mirror of https://github.com/ArduPilot/ardupilot
549 lines
18 KiB
C++
549 lines
18 KiB
C++
/*
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AP_MotorsHeli.cpp - ArduCopter motors library
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Code by RandyMackay. DIYDrones.com
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This library is free software; you can redistribute it and/or
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modify it under the terms of the GNU Lesser General Public
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License as published by the Free Software Foundation; either
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version 2.1 of the License, or (at your option) any later version.
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*/
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#include "AP_MotorsHeli.h"
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const AP_Param::GroupInfo AP_MotorsHeli::var_info[] PROGMEM = {
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// @Param: SV1_POS
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// @DisplayName: Servo 1 Position
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// @Description: This is the angular location of swash servo #1.
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// @Range: -180 180
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// @Units: Degrees
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// @User: Standard
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// @Increment: 1
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AP_GROUPINFO("SV1_POS", 1, AP_MotorsHeli, servo1_pos),
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// @Param: SV2_POS
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// @DisplayName: Servo 2 Position
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// @Description: This is the angular location of swash servo #2.
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// @Range: -180 180
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// @Units: Degrees
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// @User: Standard
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// @Increment: 1
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AP_GROUPINFO("SV2_POS", 2, AP_MotorsHeli, servo2_pos),
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// @Param: SV3_POS
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// @DisplayName: Servo 3 Position
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// @Description: This is the angular location of swash servo #3.
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// @Range: -180 180
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// @Units: Degrees
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// @User: Standard
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// @Increment: 1
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AP_GROUPINFO("SV3_POS", 3, AP_MotorsHeli, servo3_pos),
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// @Param: ROL_MAX
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// @DisplayName: Maximum Roll Angle
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// @Description: This is the maximum allowable aircraft roll angle in Stabilize Mode.
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// @Range: 0 18000
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// @Units: Degrees
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// @Increment: 1
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// @User: Advanced
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AP_GROUPINFO("ROL_MAX", 4, AP_MotorsHeli, roll_max),
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// @Param: PIT_MAX
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// @DisplayName: Maximum Pitch Angle
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// @Description: This is the maximum allowable aircraft pitch angle in Stabilize Mode.
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// @Range: 0 18000
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// @Units: Degrees
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// @Increment: 1
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// @User: Advanced
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AP_GROUPINFO("PIT_MAX", 5, AP_MotorsHeli, pitch_max),
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// @Param: COL_MIN
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// @DisplayName: Collective Pitch Minimum
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// @Description: This controls the lowest possible servo position for the swashplate.
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// @Range: 1000 2000
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// @Units: PWM
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// @Increment: 1
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// @User: Standard
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AP_GROUPINFO("COL_MIN", 6, AP_MotorsHeli, collective_min),
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// @Param: COL_MAX
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// @DisplayName: Collective Pitch Maximum
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// @Description: This controls the highest possible servo position for the swashplate.
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// @Range: 1000 2000
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// @Units: PWM
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// @Increment: 1
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// @User: Standard
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AP_GROUPINFO("COL_MAX", 7, AP_MotorsHeli, collective_max),
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// @Param: COL_MID
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// @DisplayName: Collective Pitch Mid-Point
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// @Description: This is the swash servo position corresponding to zero collective pitch (or zero lift for Assymetrical blades).
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// @Range: 1000 2000
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// @Units: PWM
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// @Increment: 1
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// @User: Standard
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AP_GROUPINFO("COL_MID", 8, AP_MotorsHeli, collective_mid),
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// @Param: GYR_ENABLE
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// @DisplayName: External Gyro Enabled
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// @Description: Setting this to Enabled(1) will enable an external rudder gyro control. Setting this to Disabled(0) will disable the external gyro control and will revert to internal rudder control.
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// @Values: 0:Disabled,1:Enabled
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// @User: Standard
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AP_GROUPINFO("GYR_ENABLE", 9, AP_MotorsHeli, ext_gyro_enabled),
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// @Param: SWASH_TYPE
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// @DisplayName: Swash Plate Type
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// @Description: Setting this to 0 will configure for a 3-servo CCPM. Setting this to 1 will configure for mechanically mixed "H1".
