/* 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 . */ #include "AR_PosControl.h" #include #include #include #include #include #include extern const AP_HAL::HAL& hal; #define AR_POSCON_TIMEOUT_MS 100 // timeout after 0.1 sec #define AR_POSCON_POS_P 0.2f // default position P gain #define AR_POSCON_VEL_P 1.0f // default velocity P gain #define AR_POSCON_VEL_I 0.0f // default velocity I gain #define AR_POSCON_VEL_D 0.0f // default velocity D gain #define AR_POSCON_VEL_FF 0.0f // default velocity FF gain #define AR_POSCON_VEL_IMAX 1.0f // default velocity IMAX #define AR_POSCON_VEL_FILT 5.0f // default velocity filter #define AR_POSCON_VEL_FILT_D 5.0f // default velocity D term filter #define AR_POSCON_DT 0.02f // default dt for PID controllers const AP_Param::GroupInfo AR_PosControl::var_info[] = { // @Param: _POS_P // @DisplayName: Position controller P gain // @Description: Position controller P gain. Converts the distance to the target location into a desired speed which is then passed to the loiter latitude rate controller // @Range: 0.500 2.000 // @User: Standard AP_SUBGROUPINFO(_p_pos, "_POS_", 1, AR_PosControl, AC_P_2D), // @Param: _VEL_P // @DisplayName: Velocity (horizontal) P gain // @Description: Velocity (horizontal) P gain. Converts the difference between desired and actual velocity to a target acceleration // @Range: 0.1 6.0 // @Increment: 0.1 // @User: Advanced // @Param: _VEL_I // @DisplayName: Velocity (horizontal) I gain // @Description: Velocity (horizontal) I gain. Corrects long-term difference between desired and actual velocity to a target acceleration // @Range: 0.02 1.00 // @Increment: 0.01 // @User: Advanced // @Param: _VEL_D // @DisplayName: Velocity (horizontal) D gain // @Description: Velocity (horizontal) D gain. Corrects short-term changes in velocity // @Range: 0.00 1.00 // @Increment: 0.001 // @User: Advanced // @Param: _VEL_IMAX // @DisplayName: Velocity (horizontal) integrator maximum // @Description: Velocity (horizontal) integrator maximum. Constrains the target acceleration that the I gain will output // @Range: 0 4500 // @Increment: 10 // @Units: cm/s/s // @User: Advanced // @Param: _VEL_FLTE // @DisplayName: Velocity (horizontal) input filter // @Description: Velocity (horizontal) input filter. This filter (in Hz) is applied to the input for P and I terms // @Range: 0 100 // @Units: Hz // @User: Advanced // @Param: _VEL_FLTD // @DisplayName: Velocity (horizontal) input filter // @Description: Velocity (horizontal) input filter. This filter (in Hz) is applied to the input for D term // @Range: 0 100 // @Units: Hz // @User: Advanced // @Param: _VEL_FF // @DisplayName: Velocity (horizontal) feed forward gain // @Description: Velocity (horizontal) feed forward gain. Converts the difference between desired velocity to a target acceleration // @Range: 0 6 // @Increment: 0.01 // @User: Advanced AP_SUBGROUPINFO(_pid_vel, "_VEL_", 2, AR_PosControl, AC_PID_2D), AP_GROUPEND }; AR_PosControl::AR_PosControl(AR_AttitudeControl& atc) : _atc(atc), _p_pos(AR_POSCON_POS_P), _pid_vel(AR_POSCON_VEL_P, AR_POSCON_VEL_I, AR_POSCON_VEL_D, AR_POSCON_VEL_FF, AR_POSCON_VEL_IMAX, AR_POSCON_VEL_FILT, AR_POSCON_VEL_FILT_D) { AP_Param::setup_object_defaults(this, var_info); } // update navigation void AR_PosControl::update(float dt) { // exit immediately if no current location, destination or disarmed Vector2f curr_pos_NE; Vector3f curr_vel_NED; if (!hal.util->get_soft_armed() || !AP::ahrs().get_relative_position_NE_origin(curr_pos_NE) || !AP::ahrs().get_velocity_NED(curr_vel_NED)) { _desired_speed = _atc.get_desired_speed_accel_limited(0.0f, dt); _desired_lat_accel = 0.0f; _desired_turn_rate_rads = 0.0f; return; } // check for ekf xy position reset handle_ekf_xy_reset(); // if no recent calls reset velocity controller if (!is_active()) { _pid_vel.reset_I(); _pid_vel.reset_filter(); } _last_update_ms = AP_HAL::millis(); // calculate position error and convert to desired velocity _vel_target.zero(); if (_pos_target_valid) { Vector2p pos_target = _pos_target; _vel_target = _p_pos.update_all(pos_target.x, pos_target.y, curr_pos_NE); } // calculation velocity error if (_vel_desired_valid) { // add target velocity to desired velocity from position error _vel_target += _vel_desired; } // limit velocity to maximum speed _vel_target.limit_length(get_speed_max()); // Limit the velocity to prevent fence violations bool backing_up = false; AC_Avoid *avoid = AP::ac_avoid(); if (avoid != nullptr) { Vector3f vel_3d_cms{_vel_target.x * 100.0f, _vel_target.y * 100.0f, 0.0f}; const float accel_max_cmss = MIN(_accel_max, _lat_accel_max) * 100.0; avoid->adjust_velocity(vel_3d_cms, backing_up, _p_pos.kP(), accel_max_cmss, _p_pos.kP(), accel_max_cmss, dt); _vel_target.x = vel_3d_cms.x * 0.01; _vel_target.y = vel_3d_cms.y * 0.01; } // calculate desired acceleration // To-Do: fixup _limit_vel used below _accel_target = _pid_vel.update_all(_vel_target, curr_vel_NED.xy(), dt, _limit_vel); if (_accel_desired_valid) { _accel_target += _accel_desired; } // convert desired acceleration to desired forward-back speed, desired lateral speed and desired turn rate // rotate acceleration into body frame using current heading const Vector2f accel_target_FR = AP::ahrs().earth_to_body2D(_accel_target); // calculate minimum turn speed which is the max speed the vehicle could turn through the corner // given the vehicle's turn radius and half its max lateral acceleration // todo: remove MAX of zero when safe_sqrt fixed float turn_speed_min = MAX(safe_sqrt(_atc.get_turn_lat_accel_max() * 0.5 * _turn_radius), 0); // rotate target velocity from earth-frame to body frame const Vector2f vel_target_FR = AP::ahrs().earth_to_body2D(_vel_target); // desired speed is normally the forward component (only) of the target velocity // but we do not let it fall below the minimum turn speed unless the vehicle is slowing down const float abs_des_speed_min = MIN(_vel_target.length(), turn_speed_min); float des_speed; if (_reversed != backing_up) { // if reversed or backing up desired speed will be negative des_speed = MIN(-abs_des_speed_min, vel_target_FR.x); } else { des_speed = MAX(abs_des_speed_min, vel_target_FR.x); } _desired_speed = _atc.get_desired_speed_accel_limited(des_speed, dt); // calculate turn rate from desired lateral acceleration _desired_lat_accel = accel_target_FR.y; _desired_turn_rate_rads = _atc.get_turn_rate_from_lat_accel(_desired_lat_accel, _desired_speed); } // true if update has been called recently bool AR_PosControl::is_active() const { return ((AP_HAL::millis() - _last_update_ms) < AR_POSCON_TIMEOUT_MS); } // set limits void AR_PosControl::set_limits(float speed_max, float accel_max, float lat_accel_max, float jerk_max) { _speed_max = MAX(speed_max, 0); _accel_max = MAX(accel_max, 0); _lat_accel_max = MAX(lat_accel_max, 0); _jerk_max = MAX(jerk_max, 0); // set position P controller limits _p_pos.set_limits(_speed_max, MIN(_accel_max, _lat_accel_max), _jerk_max); } // setter to allow vehicle code to provide turn related param values to this library (should be updated regularly) void AR_PosControl::set_turn_params(float turn_radius, bool pivot_possible) { if (pivot_possible) { _turn_radius = 0; } else { _turn_radius = turn_radius; } } // initialise the position controller to the current position, velocity, acceleration and attitude // this should be called before the input shaping methods are used bool AR_PosControl::init() { // get current position and velocity from AHRS Vector2f pos_NE; Vector3f vel_NED; if (!AP::ahrs().get_relative_position_NE_origin(pos_NE) || !AP::ahrs().get_velocity_NED(vel_NED)) { return false; } // set target position to current position _pos_target.x = pos_NE.x; _pos_target.y = pos_NE.y; // set target velocity and acceleration _vel_desired = vel_NED.xy(); _vel_target.zero(); _accel_desired = AP::ahrs().get_accel_ef().xy(); _accel_target.zero(); // clear reversed setting _reversed = false; // initialise ekf xy reset handler init_ekf_xy_reset(); return true; } // adjust position, velocity and acceleration targets smoothly using input shaping // pos is the target position as an offset from the EKF origin (in meters) // vel is the target velocity in m/s. accel is the target acceleration in m/s/s // dt should be the update rate in seconds // init should be called once before starting to use these methods void AR_PosControl::input_pos_target(const Vector2p &pos, float dt) { Vector2f vel; Vector2f accel; input_pos_vel_accel_target(pos, vel, accel, dt); } // adjust position, velocity and acceleration targets smoothly using input shaping // pos is the target position as an offset from the EKF origin (in meters) // vel is the target velocity in m/s. accel is the target acceleration in m/s/s // dt should be the update rate in seconds // init should be called once before starting