mirror of https://github.com/ArduPilot/ardupilot
213 lines
9.0 KiB
C++
213 lines
9.0 KiB
C++
#include "AP_Mount_Servo.h"
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#if HAL_MOUNT_SERVO_ENABLED
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extern const AP_HAL::HAL& hal;
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// init - performs any required initialisation for this instance
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void AP_Mount_Servo::init()
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{
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if (_instance == 0) {
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_roll_idx = SRV_Channel::k_mount_roll;
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_tilt_idx = SRV_Channel::k_mount_tilt;
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_pan_idx = SRV_Channel::k_mount_pan;
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_open_idx = SRV_Channel::k_mount_open;
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} else {
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// this must be the 2nd mount
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_roll_idx = SRV_Channel::k_mount2_roll;
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_tilt_idx = SRV_Channel::k_mount2_tilt;
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_pan_idx = SRV_Channel::k_mount2_pan;
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_open_idx = SRV_Channel::k_mount2_open;
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}
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}
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// update mount position - should be called periodically
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void AP_Mount_Servo::update()
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{
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switch (get_mode()) {
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// move mount to a "retracted position" or to a position where a fourth servo can retract the entire mount into the fuselage
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case MAV_MOUNT_MODE_RETRACT: {
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_angle_bf_output_deg = _state._retract_angles.get();
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// initialise _angle_rad to smooth transition if user changes to RC_TARGETTING
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_angle_rad.roll = radians(_angle_bf_output_deg.x);
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_angle_rad.pitch = radians(_angle_bf_output_deg.y);
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_angle_rad.yaw = radians(_angle_bf_output_deg.z);
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_angle_rad.yaw_is_ef = false;
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break;
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}
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// move mount to a neutral position, typically pointing forward
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case MAV_MOUNT_MODE_NEUTRAL: {
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_angle_bf_output_deg = _state._neutral_angles.get();
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// initialise _angle_rad to smooth transition if user changes to RC_TARGETTING
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_angle_rad.roll = radians(_angle_bf_output_deg.x);
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_angle_rad.pitch = radians(_angle_bf_output_deg.y);
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_angle_rad.yaw = radians(_angle_bf_output_deg.z);
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_angle_rad.yaw_is_ef = false;
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break;
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}
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// point to the angles given by a mavlink message
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case MAV_MOUNT_MODE_MAVLINK_TARGETING: {
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switch (mavt_target.target_type) {
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case MountTargetType::ANGLE:
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_angle_rad = mavt_target.angle_rad;
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break;
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case MountTargetType::RATE:
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update_angle_target_from_rate(mavt_target.rate_rads, _angle_rad);
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break;
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}
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// update _angle_bf_output_deg based on angle target
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update_angle_outputs(_angle_rad);
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break;
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}
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// RC radio manual angle control, but with stabilization from the AHRS
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case MAV_MOUNT_MODE_RC_TARGETING: {
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// update targets using pilot's RC inputs
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MountTarget rc_target {};
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if (get_rc_rate_target(rc_target)) {
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update_angle_target_from_rate(rc_target, _angle_rad);
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} else if (get_rc_angle_target(rc_target)) {
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_angle_rad = rc_target;
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}
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// update _angle_bf_output_deg based on angle target
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update_angle_outputs(_angle_rad);
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break;
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}
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// point mount to a GPS location
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case MAV_MOUNT_MODE_GPS_POINT: {
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if (get_angle_target_to_roi(_angle_rad)) {
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update_angle_outputs(_angle_rad);
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}
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break;
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}
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case MAV_MOUNT_MODE_HOME_LOCATION: {
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if (get_angle_target_to_home(_angle_rad)) {
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update_angle_outputs(_angle_rad);
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}
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break;
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}
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case MAV_MOUNT_MODE_SYSID_TARGET: {
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if (get_angle_target_to_sysid(_angle_rad)) {
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update_angle_outputs(_angle_rad);
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}
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break;
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}
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default:
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//do nothing
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break;
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}
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// move mount to a "retracted position" into the fuselage with a fourth servo
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const bool mount_open = (get_mode() == MAV_MOUNT_MODE_RETRACT) ? 0 : 1;
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move_servo(_open_idx, mount_open, 0, 1);
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// write the results to the servos
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move_servo(_roll_idx, _angle_bf_output_deg.x*10, _state._roll_angle_min*0.1f, _state._roll_angle_max*0.1f);
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move_servo(_tilt_idx, _angle_bf_output_deg.y*10, _state._tilt_angle_min*0.1f, _state._tilt_angle_max*0.1f);
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move_servo(_pan_idx, _angle_bf_output_deg.z*10, _state._pan_angle_min*0.1f, _state._pan_angle_max*0.1f);
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}
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// returns true if this mount can control its pan (required for multicopters)
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bool AP_Mount_Servo::has_pan_control() const
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{
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return SRV_Channels::function_assigned(_pan_idx);
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}
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// private methods
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// send_mount_status - called to allow mounts to send their status to GCS using the MOUNT_STATUS message
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void AP_Mount_Servo::send_mount_status(mavlink_channel_t chan)
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{
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mavlink_msg_mount_status_send(chan, 0, 0, _angle_bf_output_deg.y*100, _angle_bf_output_deg.x*100, _angle_bf_output_deg.z*100, _mode);
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}
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// update body-frame angle outputs from earth-frame angle targets
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void AP_Mount_Servo::update_angle_outputs(const MountTarget& angle_rad)
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{
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const AP_AHRS &ahrs = AP::ahrs();
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// only do the full 3D frame transform if we are stabilising yaw
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if (_state._stab_pan) {
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Matrix3f m; // 3 x 3 rotation matrix used as temporary variable in calculations
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Matrix3f ef_to_cam; // rotation matrix from earth-frame to camera. Desired camera from input.