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// @User: Standard
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AP_GROUPINFO("SWASH_TYPE", 10, AP_MotorsHeli, swash_type),
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// @Param: GYR_GAIM
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// @DisplayName: External Gyro Gain
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// @Description: This is the PWM which is passed to the external gyro when external gyro is enabled.
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// @Range: 1000 2000
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// @Units: PWM
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// @Increment: 1
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// @User: Standard
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AP_GROUPINFO("GYR_GAIN", 11, AP_MotorsHeli, ext_gyro_gain),
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// @Param: SV_MAN
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// @DisplayName: Manual Servo Mode
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// @Description: Setting this to Enabled(1) will pass radio inputs directly to servos. Setting this to Disabled(0) will enable Arducopter control of servos.
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// @Values: 0:Disabled,1:Enabled
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// @User: Standard
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AP_GROUPINFO("SV_MAN", 12, AP_MotorsHeli, servo_manual),
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// @Param: PHANG
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// @DisplayName: Swashplate Phase Angle Compensation
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// @Description: This corrects for phase angle errors of the helicopter main rotor head.
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// @Range: -90 90
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// @Units: Degrees
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// @User: Advanced
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// @Increment: 1
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AP_GROUPINFO("PHANG", 13, AP_MotorsHeli, phase_angle),
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// @Param: COLYAW
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// @DisplayName: Collective-Yaw Mixing
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// @Description: This is a feed-forward compensation to automatically add rudder input when collective pitch is increased.
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// @Range: 0 5
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AP_GROUPINFO("COLYAW", 14, AP_MotorsHeli, collective_yaw_effect),
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// @Param: GOV_SETPOINT
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// @DisplayName: External Motor Governor Setpoint
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// @Description: This is the PWM which is passed to the external motor governor when external governor is enabled.
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// @Range: 1000 2000
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// @Units: PWM
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// @Increment: 10
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// @User: Standard
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AP_GROUPINFO("GOV_SETPOINT", 15, AP_MotorsHeli, ext_gov_setpoint),
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AP_GROUPEND
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};
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// init
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void AP_MotorsHeli::Init()
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{
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// set update rate
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set_update_rate(_speed_hz);
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}
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// set update rate to motors - a value in hertz or AP_MOTORS_SPEED_INSTANT_PWM for instant pwm
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void AP_MotorsHeli::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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if( _speed_hz != AP_MOTORS_SPEED_INSTANT_PWM ) {
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_rc->SetFastOutputChannels(_BV(_motor_to_channel_map[AP_MOTORS_MOT_1]) | _BV(_motor_to_channel_map[AP_MOTORS_MOT_2]) | _BV(_motor_to_channel_map[AP_MOTORS_MOT_3]) | _BV(_motor_to_channel_map[AP_MOTORS_MOT_4]), _speed_hz);
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}
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}
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// enable - starts allowing signals to be sent to motors
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void AP_MotorsHeli::enable()
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{
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// enable output channels
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_rc->enable_out(_motor_to_channel_map[AP_MOTORS_MOT_1]); // swash servo 1
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_rc->enable_out(_motor_to_channel_map[AP_MOTORS_MOT_2]); // swash servo 2
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_rc->enable_out(_motor_to_channel_map[AP_MOTORS_MOT_3]); // swash servo 3
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_rc->enable_out(_motor_to_channel_map[AP_MOTORS_MOT_4]); // yaw
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_rc->enable_out(AP_MOTORS_HELI_EXT_GYRO); // for external gyro
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_rc->enable_out(AP_MOTORS_HELI_EXT_ESC); // for external ESC
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}
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// output_min - sends minimum values out to the motors
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void AP_MotorsHeli::output_min()
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{
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// move swash to mid
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move_swash(0,0,500,0);
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}
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// output_armed - sends commands to the motors
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void AP_MotorsHeli::output_armed()
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{
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// if manual override (i.e. when setting up swash), pass pilot commands straight through to swash
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if( servo_manual == 1 ) {
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_rc_roll->servo_out = _rc_roll->control_in;
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_rc_pitch->servo_out = _rc_pitch->control_in;
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_rc_throttle->servo_out = _rc_throttle->control_in;
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_rc_yaw->servo_out = _rc_yaw->control_in;
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}
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//static int counter = 0;
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_rc_roll->calc_pwm();
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_rc_pitch->calc_pwm();
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_rc_throttle->calc_pwm();
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_rc_yaw->calc_pwm();
