mirror of https://github.com/ArduPilot/ardupilot
330 lines
11 KiB
C++
330 lines
11 KiB
C++
/*
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* This program is free software: you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation, either version 3 of the License, or
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* (at your option) any later version.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program. If not, see <http://www.gnu.org/licenses/>.
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*/
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#include <stdlib.h>
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#include <AP_HAL/AP_HAL.h>
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#include <GCS_MAVLink/GCS.h>
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#include "AP_MotorsHeli_Quad.h"
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extern const AP_HAL::HAL& hal;
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const AP_Param::GroupInfo AP_MotorsHeli_Quad::var_info[] = {
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AP_NESTEDGROUPINFO(AP_MotorsHeli, 0),
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// Indices 1-3 were used by RSC_PWM_MIN, RSC_PWM_MAX and RSC_PWM_REV and should not be used
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AP_GROUPEND
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};
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#define QUAD_SERVO_MAX_ANGLE 4500
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// set update rate to motors - a value in hertz
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void AP_MotorsHeli_Quad::set_update_rate( uint16_t speed_hz )
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{
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// record requested speed
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_speed_hz = speed_hz;
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// setup fast channels
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uint32_t mask = 0;
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for (uint8_t i=0; i<AP_MOTORS_HELI_QUAD_NUM_MOTORS; i++) {
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mask |= 1U << (AP_MOTORS_MOT_1+i);
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}
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rc_set_freq(mask, _speed_hz);
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}
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// init_outputs
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bool AP_MotorsHeli_Quad::init_outputs()
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{
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if (_flags.initialised_ok) {
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return true;
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}
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for (uint8_t i=0; i<AP_MOTORS_HELI_QUAD_NUM_MOTORS; i++) {
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add_motor_num(CH_1+i);
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SRV_Channels::set_angle(SRV_Channels::get_motor_function(i), QUAD_SERVO_MAX_ANGLE);
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}
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// set rotor servo range
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_main_rotor.init_servo();
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_flags.initialised_ok = true;
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return true;
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}
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// output_test_seq - spin a motor at the pwm value specified
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// motor_seq is the motor's sequence number from 1 to the number of motors on the frame
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// pwm value is an actual pwm value that will be output, normally in the range of 1000 ~ 2000
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void AP_MotorsHeli_Quad::output_test_seq(uint8_t motor_seq, int16_t pwm)
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{
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// exit immediately if not armed
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if (!armed()) {
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return;
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}
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// output to motors and servos
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switch (motor_seq) {
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case 1 ... AP_MOTORS_HELI_QUAD_NUM_MOTORS:
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rc_write(AP_MOTORS_MOT_1 + (motor_seq-1), pwm);
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break;
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case AP_MOTORS_HELI_QUAD_NUM_MOTORS+1:
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// main rotor
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rc_write(AP_MOTORS_HELI_RSC, pwm);
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break;
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default:
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// do nothing
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break;
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}
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}
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// set_desired_rotor_speed
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void AP_MotorsHeli_Quad::set_desired_rotor_speed(float desired_speed)
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{
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_main_rotor.set_desired_speed(desired_speed);
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}
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// set_rotor_rpm - used for governor with speed sensor
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void AP_MotorsHeli_Quad::set_rpm(float rotor_rpm)
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{
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_main_rotor.set_rotor_rpm(rotor_rpm);
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}
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// calculate_armed_scalars
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void AP_MotorsHeli_Quad::calculate_armed_scalars()
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{
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// Set rsc mode specific parameters
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if (_main_rotor._rsc_mode.get() == ROTOR_CONTROL_MODE_OPEN_LOOP_POWER_OUTPUT || _main_rotor._rsc_mode.get() == ROTOR_CONTROL_MODE_CLOSED_LOOP_POWER_OUTPUT) {
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_main_rotor.set_throttle_curve();
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}
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// keeps user from changing RSC mode while armed
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if (_main_rotor._rsc_mode.get() != _main_rotor.get_control_mode()) {
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_main_rotor.reset_rsc_mode_param();
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gcs().send_text(MAV_SEVERITY_CRITICAL, "RSC control mode change failed");
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_heliflags.save_rsc_mode = true;
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}
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// saves rsc mode parameter when disarmed if it had been reset while armed
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if (_heliflags.save_rsc_mode && !_flags.armed) {
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_main_rotor._rsc_mode.save();
