// -*- tab-width: 4; Mode: C++; c-basic-offset: 4; indent-tabs-mode: t -*- #include "AC_AttitudeControl.h" #include extern const AP_HAL::HAL& hal; // table of user settable parameters const AP_Param::GroupInfo AC_AttitudeControl::var_info[] PROGMEM = { // @Param: RATE_RP_MAX // @DisplayName: Angle Rate Roll-Pitch max // @Description: maximum rotation rate in roll/pitch axis requested by angle controller used in stabilize, loiter, rtl, auto flight modes // @Units: Centi-Degrees/Sec // @Range: 90000 250000 // @Increment: 500 // @User: Advanced AP_GROUPINFO("RATE_RP_MAX", 0, AC_AttitudeControl, _angle_rate_rp_max, AC_ATTITUDE_CONTROL_RATE_RP_MAX_DEFAULT), // @Param: RATE_Y_MAX // @DisplayName: Angle Rate Yaw max // @Description: maximum rotation rate in roll/pitch axis requested by angle controller used in stabilize, loiter, rtl, auto flight modes // @Units: Centi-Degrees/Sec // @Range: 90000 250000 // @Increment: 500 // @User: Advanced AP_GROUPINFO("RATE_Y_MAX", 1, AC_AttitudeControl, _angle_rate_y_max, AC_ATTITUDE_CONTROL_RATE_Y_MAX_DEFAULT), // @Param: SLEW_YAW // @DisplayName: Yaw target slew rate // @Description: Maximum rate the yaw target can be updated in Loiter, RTL, Auto flight modes // @Units: Centi-Degrees/Sec // @Range: 500 18000 // @Increment: 100 // @User: Advanced AP_GROUPINFO("SLEW_YAW", 2, AC_AttitudeControl, _slew_yaw, AC_ATTITUDE_CONTROL_SLEW_YAW_DEFAULT), // @Param: ACCEL_RP_MAX // @DisplayName: Acceleration Max for Roll/Pitch // @Description: Maximum acceleration in roll/pitch axis // @Units: Centi-Degrees/Sec/Sec // @Values: 36000:Very Soft, 54000:Soft, 90000:Medium, 126000:Crisp, 162000:Very Crisp // @User: Advanced AP_GROUPINFO("ACCEL_RP_MAX", 3, AC_AttitudeControl, _accel_rp_max, AC_ATTITUDE_CONTROL_ACCEL_RP_MAX_DEFAULT), // @Param: ACCEL_Y_MAX // @DisplayName: Acceleration Max for Yaw // @Description: Maximum acceleration in yaw axis // @Units: Centi-Degrees/Sec/Sec // @Range: 20000 100000 // @Increment: 100 // @User: Advanced AP_GROUPINFO("ACCEL_Y_MAX", 4, AC_AttitudeControl, _accel_y_max, AC_ATTITUDE_CONTROL_ACCEL_Y_MAX_DEFAULT), AP_GROUPEND }; // // high level controllers // // init_targets - resets target angles to current angles void AC_AttitudeControl::init_targets() { // set earth frame angle targets to current lean angles _angle_ef_target.x = _ahrs.roll_sensor; _angle_ef_target.y = _ahrs.pitch_sensor; _angle_ef_target.z = _ahrs.yaw_sensor; // clear body frame angle errors _angle_bf_error.zero(); // clear earth-frame and body-frame feed forward rates const Vector3f& gyro = _ins.get_gyro(); _rate_bf_desired = gyro * AC_ATTITUDE_CONTROL_DEGX100; frame_conversion_bf_to_ef(_rate_bf_desired,_rate_ef_desired); } // // methods to be called by upper controllers to request and implement a desired attitude // // angle_ef_roll_pitch_rate_ef_yaw_smooth - attempts to maintain a roll and pitch angle and yaw rate (all earth frame) while smoothing the attitude based on the feel parameter // smoothing_gain : a number from 1 to 50 with 1 being sluggish and 50 being very crisp void AC_AttitudeControl::angle_ef_roll_pitch_rate_ef_yaw_smooth(float roll_angle_ef, float pitch_angle_ef, float yaw_rate_ef, float smoothing_gain) { Vector3f angle_ef_error; // earth frame angle errors float rate_change_limit; // sanity check smoothing gain smoothing_gain = constrain_float(smoothing_gain,1.0f,50.0f); float linear_angle = _accel_rp_max/(smoothing_gain*smoothing_gain); rate_change_limit = _accel_rp_max * _dt; float rate_ef_desired; float angle_to_target; // calculate earth-frame roll and pitch angle