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move_swash( _rc_roll->servo_out, _rc_pitch->servo_out, _rc_throttle->servo_out, _rc_yaw->servo_out );
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ext_esc_control();
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}
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// output_disarmed - sends commands to the motors
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void AP_MotorsHeli::output_disarmed()
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{
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if(_rc_throttle->control_in > 0){
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// we have pushed up the throttle
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// remove safety
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_auto_armed = true;
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}
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// for helis - armed or disarmed we allow servos to move
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output_armed();
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}
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// output_disarmed - sends commands to the motors
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void AP_MotorsHeli::output_test()
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{
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int16_t i;
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// Send minimum values to all motors
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output_min();
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// servo 1
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for( i=0; i<5; i++ ) {
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_rc->OutputCh(_motor_to_channel_map[AP_MOTORS_MOT_1], _servo_1->radio_trim + 100);
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delay(300);
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_rc->OutputCh(_motor_to_channel_map[AP_MOTORS_MOT_1], _servo_1->radio_trim - 100);
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delay(300);
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_rc->OutputCh(_motor_to_channel_map[AP_MOTORS_MOT_1], _servo_1->radio_trim + 0);
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delay(300);
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}
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// servo 2
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for( i=0; i<5; i++ ) {
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_rc->OutputCh(_motor_to_channel_map[AP_MOTORS_MOT_2], _servo_2->radio_trim + 100);
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delay(300);
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_rc->OutputCh(_motor_to_channel_map[AP_MOTORS_MOT_2], _servo_2->radio_trim - 100);
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delay(300);
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_rc->OutputCh(_motor_to_channel_map[AP_MOTORS_MOT_2], _servo_2->radio_trim + 0);
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delay(300);
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}
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// servo 3
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for( i=0; i<5; i++ ) {
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_rc->OutputCh(_motor_to_channel_map[AP_MOTORS_MOT_3], _servo_3->radio_trim + 100);
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delay(300);
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_rc->OutputCh(_motor_to_channel_map[AP_MOTORS_MOT_3], _servo_3->radio_trim - 100);
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delay(300);
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_rc->OutputCh(_motor_to_channel_map[AP_MOTORS_MOT_3], _servo_3->radio_trim + 0);
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delay(300);
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}
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// external gyro
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if( ext_gyro_enabled ) {
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_rc->OutputCh(AP_MOTORS_HELI_EXT_GYRO, ext_gyro_gain);
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}
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// servo 4
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for( i=0; i<5; i++ ) {
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_rc->OutputCh(_motor_to_channel_map[AP_MOTORS_MOT_4], _servo_4->radio_trim + 100);
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delay(300);
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_rc->OutputCh(_motor_to_channel_map[AP_MOTORS_MOT_4], _servo_4->radio_trim - 100);
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delay(300);
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_rc->OutputCh(_motor_to_channel_map[AP_MOTORS_MOT_4], _servo_4->radio_trim + 0);
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delay(300);
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}
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// Send minimum values to all motors
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output_min();
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}
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// reset_swash - free up swash for maximum movements. Used for set-up
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void AP_MotorsHeli::reset_swash()
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{
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// free up servo ranges
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_servo_1->radio_min = 1000;
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_servo_1->radio_max = 2000;
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_servo_2->radio_min = 1000;
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_servo_2->radio_max = 2000;
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_servo_3->radio_min = 1000;
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_servo_3->radio_max = 2000;
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if( swash_type == AP_MOTORS_HELI_SWASH_CCPM ) { //CCPM Swashplate, perform servo control mixing
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// roll factors
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_rollFactor[CH_1] = cos(radians(servo1_pos + 90 - phase_angle));
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_rollFactor[CH_2] = cos(radians(servo2_pos + 90 - phase_angle));
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_rollFactor[CH_3] = cos(radians(servo3_pos + 90 - phase_angle));
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// pitch factors
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_pitchFactor[CH_1] = cos(radians(servo1_pos - phase_angle));
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_pitchFactor[CH_2] = cos(radians(servo2_pos - phase_angle));
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_pitchFactor[CH_3] = cos(radians(servo3_pos - phase_angle));
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// collective factors
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_collectiveFactor[CH_1] = 1;
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_collectiveFactor[CH_2] = 1;
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_collectiveFactor[CH_3] = 1;
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}else{ //H1 Swashplate, keep servo outputs seperated
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// roll factors