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_heliflags.save_rsc_mode = false;
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}
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// set bailout ramp time
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_main_rotor.use_bailout_ramp_time(_heliflags.enable_bailout);
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}
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// calculate_scalars
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void AP_MotorsHeli_Quad::calculate_scalars()
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{
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// range check collective min, max and mid
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if( _collective_min >= _collective_max ) {
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_collective_min = AP_MOTORS_HELI_COLLECTIVE_MIN;
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_collective_max = AP_MOTORS_HELI_COLLECTIVE_MAX;
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}
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_collective_mid = constrain_int16(_collective_mid, _collective_min, _collective_max);
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// calculate collective mid point as a number from 0 to 1000
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_collective_mid_pct = ((float)(_collective_mid-_collective_min))/((float)(_collective_max-_collective_min));
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// calculate factors based on swash type and servo position
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calculate_roll_pitch_collective_factors();
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// set mode of main rotor controller and trigger recalculation of scalars
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_main_rotor.set_control_mode(static_cast<RotorControlMode>(_main_rotor._rsc_mode.get()));
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calculate_armed_scalars();
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}
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// calculate_swash_factors - calculate factors based on swash type and servo position
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void AP_MotorsHeli_Quad::calculate_roll_pitch_collective_factors()
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{
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// assume X quad layout, with motors at 45, 135, 225 and 315 degrees
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// order FrontRight, RearLeft, FrontLeft, RearLeft
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const float angles[AP_MOTORS_HELI_QUAD_NUM_MOTORS] = { 45, 225, 315, 135 };
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const bool x_clockwise[AP_MOTORS_HELI_QUAD_NUM_MOTORS] = { false, false, true, true };
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const float cos45 = cosf(radians(45));
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for (uint8_t i=0; i<AP_MOTORS_HELI_QUAD_NUM_MOTORS; i++) {
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bool clockwise = x_clockwise[i];
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if (_frame_type == MOTOR_FRAME_TYPE_H) {
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// reverse yaw for H frame
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clockwise = !clockwise;
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}
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_rollFactor[CH_1+i] = -0.25*sinf(radians(angles[i]))/cos45;
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_pitchFactor[CH_1+i] = 0.25*cosf(radians(angles[i]))/cos45;
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_yawFactor[CH_1+i] = clockwise?-0.25:0.25;
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_collectiveFactor[CH_1+i] = 1;
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}
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}
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// get_motor_mask - returns a bitmask of which outputs are being used for motors or servos (1 means being used)
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// this can be used to ensure other pwm outputs (i.e. for servos) do not conflict
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uint16_t AP_MotorsHeli_Quad::get_motor_mask()
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{
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uint16_t mask = 0;
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for (uint8_t i=0; i<AP_MOTORS_HELI_QUAD_NUM_MOTORS; i++) {
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mask |= 1U << (AP_MOTORS_MOT_1+i);
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}
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mask |= 1U << AP_MOTORS_HELI_RSC;
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return mask;
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}
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// update_motor_controls - sends commands to motor controllers
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void AP_MotorsHeli_Quad::update_motor_control(RotorControlState state)
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{
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// Send state update to motors
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_main_rotor.output(state);
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if (state == ROTOR_CONTROL_STOP) {
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// set engine run enable aux output to not run position to kill engine when disarmed
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SRV_Channels::set_output_limit(SRV_Channel::k_engine_run_enable, SRV_Channel::SRV_CHANNEL_LIMIT_MIN);
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} else {
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// else if armed, set engine run enable output to run position
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SRV_Channels::set_output_limit(SRV_Channel::k_engine_run_enable, SRV_Channel::SRV_CHANNEL_LIMIT_MAX);
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}
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// Check if rotors are run-up
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_heliflags.rotor_runup_complete = _main_rotor.is_runup_complete();
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}
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//
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// move_actuators - moves swash plate to attitude of parameters passed in
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// - expected ranges:
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// roll : -1 ~ +1
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// pitch: -1 ~ +1
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// collective: 0 ~ 1
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// yaw: -1 ~ +1
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//
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void AP_MotorsHeli_Quad::move_actuators(float roll_out, float pitch_out, float collective_in, float yaw_out)
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{
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// initialize limits flag
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limit.roll = false;
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limit.pitch = false;
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limit.yaw = false;
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limit.throttle_lower = false;
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limit.throttle_upper = false;
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// constrain collective input
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float collective_out = collective_in;