error angle_ef_error.x = wrap_180_cd_float(_angle_ef_target.x - _ahrs.roll_sensor); angle_ef_error.y = wrap_180_cd_float(_angle_ef_target.y - _ahrs.pitch_sensor); // calculate earth-frame feed forward roll rate using linear response when close to the target, sqrt response when we're further away angle_to_target = roll_angle_ef - _angle_ef_target.x; if (angle_to_target > linear_angle){ rate_ef_desired = safe_sqrt(2.0f*_accel_rp_max*(fabs(angle_to_target)-(linear_angle/2.0f))); } else if (angle_to_target < -linear_angle){ rate_ef_desired = -safe_sqrt(2.0f*_accel_rp_max*(fabs(angle_to_target)-(linear_angle/2.0f))); } else { rate_ef_desired = smoothing_gain*angle_to_target; } _rate_ef_desired.x = constrain_float(rate_ef_desired, _rate_ef_desired.x-rate_change_limit, _rate_ef_desired.x+rate_change_limit); // update earth-frame roll angle target using desired roll rate _angle_ef_target.x += _rate_ef_desired.x*_dt; // calculate earth-frame feed forward pitch rate using linear response when close to the target, sqrt response when we're further away angle_to_target = pitch_angle_ef - _angle_ef_target.y; if (angle_to_target > linear_angle){ rate_ef_desired = safe_sqrt(2.0f*_accel_rp_max*(fabs(angle_to_target)-(linear_angle/2.0f))); } else if (angle_to_target < -linear_angle){ rate_ef_desired = -safe_sqrt(2.0f*_accel_rp_max*(fabs(angle_to_target)-(linear_angle/2.0f))); } else { rate_ef_desired = smoothing_gain*angle_to_target; } _rate_ef_desired.y = constrain_float(rate_ef_desired, _rate_ef_desired.y-rate_change_limit, _rate_ef_desired.y+rate_change_limit); // update earth-frame pitch angle target using desired pitch rate _angle_ef_target.y += _rate_ef_desired.y*_dt; // set earth-frame feed forward rate for yaw rate_change_limit = _accel_y_max * _dt; float rate_change = yaw_rate_ef - _rate_ef_desired.z; rate_change = constrain_float(rate_change, -rate_change_limit, rate_change_limit); _rate_ef_desired.z += rate_change; // calculate yaw target angle and angle error update_ef_yaw_angle_and_error(_rate_ef_desired.z, angle_ef_error); // convert earth-frame angle errors to body-frame angle errors frame_conversion_ef_to_bf(angle_ef_error, _angle_bf_error); // convert earth-frame feed forward rates to body-frame feed forward rates frame_conversion_ef_to_bf(_rate_ef_desired, _rate_bf_desired); // convert body-frame angle errors to body-frame rate targets update_rate_bf_targets(); // add body frame rate feed forward _rate_bf_target += _rate_bf_desired; // body-frame to motor outputs should be called separately } // // methods to be called by upper controllers to request and implement a desired attitude // // angle_ef_roll_pitch_rate_ef_yaw - attempts to maintain a roll and pitch angle and yaw rate (all earth frame) void AC_AttitudeControl::angle_ef_roll_pitch_rate_ef_yaw(float roll_angle_ef, float pitch_angle_ef, float yaw_rate_ef) { Vector3f angle_ef_error; // earth frame angle errors // set earth-frame angle targets for roll and pitch and calculate angle error _angle_ef_target.x = roll_angle_ef; angle_ef_error.x = wrap_180_cd_float(_angle_ef_target.x - _ahrs.roll_sensor); _angle_ef_target.y = pitch_angle_ef; angle_ef_error.y = wrap_180_cd_float(_angle_ef_target.y - _ahrs.pitch_sensor); // set earth-frame feed forward rate for yaw float rate_change_limit = _accel_y_max * _dt; float rate_change = yaw_rate_ef - _rate_ef_desired.z; rate_change = constrain_float(rate_change, -rate_change_limit, rate_change_limit); _rate_ef_desired.z += rate_change; update_ef_yaw_angle_and_error(_rate_ef_desired.z, angle_ef_error); // convert