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_rollFactor[CH_1] = 1;
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_rollFactor[CH_2] = 0;
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_rollFactor[CH_3] = 0;
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// pitch factors
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_pitchFactor[CH_1] = 0;
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_pitchFactor[CH_2] = 1;
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_pitchFactor[CH_3] = 0;
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// collective factors
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_collectiveFactor[CH_1] = 0;
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_collectiveFactor[CH_2] = 0;
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_collectiveFactor[CH_3] = 1;
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}
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// set roll, pitch and throttle scaling
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_roll_scaler = 1.0;
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_pitch_scaler = 1.0;
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_collective_scalar = ((float)(_rc_throttle->radio_max - _rc_throttle->radio_min))/1000.0;
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// we must be in set-up mode so mark swash as uninitialised
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_swash_initialised = false;
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}
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// init_swash - initialise the swash plate
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void AP_MotorsHeli::init_swash()
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{
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// swash servo initialisation
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_servo_1->set_range(0,1000);
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_servo_2->set_range(0,1000);
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_servo_3->set_range(0,1000);
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_servo_4->set_angle(4500);
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// ensure _coll values are reasonable
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if( collective_min >= collective_max ) {
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collective_min = 1000;
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collective_max = 2000;
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}
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collective_mid = constrain(collective_mid, collective_min, collective_max);
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// calculate throttle mid point
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throttle_mid = ((float)(collective_mid-collective_min))/((float)(collective_max-collective_min))*1000.0;
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// determine roll, pitch and throttle scaling
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_roll_scaler = (float)roll_max/4500.0;
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_pitch_scaler = (float)pitch_max/4500.0;
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_collective_scalar = ((float)(collective_max-collective_min))/1000.0;
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if( swash_type == AP_MOTORS_HELI_SWASH_CCPM ) { //CCPM Swashplate, perform control mixing
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// roll factors
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_rollFactor[CH_1] = cos(radians(servo1_pos + 90 - phase_angle));
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_rollFactor[CH_2] = cos(radians(servo2_pos + 90 - phase_angle));
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_rollFactor[CH_3] = cos(radians(servo3_pos + 90 - phase_angle));
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// pitch factors
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_pitchFactor[CH_1] = cos(radians(servo1_pos - phase_angle));
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_pitchFactor[CH_2] = cos(radians(servo2_pos - phase_angle));
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_pitchFactor[CH_3] = cos(radians(servo3_pos - phase_angle));
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// collective factors
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_collectiveFactor[CH_1] = 1;
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_collectiveFactor[CH_2] = 1;
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_collectiveFactor[CH_3] = 1;
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}else{ //H1 Swashplate, keep servo outputs seperated
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// roll factors
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_rollFactor[CH_1] = 1;
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_rollFactor[CH_2] = 0;
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_rollFactor[CH_3] = 0;
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// pitch factors
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_pitchFactor[CH_1] = 0;
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_pitchFactor[CH_2] = 1;
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_pitchFactor[CH_3] = 0;
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// collective factors
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_collectiveFactor[CH_1] = 0;
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_collectiveFactor[CH_2] = 0;
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_collectiveFactor[CH_3] = 1;
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}
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// servo min/max values
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_servo_1->radio_min = 1000;
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_servo_1->radio_max = 2000;
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_servo_2->radio_min = 1000;
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_servo_2->radio_max = 2000;
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_servo_3->radio_min = 1000;
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_servo_3->radio_max = 2000;
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// mark swash as initialised
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_swash_initialised = true;
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}
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//
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// heli_move_swash - moves swash plate to attitude of parameters passed in
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// - expected ranges:
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// roll : -4500 ~ 4500
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// pitch: -4500 ~ 4500
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// collective: 0 ~ 1000
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// yaw: -4500 ~ 4500
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//
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void AP_MotorsHeli::move_swash(int16_t roll_out, int16_t pitch_out, int16_t coll_out, int16_t yaw_out)
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{
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int16_t yaw_offset = 0;
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int16_t coll_out_scaled;
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if( servo_manual == 1 ) { // are we in manual servo mode? (i.e. swash set-up mode)?
