mirror of https://github.com/ArduPilot/ardupilot
193 lines
7.7 KiB
C++
193 lines
7.7 KiB
C++
// -*- tab-width: 4; Mode: C++; c-basic-offset: 4; indent-tabs-mode: t -*-
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#include <APM_RC.h>
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#include "RC_Channel_aux.h"
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const AP_Param::GroupInfo RC_Channel_aux::var_info[] PROGMEM = {
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AP_NESTEDGROUPINFO(RC_Channel, 0),
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// @Param: FUNCTION
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// @DisplayName: Servo out function
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// @Description: Setting this to Disabled(0) will disable this output, any other value will enable the corresponding function
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// @Values: 0:Disabled,1:Manual,2:Flap,3:Flap_auto,4:Aileron,5:flaperon,6:mount_pan,7:mount_pitch,8:mount_roll,9:mount_open,10:camera_trigger,11:release
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// @User: Standard
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AP_GROUPINFO("FUNCTION", 1, RC_Channel_aux, function),
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// @Param: ANGLE_MIN
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// @DisplayName: Minimum object position
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// @Description: Minimum physical angular position of the object that this servo output controls. For example a camera pan angle, an aileron angle, etc
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// @Units: centi-Degrees
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// @Range: -18000 17999
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// @Increment: 1
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// @User: Standard
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AP_GROUPINFO("ANGLE_MIN", 2, RC_Channel_aux, angle_min),
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// @Param: ANGLE_MAX
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// @DisplayName: Maximum object position
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// @Description: Maximum physical angular position of the object that this servo output controls. For example a camera pan angle, an aileron angle, etc
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// @Units: centi-Degrees
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// @Range: -18000 17999
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// @Increment: 1
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// @User: Standard
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AP_GROUPINFO("ANGLE_MAX", 3, RC_Channel_aux, angle_max),
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AP_GROUPEND
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};
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/// Global pointer array, indexed by a "RC function enum" and points to the RC channel output assigned to that function/operation
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RC_Channel_aux* g_rc_function[RC_Channel_aux::k_nr_aux_servo_functions];
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/// saturate to the closest angle limit if outside of [min max] angle interval
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/// input angle is in degrees * 10
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int16_t
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RC_Channel_aux::closest_limit(int16_t angle)
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{
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// Change scaling to 0.1 degrees in order to avoid overflows in the angle arithmetic
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int16_t min = angle_min / 10;
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int16_t max = angle_max / 10;
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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 (min < -1800) min += 3600;
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while (min >= 1800) min -= 3600;
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while (max < -1800) max += 3600;
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while (max >= 1800) max -= 3600;
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// This is done every time because the user might change the min, max values on the fly
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set_range(min, max);
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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 < min) && (angle > max)){
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// angle error if min limit is used
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int16_t err_min = min - 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 - max + (angle>max?0:3600); // add 360 degrees if on the "wrong side"
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angle = err_min<err_max?min:max;
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}
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servo_out = angle;
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// convert angle to PWM using a linear transformation (ignores trimming because the servo limits might not be symmetric)
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calc_pwm();
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return angle;
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}
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/// Gets the RC and integrates and then compares with the servo out angles to limit control input to servo travel.
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/// That way the user doesn't get lost. Rotationally.
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void
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RC_Channel_aux::rc_input(float *control_angle, int16_t angle)
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{
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if((radio_in < 1480 && angle < angle_max)||(radio_in > 1520 && angle > angle_min)){
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*control_angle += ( 1500 - radio_in ) * .0001; // .0001 is the control speed scaler.
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}
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}
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/// returns the angle (degrees*100) that the RC_Channel input is receiving
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int32_t
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RC_Channel_aux::angle_input()
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{
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return (get_reverse()?-1:1) * (radio_in - radio_min) * (int32_t)(angle_max - angle_min) / (radio_max - radio_min) + (get_reverse()?angle_max:angle_min);
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}
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/// returns the angle (radians) that the RC_Channel input is receiving
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float
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RC_Channel_aux::angle_input_rad()
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{
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return radians(angle_input()*0.01);
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}
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/// enable_out_ch - enable the channel through APM_RC
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void
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RC_Channel_aux::enable_out_ch(unsigned char ch_nr)
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{
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// enable_out this channel if it assigned to a function
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if( function != k_none ) {
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_apm_rc->enable_out(ch_nr);
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}
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}
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/// map a function to a servo channel and output it
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void
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RC_Channel_aux::output_ch(unsigned char ch_nr)
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{
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// take care or two corner cases
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switch(function)
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{
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case k_none: // disabled
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return;
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break;
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case k_manual: // manual
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radio_out = radio_in;
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break;
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}
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_apm_rc->OutputCh(ch_nr, radio_out);
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}
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/// Update the g_rc_function array of pointers to rc_x channels
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/// This is to be done before rc_init so that the channels get correctly initialized.