earth-frame angle errors to body-frame angle errors frame_conversion_ef_to_bf(angle_ef_error, _angle_bf_error); // convert earth-frame feed forward rates to body-frame feed forward rates frame_conversion_ef_to_bf(_rate_ef_desired, _rate_bf_desired); // convert body-frame angle errors to body-frame rate targets update_rate_bf_targets(); // add body frame rate feed forward _rate_bf_target += _rate_bf_desired; // body-frame to motor outputs should be called separately } // angle_ef_roll_pitch_yaw - attempts to maintain a roll, pitch and yaw angle (all earth frame) // if yaw_slew is true then target yaw movement will be gradually moved to the new target based on the SLEW_YAW parameter void AC_AttitudeControl::angle_ef_roll_pitch_yaw(float roll_angle_ef, float pitch_angle_ef, float yaw_angle_ef, bool slew_yaw) { Vector3f angle_ef_error; // set earth-frame angle targets _angle_ef_target.x = roll_angle_ef; _angle_ef_target.y = pitch_angle_ef; _angle_ef_target.z = yaw_angle_ef; // calculate earth frame errors angle_ef_error.x = wrap_180_cd_float(_angle_ef_target.x - _ahrs.roll_sensor); angle_ef_error.y = wrap_180_cd_float(_angle_ef_target.y - _ahrs.pitch_sensor); angle_ef_error.z = wrap_180_cd_float(_angle_ef_target.z - _ahrs.yaw_sensor); // constrain the yaw angle error if (slew_yaw) { angle_ef_error.z = constrain_float(angle_ef_error.z,-_slew_yaw,_slew_yaw); } // convert earth-frame angle errors to body-frame angle errors frame_conversion_ef_to_bf(angle_ef_error, _angle_bf_error); // convert body-frame angle errors to body-frame rate targets update_rate_bf_targets(); // body-frame to motor outputs should be called separately } // rate_ef_roll_pitch_yaw - attempts to maintain a roll, pitch and yaw rate (all earth frame) void AC_AttitudeControl::rate_ef_roll_pitch_yaw(float roll_rate_ef, float pitch_rate_ef, float yaw_rate_ef) { Vector3f angle_ef_error; float rate_change_limit = _accel_rp_max * _dt; // update feed forward roll rate after checking it is within acceleration limits float rate_change = roll_rate_ef - _rate_ef_desired.x; rate_change = constrain_float(rate_change, -rate_change_limit, rate_change_limit); _rate_ef_desired.x += rate_change; // update feed forward pitch rate after checking it is within acceleration limits rate_change = pitch_rate_ef - _rate_ef_desired.y; rate_change = constrain_float(rate_change, -rate_change_limit, rate_change_limit); _rate_ef_desired.y += rate_change; // update feed forward yaw rate after checking it is within acceleration limits rate_change_limit = _accel_y_max * _dt; rate_change = yaw_rate_ef - _rate_ef_desired.z; rate_change = constrain_float(rate_change, -rate_change_limit, rate_change_limit); _rate_ef_desired.z += rate_change; // update earth frame angle targets and errors update_ef_roll_angle_and_error(_rate_ef_desired.x, angle_ef_error); update_ef_pitch_angle_and_error(_rate_ef_desired.y, angle_ef_error); update_ef_yaw_angle_and_error(_rate_ef_desired.z, angle_ef_error); // convert earth-frame angle errors to body-frame angle errors frame_conversion_ef_to_bf(angle_ef_error, _angle_bf_error); // convert earth-frame rates to body-frame rates frame_conversion_ef_to_bf(_rate_ef_desired, _rate_bf_desired); // convert body-frame angle errors to body-frame rate targets update_rate_bf_targets(); // add body frame rate feed forward _rate_bf_target += _rate_bf_desired; // body-frame to motor outputs should be called separately } // rate_bf_roll_pitch_yaw - attempts to maintain a roll, pitch and yaw rate (all body frame) void AC_AttitudeControl::rate_bf_roll_pitch_yaw(float