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// check if we need to free up the swash
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if( _swash_initialised ) {
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reset_swash();
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}
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coll_out_scaled = coll_out * _collective_scalar + _rc_throttle->radio_min - 1000;
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}else{ // regular flight mode
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// check if we need to reinitialise the swash
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if( !_swash_initialised ) {
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init_swash();
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}
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// rescale roll_out and pitch-out into the min and max ranges to provide linear motion
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// across the input range instead of stopping when the input hits the constrain value
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// these calculations are based on an assumption of the user specified roll_max and pitch_max
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// coming into this equation at 4500 or less, and based on the original assumption of the
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// total _servo_x.servo_out range being -4500 to 4500.
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roll_out = roll_out * _roll_scaler;
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roll_out = constrain(roll_out, (int16_t)-roll_max, (int16_t)roll_max);
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pitch_out = pitch_out * _pitch_scaler;
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pitch_out = constrain(pitch_out, (int16_t)-pitch_max, (int16_t)pitch_max);
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// scale collective pitch
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coll_out = constrain(coll_out, 0, 1000);
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coll_out_scaled = coll_out * _collective_scalar + collective_min - 1000;
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// rudder feed forward based on collective
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if( !ext_gyro_enabled ) {
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yaw_offset = collective_yaw_effect * abs(coll_out_scaled - throttle_mid);
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}
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}
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// swashplate servos
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_servo_1->servo_out = (_rollFactor[CH_1] * roll_out + _pitchFactor[CH_1] * pitch_out)/10 + _collectiveFactor[CH_1] * coll_out_scaled + (_servo_1->radio_trim-1500);
|
|
_servo_2->servo_out = (_rollFactor[CH_2] * roll_out + _pitchFactor[CH_2] * pitch_out)/10 + _collectiveFactor[CH_2] * coll_out_scaled + (_servo_2->radio_trim-1500);
|
|
if( swash_type == AP_MOTORS_HELI_SWASH_H1 ) {
|
|
_servo_1->servo_out += 500;
|
|
_servo_2->servo_out += 500;
|
|
}
|
|
_servo_3->servo_out = (_rollFactor[CH_3] * roll_out + _pitchFactor[CH_3] * pitch_out)/10 + _collectiveFactor[CH_3] * coll_out_scaled + (_servo_3->radio_trim-1500);