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Matrix3f gimbal_target_bf; // rotation matrix from vehicle to camera then Euler angles to the servos
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Vector3f gimbal_angle_bf_rad; // gimbal angle targets in body-frame euler angles
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m = ahrs.get_rotation_body_to_ned();
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m.transpose();
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ef_to_cam.from_euler(angle_rad.roll, angle_rad.pitch, get_ef_yaw_angle(angle_rad));
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gimbal_target_bf = m * ef_to_cam;
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gimbal_target_bf.to_euler(&gimbal_angle_bf_rad.x, &gimbal_angle_bf_rad.y, &gimbal_angle_bf_rad.z);
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_angle_bf_output_deg.x = _state._stab_roll ? degrees(gimbal_angle_bf_rad.x) : degrees(angle_rad.roll);
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_angle_bf_output_deg.y = _state._stab_tilt ? degrees(gimbal_angle_bf_rad.y) : degrees(angle_rad.pitch);
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_angle_bf_output_deg.z = degrees(gimbal_angle_bf_rad.z);
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} else {
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// otherwise base roll and pitch on the ahrs roll and pitch angle plus any requested angle
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_angle_bf_output_deg.x = degrees(angle_rad.roll);
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_angle_bf_output_deg.y = degrees(angle_rad.pitch);
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_angle_bf_output_deg.z = degrees(get_bf_yaw_angle(angle_rad));
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if (_state._stab_roll) {
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_angle_bf_output_deg.x -= degrees(ahrs.roll);
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}
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if (_state._stab_tilt) {
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_angle_bf_output_deg.y -= degrees(ahrs.pitch);
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}
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// lead filter
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const Vector3f &gyro = ahrs.get_gyro();
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if (_state._stab_roll && !is_zero(_state._roll_stb_lead) && fabsf(ahrs.pitch) < M_PI/3.0f) {
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// Compute rate of change of euler roll angle
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float roll_rate = gyro.x + (ahrs.sin_pitch() / ahrs.cos_pitch()) * (gyro.y * ahrs.sin_roll() + gyro.z * ahrs.cos_roll());
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_angle_bf_output_deg.x -= degrees(roll_rate) * _state._roll_stb_lead;
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}
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if (_state._stab_tilt && !is_zero(_state._pitch_stb_lead)) {
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// Compute rate of change of euler pitch angle
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float pitch_rate = ahrs.cos_pitch() * gyro.y - ahrs.sin_roll() * gyro.z;
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_angle_bf_output_deg.y -= degrees(pitch_rate) * _state._pitch_stb_lead;
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}
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}
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}
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// closest_limit - returns closest angle to 'angle' taking into account limits. all angles are in degrees * 10
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int16_t AP_Mount_Servo::closest_limit(int16_t angle, int16_t angle_min, int16_t angle_max)
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{
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// Make sure the angle lies in the interval [-180 .. 180[ degrees
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while (angle < -1800) angle += 3600;
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while (angle >= 1800) angle -= 3600;
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// Make sure the angle limits lie in the interval [-180 .. 180[ degrees
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while (angle_min < -1800) angle_min += 3600;
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while (angle_min >= 1800) angle_min -= 3600;
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while (angle_max < -1800) angle_max += 3600;
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while (angle_max >= 1800) angle_max -= 3600;
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// If the angle is outside servo limits, saturate the angle to the closest limit
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// On a circle the closest angular position must be carefully calculated to account for wrap-around
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if ((angle < angle_min) && (angle > angle_max)) {
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// angle error if min limit is used
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int16_t err_min = angle_min - angle + (angle<angle_min ? 0 : 3600); // add 360 degrees if on the "wrong side"
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// angle error if max limit is used
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int16_t err_max = angle - angle_max + (angle>angle_max ? 0 : 3600); // add 360 degrees if on the "wrong side"
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angle = err_min<err_max ? angle_min : angle_max;
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}
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return angle;
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}
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// move_servo - moves servo with the given id to the specified angle. all angles are in degrees * 10
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void AP_Mount_Servo::move_servo(uint8_t function_idx, int16_t angle, int16_t angle_min, int16_t angle_max)
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{
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// saturate to the closest angle limit if outside of [min max] angle interval
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int16_t servo_out = closest_limit(angle, angle_min, angle_max);
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SRV_Channels::move_servo((SRV_Channel::Aux_servo_function_t)function_idx, servo_out, angle_min, angle_max);
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}
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#endif // HAL_MOUNT_SERVO_ENABLED
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