roll_rate_bf, float pitch_rate_bf, float yaw_rate_bf) { Vector3f angle_ef_error; // Update angle error if (labs(_ahrs.pitch_sensor)<_acro_angle_switch){ _acro_angle_switch = 6000; // convert body-frame rates to earth-frame rates frame_conversion_bf_to_ef(_rate_bf_desired, _rate_ef_desired); // update earth frame angle targets and errors update_ef_roll_angle_and_error(_rate_ef_desired.x, angle_ef_error); update_ef_pitch_angle_and_error(_rate_ef_desired.y, angle_ef_error); update_ef_yaw_angle_and_error(_rate_ef_desired.z, angle_ef_error); // convert earth-frame angle errors to body-frame angle errors frame_conversion_ef_to_bf(angle_ef_error, _angle_bf_error); } else { _acro_angle_switch = 4500; integrate_bf_rate_error_to_angle_errors(); frame_conversion_bf_to_ef(_angle_bf_error, angle_ef_error); _angle_ef_target.x = wrap_180_cd_float(angle_ef_error.x + _ahrs.roll_sensor); _angle_ef_target.y = wrap_180_cd_float(angle_ef_error.y + _ahrs.pitch_sensor); _angle_ef_target.z = wrap_360_cd_float(angle_ef_error.z + _ahrs.yaw_sensor); if (_angle_ef_target.y>9000){ _angle_ef_target.x = wrap_180_cd_float(_angle_ef_target.x + 18000); _angle_ef_target.y = wrap_180_cd_float(18000-_angle_ef_target.x); _angle_ef_target.z = wrap_360_cd_float(_angle_ef_target.z + 18000); } if (_angle_ef_target.y<-9000){ _angle_ef_target.x = wrap_180_cd_float(_angle_ef_target.x + 18000); _angle_ef_target.y = wrap_180_cd_float(-18000-_angle_ef_target.x); _angle_ef_target.z = wrap_360_cd_float(_angle_ef_target.z + 18000); } } // convert body-frame angle errors to body-frame rate targets update_rate_bf_targets(); float rate_change, rate_change_limit; // update the rate feed forward with angular acceleration limits rate_change_limit = _accel_rp_max * _dt; rate_change = roll_rate_bf - _rate_bf_desired.x; rate_change = constrain_float(rate_change, -rate_change_limit, rate_change_limit); _rate_bf_desired.x += rate_change; rate_change = pitch_rate_bf - _rate_bf_desired.y; rate_change = constrain_float(rate_change, -rate_change_limit, rate_change_limit); _rate_bf_desired.y += rate_change; rate_change_limit = _accel_y_max * _dt; rate_change = yaw_rate_bf - _rate_bf_desired.z; rate_change = constrain_float(rate_change, -rate_change_limit, rate_change_limit); _rate_bf_desired.z += rate_change; // body-frame rate commands added _rate_bf_target += _rate_bf_desired; // body-frame to motor outputs should be called separately } // // rate_controller_run - run lowest level body-frame rate controller and send outputs to the motors // should be called at 100hz or more // void AC_AttitudeControl::rate_controller_run() { // call rate controllers and send output to motors object // To-Do: should the outputs from get_rate_roll, pitch, yaw be int16_t which is the input to the motors library? // To-Do: skip this step if the throttle out is zero? _motors.set_roll(rate_bf_to_motor_roll(_rate_bf_target.x)); _motors.set_pitch(rate_bf_to_motor_pitch(_rate_bf_target.y)); _motors.set_yaw(rate_bf_to_motor_yaw(_rate_bf_target.z)); } // // earth-frame <-> body-frame conversion functions // // frame_conversion_ef_to_bf - converts earth frame vector to body frame vector void AC_AttitudeControl::frame_conversion_ef_to_bf(const Vector3f& ef_vector, Vector3f& bf_vector) { // convert earth frame rates to body frame rates bf_vector.x = ef_vector.x - _ahrs.sin_pitch() * ef_vector.z; bf_vector.y = _ahrs.cos_roll() * ef_vector.y + _ahrs.sin_roll() * _ahrs.cos_pitch() * ef_vector.z; bf_vector.z = -_ahrs.sin_roll() * ef_vector.y + _ahrs.cos_pitch() * _ahrs.cos_roll() * ef_vector.z; } // frame_conversion_bf_to_ef - converts body frame vector to earth frame vector void AC_AttitudeControl::frame_conversion_bf_to_ef(const Vector3f& bf_vector, Vector3f& ef_vector) { // convert earth frame rates to body frame rates ef_vector.x = bf_vector.x + _ahrs.sin_roll() * (_ahrs.sin_pitch()/_ahrs.cos_pitch()) * bf_vector.y + _ahrs.cos_roll() * (_ahrs.sin_pitch()/_ahrs.cos_pitch()) * bf_vector.z; ef_vector.y = _ahrs.cos_roll() * bf_vector.y - _ahrs.sin_roll() * bf_vector.z; ef_vector.z = (_ahrs.sin_roll() / _ahrs.cos_pitch()) * bf_vector.y + (_ahrs.cos_roll() / _ahrs.cos_pitch()) * bf_vector.z; } // // protected methods // // // stabilized rate controller (body-frame) methods // // update_ef_roll_angle_and_error - update _angle_ef_target.x using an earth frame roll rate request void AC_AttitudeControl::update_ef_roll_angle_and_error(float roll_rate_ef, Vector3f &angle_ef_error) { // calculate angle error with maximum of +- max angle overshoot angle_ef_error.x = wrap_180_cd(_angle_ef_target.x - _ahrs.roll_sensor); angle_ef_error.x = constrain_float(angle_ef_error.x, -AC_ATTITUDE_RATE_STAB_ROLL_OVERSHOOT_ANGLE_MAX, AC_ATTITUDE_RATE_STAB_ROLL_OVERSHOOT_ANGLE_MAX); // To-Do: handle check for traditional heli's motors.motor_runup_complete // update roll angle target to be within max angle overshoot of our roll angle _angle_ef_target.x = angle_ef_error.x + _ahrs.roll_sensor; // increment the roll angle target _angle_ef_target.x += roll_rate_ef * _dt; _angle_ef_target.x = wrap_180_cd(_angle_ef_target.x); } // update_ef_pitch_angle_and_error - update _angle_ef_target.y using an earth frame pitch rate request void AC_AttitudeControl::update_ef_pitch_angle_and_error(float pitch_rate_ef, Vector3f &angle_ef_error) { // calculate angle error with maximum of +- max angle overshoot // To-Do: should we do something better as we cross 90 degrees? angle_ef_error.y = wrap_180_cd(_angle_ef_target.y - _ahrs.pitch_sensor); angle_ef_error.y = constrain_float(angle_ef_error.y, -AC_ATTITUDE_RATE_STAB_PITCH_OVERSHOOT_ANGLE_MAX, AC_ATTITUDE_RATE_STAB_PITCH_OVERSHOOT_ANGLE_MAX); // To-Do: handle check for traditional heli's motors.motor_runup_complete // update pitch angle target to be within max angle overshoot of our pitch angle _angle_ef_target.y = angle_ef_error.y + _ahrs.pitch_sensor; // increment the pitch angle target _angle_ef_target.y += pitch_rate_ef * _dt; _angle_ef_target.y = wrap_180_cd(_angle_ef_target.y); } // update_ef_yaw_angle_and_error - update _angle_ef_target.z using an earth frame yaw rate request void AC_AttitudeControl::update_ef_yaw_angle_and_error(float yaw_rate_ef, Vector3f &angle_ef_error) { // calculate angle error with maximum of +- max angle overshoot angle_ef_error.z = wrap_180_cd(_angle_ef_target.z - _ahrs.yaw_sensor); angle_ef_error.z = constrain_float(angle_ef_error.z, -AC_ATTITUDE_RATE_STAB_YAW_OVERSHOOT_ANGLE_MAX, AC_ATTITUDE_RATE_STAB_YAW_OVERSHOOT_ANGLE_MAX); // update yaw angle target to be within max angle overshoot of our current heading _angle_ef_target.z = angle_ef_error.z + _ahrs.yaw_sensor; // increment the yaw angle target _angle_ef_target.z += yaw_rate_ef * _dt; _angle_ef_target.z = wrap_360_cd(_angle_ef_target.z); } // update_rate_bf_errors - calculates body frame angle errors // body-frame feed forward rates (centi-degrees / second) taken from _angle_bf_error // angle errors in centi-degrees placed in _angle_bf_error void AC_AttitudeControl::integrate_bf_rate_error_to_angle_errors() { // roll - calculate body-frame angle error by integrating body-frame rate error _angle_bf_error.x += (_rate_bf_desired.x - (_ins.get_gyro().x * AC_ATTITUDE_CONTROL_DEGX100)) * _dt; // roll - limit maximum error _angle_bf_error.x = constrain_float(_angle_bf_error.x, -AC_ATTITUDE_RATE_STAB_ROLL_OVERSHOOT_ANGLE_MAX, AC_ATTITUDE_RATE_STAB_ROLL_OVERSHOOT_ANGLE_MAX); // pitch - calculate body-frame angle error by integrating body-frame rate error _angle_bf_error.y += (_rate_bf_desired.y - (_ins.get_gyro().y * AC_ATTITUDE_CONTROL_DEGX100)) * _dt; // pitch - limit maximum error _angle_bf_error.y = constrain_float(_angle_bf_error.y, -AC_ATTITUDE_RATE_STAB_PITCH_OVERSHOOT_ANGLE_MAX, AC_ATTITUDE_RATE_STAB_PITCH_OVERSHOOT_ANGLE_MAX); // yaw - calculate body-frame angle error by integrating body-frame rate error _angle_bf_error.z += (_rate_bf_desired.z - (_ins.get_gyro().z * AC_ATTITUDE_CONTROL_DEGX100)) * _dt; // yaw - limit maximum error _angle_bf_error.z = constrain_float(_angle_bf_error.z, -AC_ATTITUDE_RATE_STAB_YAW_OVERSHOOT_ANGLE_MAX, AC_ATTITUDE_RATE_STAB_YAW_OVERSHOOT_ANGLE_MAX); // To-Do: handle case of motors being disarmed or g.rc_3.servo_out == 0 and set error to zero } // update_rate_bf_targets - converts body-frame angle error to body-frame rate targets for roll, pitch and yaw axis // targets rates in centi-degrees taken from _angle_bf_error // results in centi-degrees/sec put into _rate_bf_target void AC_AttitudeControl::update_rate_bf_targets() { // stab roll calculation _rate_bf_target.x = _p_angle_roll.kP() * _angle_bf_error.x; // constrain roll rate request if (_flags.limit_angle_to_rate_request) { _rate_bf_target.x = constrain_float(_rate_bf_target.x,-_angle_rate_rp_max,_angle_rate_rp_max); } // stab pitch calculation _rate_bf_target.y = _p_angle_pitch.kP() * _angle_bf_error.y; // constrain pitch rate request if (_flags.limit_angle_to_rate_request) { _rate_bf_target.y = constrain_float(_rate_bf_target.y,-_angle_rate_rp_max,_angle_rate_rp_max); } // stab yaw calculation _rate_bf_target.z = _p_angle_yaw.kP() * _angle_bf_error.z; // constrain yaw rate request if (_flags.limit_angle_to_rate_request) { _rate_bf_target.z = constrain_float(_rate_bf_target.z,-_angle_rate_y_max,_angle_rate_y_max); } } // // body-frame rate controller // // rate_bf_to_motor_roll - ask the rate controller to calculate the motor outputs to achieve the target rate in centi-degrees / second float AC_AttitudeControl::rate_bf_to_motor_roll(float rate_target_cds) { float p,i,d; // used to capture pid values for logging float current_rate; // this iteration's rate float rate_error; // simply target_rate - current_rate // get current rate // To-Do: make getting gyro rates more efficient? current_rate = (_ins.get_gyro().x * AC_ATTITUDE_CONTROL_DEGX100); // calculate error and call pid controller rate_error = rate_target_cds - current_rate; p = _pid_rate_roll.get_p(rate_error); // get i term i = _pid_rate_roll.get_integrator(); // update i term as long as we haven't breached the limits or the I term will certainly reduce if (!_motors.limit.roll_pitch || ((i>0&&rate_error<0)||(i<0&&rate_error>0))) { i = _pid_rate_roll.get_i(rate_error, _dt); } // get d term d = _pid_rate_roll.get_d(rate_error, _dt); // constrain output and return return constrain_float((p+i+d), -AC_ATTITUDE_RATE_RP_CONTROLLER_OUT_MAX, AC_ATTITUDE_RATE_RP_CONTROLLER_OUT_MAX); // To-Do: allow logging of PIDs? } // rate_bf_to_motor_pitch - ask the rate controller to calculate the motor outputs to achieve the target rate in centi-degrees / second float AC_AttitudeControl::rate_bf_to_motor_pitch(float rate_target_cds) { float p,i,d; // used to capture pid values for logging float current_rate; // this iteration's rate float rate_error; // simply target_rate - current_rate // get current rate // To-Do: make getting gyro rates more efficient? current_rate = (_ins.get_gyro().y * AC_ATTITUDE_CONTROL_DEGX100); // calculate error and call pid controller rate_error = rate_target_cds - current_rate; p = _pid_rate_pitch.get_p(rate_error); // get i term i = _pid_rate_pitch.get_integrator(); // update i term as long as we haven't breached the limits or the I term will certainly reduce if (!