|
|
_servo_4->servo_out = yaw_out + yaw_offset;
|
|
|
|
// use servo_out to calculate pwm_out and radio_out
|
|
_servo_1->calc_pwm();
|
|
_servo_2->calc_pwm();
|
|
_servo_3->calc_pwm();
|
|
_servo_4->calc_pwm();
|
|
|
|
// actually move the servos
|
|
_rc->OutputCh(_motor_to_channel_map[AP_MOTORS_MOT_1], _servo_1->radio_out);
|
|
_rc->OutputCh(_motor_to_channel_map[AP_MOTORS_MOT_2], _servo_2->radio_out);
|
|
_rc->OutputCh(_motor_to_channel_map[AP_MOTORS_MOT_3], _servo_3->radio_out);
|
|
_rc->OutputCh(_motor_to_channel_map[AP_MOTORS_MOT_4], _servo_4->radio_out);
|
|
|
|
// to be compatible with other frame types
|
|
motor_out[AP_MOTORS_MOT_1] = _servo_1->radio_out;
|
|
motor_out[AP_MOTORS_MOT_2] = _servo_2->radio_out;
|
|
motor_out[AP_MOTORS_MOT_3] = _servo_3->radio_out;
|
|
motor_out[AP_MOTORS_MOT_4] = _servo_4->radio_out;
|
|
|
|
// output gyro value
|
|
if( ext_gyro_enabled ) {
|
|
_rc->OutputCh(AP_MOTORS_HELI_EXT_GYRO, ext_gyro_gain);
|
|
}
|
|
|
|
// InstantPWM
|
|
if( _speed_hz == AP_MOTORS_SPEED_INSTANT_PWM ) {
|
|
_rc->Force_Out0_Out1();
|
|
_rc->Force_Out2_Out3();
|
|
}
|
|
}
|
|
|
|
void AP_MotorsHeli::ext_esc_control()
|
|
|
|
{
|
|
switch ( AP_MOTORS_ESC_MODE_PASSTHROUGH ) {
|
|
|
|
case AP_MOTORS_ESC_MODE_PASSTHROUGH:
|
|
if( armed() && _rc_8->control_in > 10 ){
|
|
if (ext_esc_ramp < AP_MOTORS_EXT_ESC_RAMP_UP){
|
|
ext_esc_ramp++;
|
|
ext_esc_output = map(ext_esc_ramp, 0, AP_MOTORS_EXT_ESC_RAMP_UP, 1000, _rc_8->control_in);
|
|
} else {
|
|
ext_esc_output = _rc_8->control_in;
|
|
}
|
|
} else if( !armed() ) {
|
|
_rc->OutputCh(AP_MOTORS_HELI_EXT_ESC, _rc_8->radio_min);
|
|
ext_esc_ramp = 0; //Return ESC Ramp to 0
|
|
}
|
|
break;
|
|
|
|
case AP_MOTORS_ESC_MODE_EXT_GOV:
|
|
|
|
if( armed() && _rc_throttle->control_in > 10){
|
|
if (ext_esc_ramp < AP_MOTORS_EXT_ESC_RAMP_UP){
|
|
ext_esc_ramp++;
|
|
ext_esc_output = map(ext_esc_ramp, 0, AP_MOTORS_EXT_ESC_RAMP_UP, 1000, ext_gov_setpoint);
|
|
} else {
|
|
ext_esc_output = ext_gov_setpoint;
|
|
}
|
|
} else {
|
|
ext_esc_ramp = 0; //Return ESC Ramp to 0
|
|
ext_esc_output = 1000; //Just to be sure ESC output is 0
|
|
}
|
|
_rc->OutputCh(AP_MOTORS_HELI_EXT_ESC, ext_esc_output);
|
|
break;
|
|
|
|
// case 3: // Open Loop ESC Control
|
|
//
|
|
// coll_scaled = _motors->coll_out_scaled + 1000;
|
|
// if(coll_scaled <= _motors->collective_mid){
|
|
// esc_ol_output = map(coll_scaled, _motors->collective_min, _motors->collective_mid, esc_out_low, esc_out_mid); // Bottom half of V-curve
|
|
// } else if (coll_scaled > _motors->collective_mid){
|
|
// esc_ol_output = map(coll_scaled, _motors->collective_mid, _motors->collective_max, esc_out_mid, esc_out_high); // Top half of V-curve
|
|
// } else { esc_ol_output = 1000; } // Just in case.
|
|
//
|
|
// if(_motors->armed() && _rc_throttle->control_in > 10){
|
|
// if (ext_esc_ramp < ext_esc_ramp_up){
|
|
// ext_esc_ramp++;
|
|
// ext_esc_output = map(ext_esc_ramp, 0, ext_esc_ramp_up, 1000, esc_ol_output);
|
|
// } else {
|
|
// ext_esc_output = esc_ol_output;
|
|
// }
|
|
// } else {
|
|
// ext_esc_ramp = 0; //Return ESC Ramp to 0
|
|
// ext_esc_output = 1000; //Just to be sure ESC output is 0
|
|
//}
|
|
// _rc->OutputCh(AP_MOTORS_HELI_EXT_ESC, ext_esc_output);
|
|
// break;
|
|
|
|
|
|
default:
|
|
break;
|
|
}
|
|
}; |