to use these methods void AR_PosControl::input_pos_vel_target(const Vector2p &pos, const Vector2f &vel, float dt) { Vector2f accel; input_pos_vel_accel_target(pos, vel, accel, dt); } // adjust position, velocity and acceleration targets smoothly using input shaping // pos is the target position as an offset from the EKF origin (in meters) // vel is the target velocity in m/s. accel is the target acceleration in m/s/s // dt should be the update rate in seconds // init should be called once before starting to use these methods void AR_PosControl::input_pos_vel_accel_target(const Vector2p &pos, const Vector2f &vel, const Vector2f &accel, float dt) { // adjust target position, velocity and acceleration forward by dt update_pos_vel_accel_xy(_pos_target, _vel_desired, _accel_desired, dt, Vector2f(), Vector2f(), Vector2f()); // call shape_pos_vel_accel_xy to pull target towards final destination const float accel_max = MIN(_accel_max, _lat_accel_max); shape_pos_vel_accel_xy(pos, vel, accel, _pos_target, _vel_desired, _accel_desired, _speed_max, accel_max, _jerk_max, dt, false); // set flags so update will consume target position, desired velocity and desired acceleration _pos_target_valid = true; _vel_desired_valid = true; _accel_desired_valid = true; } // set target position, desired velocity and acceleration. These should be from an externally created path and are not "input shaped" void AR_PosControl::set_pos_vel_accel_target(const Vector2p &pos, const Vector2f &vel, const Vector2f &accel) { _pos_target = pos; _vel_desired = vel; _accel_desired = accel; _pos_target_valid = true; _vel_desired_valid = true; _accel_desired_valid = true; } // returns desired velocity vector (i.e. feed forward) in cm/s in lat and lon direction Vector2f AR_PosControl::get_desired_velocity() const { if (_vel_desired_valid) { return _vel_desired; } return Vector2f(); } // return desired acceleration vector in m/s in lat and lon direction Vector2f AR_PosControl::get_desired_accel() const { if (_accel_desired_valid) { return _accel_desired; } return Vector2f(); } /// get position error as a vector from the current position to the target position Vector2p AR_PosControl::get_pos_error() const { // return zero error is not active or no position estimate Vector2f curr_pos_NE; if (!is_active() ||!AP::ahrs().get_relative_position_NE_origin(curr_pos_NE)) { return Vector2p{}; } // get current position return (_pos_target - curr_pos_NE.topostype()); } // write PSC logs void AR_PosControl::write_log() { // exit immediately if not active if (!is_active()) { return; } // exit immediately if no position or velocity estimate Vector3f curr_pos_NED; Vector3f curr_vel_NED; if (!AP::ahrs().get_relative_position_NED_origin(curr_pos_NED) || !AP::ahrs().get_velocity_NED(curr_vel_NED)) { return; } // get acceleration const Vector3f curr_accel_NED = AP::ahrs().get_accel_ef() * 100.0; // convert position to required format Vector2f pos_target_2d_cm = get_pos_target().tofloat() * 100.0; AP::logger().Write_PSCN(pos_target_2d_cm.x, // position target curr_pos_NED.x * 100.0, // position _vel_desired.x * 100.0, // desired velocity _vel_target.x * 100.0, // target velocity curr_vel_NED.x * 100.0, // velocity _accel_desired.x * 100.0, // desired accel _accel_target.x * 100.0, // target accel curr_accel_NED.x); // accel AP::logger().Write_PSCE(pos_target_2d_cm.y, // position target curr_pos_NED.y * 100.0, // position _vel_desired.y * 100.0, // desired velocity _vel_target.y * 100.0, // target velocity curr_vel_NED.y * 100.0, // velocity _accel_desired.y * 100.0, // desired accel _accel_target.y * 100.0, // target accel curr_accel_NED.y); // accel } /// initialise ekf xy position reset check void AR_PosControl::init_ekf_xy_reset() { Vector2f pos_shift; _ekf_xy_reset_ms = AP::ahrs().getLastPosNorthEastReset(pos_shift); } /// handle_ekf_xy_reset - check for ekf position reset and adjust loiter or brake target position void AR_PosControl::handle_ekf_xy_reset() { // check for position shift Vector2f pos_shift; uint32_t reset_ms = AP::ahrs().getLastPosNorthEastReset(pos_shift); if (reset_ms != _ekf_xy_reset_ms) { Vector2f pos_NE; if (!AP::ahrs().get_relative_position_NE_origin(pos_NE)) { return; } _pos_target = (pos_NE + _p_pos.get_error()).topostype(); Vector3f vel_NED; if (!AP::ahrs().get_velocity_NED(vel_NED)) { return; } _vel_desired = vel_NED.xy() + _pid_vel.get_error(); _ekf_xy_reset_ms = reset_ms; } }