate_error_rads = rate_target_rads - current_rate_rads;
|
|
|
|
// pass error to PID controller
|
|
get_rate_pitch_pid().set_input_filter_d(rate_error_rads);
|
|
get_rate_pitch_pid().set_desired_rate(rate_target_rads);
|
|
|
|
float integrator = get_rate_pitch_pid().get_integrator();
|
|
|
|
// Ensure that integrator can only be reduced if the output is saturated
|
|
if (!_motors.limit.roll_pitch || ((integrator > 0 && rate_error_rads < 0) || (integrator < 0 && rate_error_rads > 0))) {
|
|
integrator = get_rate_pitch_pid().get_i();
|
|
}
|
|
|
|
// Compute output in range -1 ~ +1
|
|
float output = get_rate_pitch_pid().get_p() + integrator + get_rate_pitch_pid().get_d();
|
|
|
|
// Constrain output
|
|
return constrain_float(output, -1.0f, 1.0f);
|
|
}
|
|
|
|
// Run the yaw angular velocity PID controller and return the output
|
|
float AC_AttitudeControl::rate_target_to_motor_yaw(float rate_target_rads)
|
|
{
|
|
float current_rate_rads = _ahrs.get_gyro().z;
|
|
float rate_error_rads = rate_target_rads - current_rate_rads;
|
|
|
|
// pass error to PID controller
|
|
get_rate_yaw_pid().set_input_filter_all(rate_error_rads);
|
|
get_rate_yaw_pid().set_desired_rate(rate_target_rads);
|
|
|
|
float integrator = get_rate_yaw_pid().get_integrator();
|
|
|
|
// Ensure that integrator can only be reduced if the output is saturated
|
|
if (!_motors.limit.yaw || ((integrator > 0 && rate_error_rads < 0) || (integrator < 0 && rate_error_rads > 0))) {
|
|
integrator = get_rate_yaw_pid().get_i();
|
|
}
|
|
|
|
// Compute output in range -1 ~ +1
|
|
float output = get_rate_yaw_pid().get_p() + integrator + get_rate_yaw_pid().get_d();
|
|
|
|
// Constrain output
|
|
return constrain_float(output, -1.0f, 1.0f);
|
|
}
|
|
|
|
// Enable or disable body-frame feed forward
|
|
void AC_AttitudeControl::accel_limiting(bool enable_limits)
|
|
{
|
|
if (enable_limits) {
|
|
// If enabling limits, reload from eeprom or set to defaults
|
|
if (is_zero(_accel_roll_max)) {
|
|
_accel_roll_max.load();
|
|
}
|
|
if (is_zero(_accel_pitch_max)) {
|
|
_accel_pitch_max.load();
|
|
}
|
|
if (is_zero(_accel_yaw_max)) {
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_accel_yaw_max.load();
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}
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} else {
|
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_accel_roll_max = 0.0f;
|
|
_accel_pitch_max = 0.0f;
|
|
_accel_yaw_max = 0.0f;
|
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}
|
|
}
|
|
|
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// Return tilt angle limit for pilot input that prioritises altitude hold over lean angle
|
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float AC_AttitudeControl::get_althold_lean_angle_max() const
|
|
{
|
|
// convert to centi-degrees for public interface
|
|
return ToDeg(_althold_lean_angle_max) * 100.0f;
|
|
}
|
|
|
|
// Proportional controller with piecewise sqrt sections to constrain second derivative
|
|
float AC_AttitudeControl::sqrt_controller(float error, float p, float second_ord_lim)
|
|
{
|
|
if (second_ord_lim < 0.0f || is_zero(second_ord_lim) || is_zero(p)) {
|
|
return error*p;
|
|
}
|
|
|
|
float linear_dist = second_ord_lim/sq(p);
|
|
|
|
if (error > linear_dist) {
|
|
return safe_sqrt(2.0f*second_ord_lim*(error-(linear_dist/2.0f)));
|
|
} else if (error < -linear_dist) {
|
|
return -safe_sqrt(2.0f*second_ord_lim*(-error-(linear_dist/2.0f)));
|
|
} else {
|
|
return error*p;
|
|
}
|
|
}
|
|
|
|
// Inverse proportional controller with piecewise sqrt sections to constrain second derivative
|
|
float AC_AttitudeControl::stopping_point(float first_ord_mag, float p, float second_ord_lim)
|
|
{
|
|
if (second_ord_lim > 0.0f && !is_zero(second_ord_lim) && is_zero(p)) {
|
|
return (first_ord_mag*first_ord_mag)/(2.0f*second_ord_lim);
|
|
} else if ((second_ord_lim < 0.0f || is_zero(second_ord_lim)) && !is_zero(p)) {
|
|
return first_ord_mag/p;
|
|
} else if ((second_ord_lim < 0.0f || is_zero(second_ord_lim)) && is_zero(p)) {
|
|
return 0.0f;
|
|
}
|
|
|
|
// calculate the velocity at which we switch from calculating the stopping point using a linear function to a sqrt function
|
|
float linear_velocity = second_ord_lim/p;
|
|
|
|
if (fabsf(first_ord_mag) < linear_velocity) {
|
|
// if our current velocity is below the cross-over point we use a linear function
|
|
return first_ord_mag/p;
|
|
} else {
|
|
float linear_dist = second_ord_lim/sq(p);
|
|
float overshoot = (linear_dist/2.0f) + sq(first_ord_mag)/(2.0f*second_ord_lim);
|
|
if (first_ord_mag > 0){
|
|
return overshoot;
|
|
} else {
|
|
return -overshoot;
|
|
}
|
|
}
|
|
}
|
|
|
|
// Return roll rate step size in centidegrees/s that results in maximum output after 4 time steps
|
|
float AC_AttitudeControl::max_rate_step_bf_roll()
|
|
{
|
|
float alpha = get_rate_roll_pid().get_filt_alpha();
|
|
float alpha_remaining = 1-alpha;
|
|
return 2.0f*_motors.get_throttle_hover()*AC_ATTITUDE_RATE_RP_CONTROLLER_OUT_MAX/((alpha_remaining*alpha_remaining*alpha_remaining*alpha*get_rate_roll_pid().kD())/_dt + get_rate_roll_pid().kP());
|
|
}
|
|
|
|
// Return pitch rate step size in centidegrees/s that results in maximum output after 4 time steps
|
|
float AC_AttitudeControl::max_rate_step_bf_pitch()
|
|
{
|
|
float alpha = get_rate_pitch_pid().get_filt_alpha();
|
|
float alpha_remaining = 1-alpha;
|
|
return 2.0f*_motors.get_throttle_hover()*AC_ATTITUDE_RATE_RP_CONTROLLER_OUT_MAX/((alpha_remaining*alpha_remaining*alpha_remaining*alpha*get_rate_pitch_pid().kD())/_dt + get_rate_pitch_pid().kP());
|
|
}
|
|
|
|
// Return yaw rate step size in centidegrees/s that results in maximum output after 4 time steps
|
|
float AC_AttitudeControl::max_rate_step_bf_yaw()
|
|
{
|
|
float alpha = get_rate_yaw_pid().get_filt_alpha();
|
|
float alpha_remaining = 1-alpha;
|
|
return 2.0f*_motors.get_throttle_hover()*AC_ATTITUDE_RATE_RP_CONTROLLER_OUT_MAX/((alpha_remaining*alpha_remaining*alpha_remaining*alpha*get_rate_yaw_pid().kD())/_dt + get_rate_yaw_pid().kP());
|
|
}
|