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if (collective_out <= 0.0f) {
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collective_out = 0.0f;
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limit.throttle_lower = true;
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}
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if (collective_out >= 1.0f) {
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collective_out = 1.0f;
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limit.throttle_upper = true;
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}
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// ensure not below landed/landing collective
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if (_heliflags.landing_collective && collective_out < _collective_mid_pct) {
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collective_out = _collective_mid_pct;
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limit.throttle_lower = true;
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}
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float collective_range = (_collective_max - _collective_min) * 0.001f;
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if (_heliflags.inverted_flight) {
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collective_out = 1.0f - collective_out;
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}
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// feed power estimate into main rotor controller
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_main_rotor.set_collective(fabsf(collective_out));
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// rescale collective for overhead calc
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collective_out -= _collective_mid_pct;
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// reserve some collective for attitude control
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collective_out *= collective_range;
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for (uint8_t i=0; i<AP_MOTORS_HELI_QUAD_NUM_MOTORS; i++) {
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_out[i] =
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_rollFactor[CH_1+i] * roll_out +
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_pitchFactor[CH_1+i] * pitch_out +
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_collectiveFactor[CH_1+i] * collective_out;
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}
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// see if we need to scale down yaw_out
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for (uint8_t i=0; i<AP_MOTORS_HELI_QUAD_NUM_MOTORS; i++) {
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float y = _yawFactor[CH_1+i] * yaw_out;
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if (_out[i] < 0.0f) {
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// the slope of the yaw effect changes at zero collective
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y = -y;
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}
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if (_out[i] * (_out[i] + y) < 0.0f) {
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// applying this yaw demand would change the sign of the
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// collective, which means the yaw would not be applied
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// evenly. We scale down the overall yaw demand to prevent
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// it crossing over zero
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float s = -(_out[i] / y);
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yaw_out *= s;
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}
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}
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// now apply the yaw correction
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for (uint8_t i=0; i<AP_MOTORS_HELI_QUAD_NUM_MOTORS; i++) {
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float y = _yawFactor[CH_1+i] * yaw_out;
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if (_out[i] < 0.0f) {
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// the slope of the yaw effect changes at zero collective
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y = -y;
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}
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_out[i] += y;
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}
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for (uint8_t i=0; i<AP_MOTORS_HELI_QUAD_NUM_MOTORS; i++) {
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// scale output to 0 to 1
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_out[i] += _collective_mid_pct;
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// scale output to -1 to 1 for servo output
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_out[i] = _out[i] * 2.0f - 1.0f;
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}
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}
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void AP_MotorsHeli_Quad::output_to_motors()
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{
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if (!_flags.initialised_ok) {
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return;
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}
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// move the servos
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for (uint8_t i=0; i<AP_MOTORS_HELI_QUAD_NUM_MOTORS; i++) {
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rc_write_angle(AP_MOTORS_MOT_1+i, _out[i] * QUAD_SERVO_MAX_ANGLE);
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}
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switch (_spool_state) {
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case SpoolState::SHUT_DOWN:
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// sends minimum values out to the motors
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update_motor_control(ROTOR_CONTROL_STOP);
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break;
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case SpoolState::GROUND_IDLE:
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// sends idle output to motors when armed. rotor could be static or turning (autorotation)
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update_motor_control(ROTOR_CONTROL_IDLE);
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break;
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case SpoolState::SPOOLING_UP:
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case SpoolState::THROTTLE_UNLIMITED:
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// set motor output based on thrust requests
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update_motor_control(ROTOR_CONTROL_ACTIVE);
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break;
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case SpoolState::SPOOLING_DOWN:
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// sends idle output to motors and wait for rotor to stop
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update_motor_control(ROTOR_CONTROL_IDLE);
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break;
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}
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}
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// servo_test - move servos through full range of movement
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void AP_MotorsHeli_Quad::servo_test()
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{
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// not implemented
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}
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