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/// It also should be called periodically because the user might change the configuration and
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/// expects the changes to take effect instantly
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/// Supports up to seven aux servo outputs (typically CH5 ... CH11)
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/// All servos must be configured with a single call to this function
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void update_aux_servo_function( RC_Channel_aux* rc_a,
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RC_Channel_aux* rc_b,
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RC_Channel_aux* rc_c,
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RC_Channel_aux* rc_d,
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RC_Channel_aux* rc_e,
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RC_Channel_aux* rc_f,
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RC_Channel_aux* rc_g)
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{
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RC_Channel_aux::Aux_servo_function_t aux_servo_function[7];
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aux_servo_function[0] = (rc_a == NULL)?RC_Channel_aux::k_none:(RC_Channel_aux::Aux_servo_function_t)rc_a->function.get();
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aux_servo_function[1] = (rc_b == NULL)?RC_Channel_aux::k_none:(RC_Channel_aux::Aux_servo_function_t)rc_b->function.get();
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aux_servo_function[2] = (rc_c == NULL)?RC_Channel_aux::k_none:(RC_Channel_aux::Aux_servo_function_t)rc_c->function.get();
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aux_servo_function[3] = (rc_d == NULL)?RC_Channel_aux::k_none:(RC_Channel_aux::Aux_servo_function_t)rc_d->function.get();
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aux_servo_function[4] = (rc_e == NULL)?RC_Channel_aux::k_none:(RC_Channel_aux::Aux_servo_function_t)rc_e->function.get();
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aux_servo_function[5] = (rc_f == NULL)?RC_Channel_aux::k_none:(RC_Channel_aux::Aux_servo_function_t)rc_f->function.get();
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aux_servo_function[6] = (rc_g == NULL)?RC_Channel_aux::k_none:(RC_Channel_aux::Aux_servo_function_t)rc_g->function.get();
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for (uint8_t i = 0; i < 7; i++) {
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if (aux_servo_function[i] >= RC_Channel_aux::k_nr_aux_servo_functions) {
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// invalid setting
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aux_servo_function[i] = RC_Channel_aux::k_none;
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}
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}
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// Assume that no auxiliary function is used
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for (uint8_t i = 0; i < RC_Channel_aux::k_nr_aux_servo_functions ; i++)
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{
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g_rc_function[i] = NULL;
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}
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// assign the RC channel to each function
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if( rc_a != NULL ) { g_rc_function[aux_servo_function[0]] = rc_a; }
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if( rc_b != NULL ) { g_rc_function[aux_servo_function[1]] = rc_b; }
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if( rc_c != NULL ) { g_rc_function[aux_servo_function[2]] = rc_c; }
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if( rc_d != NULL ) { g_rc_function[aux_servo_function[3]] = rc_d; }
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if( rc_e != NULL ) { g_rc_function[aux_servo_function[3]] = rc_e; }
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if( rc_f != NULL ) { g_rc_function[aux_servo_function[3]] = rc_f; }
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if( rc_g != NULL ) { g_rc_function[aux_servo_function[3]] = rc_g; }
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//set auxiliary ranges
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G_RC_AUX(k_flap)->set_range(0,100);
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G_RC_AUX(k_flap_auto)->set_range(0,100);
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G_RC_AUX(k_aileron)->set_angle(4500);
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G_RC_AUX(k_flaperon)->set_range(0,100);
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G_RC_AUX(k_mount_yaw)->set_range(
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g_rc_function[RC_Channel_aux::k_mount_yaw]->angle_min / 10,
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g_rc_function[RC_Channel_aux::k_mount_yaw]->angle_max / 10);
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G_RC_AUX(k_mount_pitch)->set_range(
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g_rc_function[RC_Channel_aux::k_mount_pitch]->angle_min / 10,
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g_rc_function[RC_Channel_aux::k_mount_pitch]->angle_max / 10);
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G_RC_AUX(k_mount_roll)->set_range(
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g_rc_function[RC_Channel_aux::k_mount_roll]->angle_min / 10,
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g_rc_function[RC_Channel_aux::k_mount_roll]->angle_max / 10);
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G_RC_AUX(k_mount_open)->set_range(0,100);
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G_RC_AUX(k_cam_trigger)->set_range(
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g_rc_function[RC_Channel_aux::k_cam_trigger]->angle_min / 10,
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g_rc_function[RC_Channel_aux::k_cam_trigger]->angle_max / 10);
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G_RC_AUX(k_egg_drop)->set_range(0,100);
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}
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