_motors.limit.roll_pitch || ((i>0&&rate_error<0)||(i<0&&rate_error>0))) { i = _pid_rate_pitch.get_i(rate_error, _dt); } // get d term d = _pid_rate_pitch.get_d(rate_error, _dt); // constrain output and return return constrain_float((p+i+d), -AC_ATTITUDE_RATE_RP_CONTROLLER_OUT_MAX, AC_ATTITUDE_RATE_RP_CONTROLLER_OUT_MAX); // To-Do: allow logging of PIDs? } // rate_bf_to_motor_yaw - ask the rate controller to calculate the motor outputs to achieve the target rate in centi-degrees / second float AC_AttitudeControl::rate_bf_to_motor_yaw(float rate_target_cds) { float p,i,d; // used to capture pid values for logging float current_rate; // this iteration's rate float rate_error; // simply target_rate - current_rate // get current rate // To-Do: make getting gyro rates more efficient? current_rate = (_ins.get_gyro().z * AC_ATTITUDE_CONTROL_DEGX100); // calculate error and call pid controller rate_error = rate_target_cds - current_rate; p = _pid_rate_yaw.get_p(rate_error); // separately calculate p, i, d values for logging p = _pid_rate_yaw.get_p(rate_error); // get i term i = _pid_rate_yaw.get_integrator(); // update i term as long as we haven't breached the limits or the I term will certainly reduce if (!_motors.limit.yaw || ((i>0&&rate_error<0)||(i<0&&rate_error>0))) { i = _pid_rate_yaw.get_i(rate_error, _dt); } // get d value d = _pid_rate_yaw.get_d(rate_error, _dt); // constrain output and return return constrain_float((p+i+d), -AC_ATTITUDE_RATE_YAW_CONTROLLER_OUT_MAX, AC_ATTITUDE_RATE_YAW_CONTROLLER_OUT_MAX); // To-Do: allow logging of PIDs? } // // throttle functions // // set_throttle_out - to be called by upper throttle controllers when they wish to provide throttle output directly to motors // provide 0 to cut motors void AC_AttitudeControl::set_throttle_out(int16_t throttle_out, bool apply_angle_boost) { if (apply_angle_boost) { _motors.set_throttle(get_angle_boost(throttle_out)); }else{ _motors.set_throttle(throttle_out); // clear angle_boost for logging purposes _angle_boost = 0; } // update compass with throttle value // To-Do: find another method to grab the throttle out and feed to the compass. Could be done completely outside this class //compass.set_throttle((float)g.rc_3.servo_out/1000.0f); } // get_angle_boost - returns a throttle including compensation for roll/pitch angle // throttle value should be 0 ~ 1000 int16_t AC_AttitudeControl::get_angle_boost(int16_t throttle_pwm) { float temp = _ahrs.cos_pitch() * _ahrs.cos_roll(); int16_t throttle_out; temp = constrain_float(temp, 0.5f, 1.0f); // reduce throttle if we go inverted temp = constrain_float(9000-max(labs(_ahrs.roll_sensor),labs(_ahrs.pitch_sensor)), 0, 3000) / (3000 * temp); // apply scale and constrain throttle // To-Do: move throttle_min and throttle_max into the AP_Vehicles class? throttle_out = constrain_float((float)(throttle_pwm-_motors.throttle_min()) * temp + _motors.throttle_min(), _motors.throttle_min(), 1000); // record angle boost for logging _angle_boost = throttle_out - throttle_pwm; return throttle_out; }