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/*
* This program is free software : you can redistribute it and / or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation , either version 3 of the License , or
* ( at your option ) any later version .
*
* This program is distributed in the hope that it will be useful ,
* but WITHOUT ANY WARRANTY ; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE . See the
* GNU General Public License for more details .
*
* You should have received a copy of the GNU General Public License
* along with this program . If not , see < http : //www.gnu.org/licenses/>.
*/
# include <stdlib.h>
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# include <AP_HAL/AP_HAL.h>
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# include <SRV_Channel/SRV_Channel.h>
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# include "AP_MotorsHeli_Single.h"
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# include <GCS_MAVLink/GCS.h>
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extern const AP_HAL : : HAL & hal ;
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const AP_Param : : GroupInfo AP_MotorsHeli_Single : : var_info [ ] = {
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AP_NESTEDGROUPINFO ( AP_MotorsHeli , 0 ) ,
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// Indices 1-3 were used by servo position params and should not be used
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// @Param: TAIL_TYPE
// @DisplayName: Tail Type
// @Description: Tail type selection. Simpler yaw controller used if external gyro is selected
// @Values: 0:Servo only,1:Servo with ExtGyro,2:DirectDrive VarPitch,3:DirectDrive FixedPitch
// @User: Standard
AP_GROUPINFO ( " TAIL_TYPE " , 4 , AP_MotorsHeli_Single , _tail_type , AP_MOTORS_HELI_SINGLE_TAILTYPE_SERVO ) ,
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// Indice 5 was used by SWASH_TYPE and should not be used
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// @Param: GYR_GAIN
// @DisplayName: External Gyro Gain
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// @Description: PWM in microseconds sent to external gyro on ch7 when tail type is Servo w/ ExtGyro
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// @Range: 0 1000
// @Units: PWM
// @Increment: 1
// @User: Standard
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AP_GROUPINFO ( " GYR_GAIN " , 6 , AP_MotorsHeli_Single , _ext_gyro_gain_std , AP_MOTORS_HELI_SINGLE_EXT_GYRO_GAIN ) ,
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// Index 7 was used for phase angle and should not be used
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// @Param: COLYAW
// @DisplayName: Collective-Yaw Mixing
// @Description: Feed-forward compensation to automatically add rudder input when collective pitch is increased. Can be positive or negative depending on mechanics.
// @Range: -10 10
// @Increment: 0.1
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// @User: Advanced
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AP_GROUPINFO ( " COLYAW " , 8 , AP_MotorsHeli_Single , _collective_yaw_effect , 0 ) ,
// @Param: FLYBAR_MODE
// @DisplayName: Flybar Mode Selector
// @Description: Flybar present or not. Affects attitude controller used during ACRO flight mode
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// @Values: 0:NoFlybar,1:Flybar
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// @User: Standard
AP_GROUPINFO ( " FLYBAR_MODE " , 9 , AP_MotorsHeli_Single , _flybar_mode , AP_MOTORS_HELI_NOFLYBAR ) ,
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// @Param: TAIL_SPEED
// @DisplayName: Direct Drive VarPitch Tail ESC speed
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// @Description: Direct Drive VarPitch Tail ESC speed in PWM microseconds. Only used when TailType is DirectDrive VarPitch
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// @Range: 0 1000
// @Units: PWM
// @Increment: 1
// @User: Standard
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AP_GROUPINFO ( " TAIL_SPEED " , 10 , AP_MotorsHeli_Single , _direct_drive_tailspeed , AP_MOTORS_HELI_SINGLE_DDVP_SPEED_DEFAULT ) ,
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// @Param: GYR_GAIN_ACRO
// @DisplayName: External Gyro Gain for ACRO
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// @Description: PWM in microseconds sent to external gyro on ch7 when tail type is Servo w/ ExtGyro. A value of zero means to use H_GYR_GAIN
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// @Range: 0 1000
// @Units: PWM
// @Increment: 1
// @User: Standard
AP_GROUPINFO ( " GYR_GAIN_ACRO " , 11 , AP_MotorsHeli_Single , _ext_gyro_gain_acro , 0 ) ,
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// Indices 16-19 were used by RSC_PWM_MIN, RSC_PWM_MAX, RSC_PWM_REV, and COL_CTRL_DIR and should not be used
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// @Group: H3_SW_
// @Path: AP_MotorsHeli_Swash.cpp
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AP_SUBGROUPINFO ( _swashplate , " SW_ " , 20 , AP_MotorsHeli_Single , AP_MotorsHeli_Swash ) ,
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AP_GROUPEND
} ;
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# define YAW_SERVO_MAX_ANGLE 4500
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// set update rate to motors - a value in hertz
void AP_MotorsHeli_Single : : set_update_rate ( uint16_t speed_hz )
{
// record requested speed
_speed_hz = speed_hz ;
// setup fast channels
uint32_t mask =
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1U < < AP_MOTORS_MOT_1 |
1U < < AP_MOTORS_MOT_2 |
1U < < AP_MOTORS_MOT_3 |
1U < < AP_MOTORS_MOT_4 ;
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if ( _swashplate . get_swash_type ( ) = = SWASHPLATE_TYPE_H4_90 | | _swashplate . get_swash_type ( ) = = SWASHPLATE_TYPE_H4_45 ) {
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mask | = 1U < < ( AP_MOTORS_MOT_5 ) ;
}
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rc_set_freq ( mask , _speed_hz ) ;
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}
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// init_outputs - initialise Servo/PWM ranges and endpoints
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bool AP_MotorsHeli_Single : : init_outputs ( )
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{
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if ( ! _flags . initialised_ok ) {
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// map primary swash servos
for ( uint8_t i = 0 ; i < AP_MOTORS_HELI_SINGLE_NUM_SWASHPLATE_SERVOS ; i + + ) {
add_motor_num ( CH_1 + i ) ;
}
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if ( _swashplate . get_swash_type ( ) = = SWASHPLATE_TYPE_H4_90 | | _swashplate . get_swash_type ( ) = = SWASHPLATE_TYPE_H4_45 ) {
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add_motor_num ( CH_5 ) ;
}
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// yaw servo
add_motor_num ( CH_4 ) ;
// initialize main rotor servo
_main_rotor . init_servo ( ) ;
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if ( _tail_type = = AP_MOTORS_HELI_SINGLE_TAILTYPE_DIRECTDRIVE_VARPITCH ) {
_tail_rotor . init_servo ( ) ;
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} else if ( _tail_type = = AP_MOTORS_HELI_SINGLE_TAILTYPE_SERVO_EXTGYRO ) {
// external gyro output
add_motor_num ( AP_MOTORS_HELI_SINGLE_EXTGYRO ) ;
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}
}
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if ( _tail_type = = AP_MOTORS_HELI_SINGLE_TAILTYPE_SERVO_EXTGYRO ) {
// External Gyro uses PWM output thus servo endpoints are forced
SRV_Channels : : set_output_min_max ( SRV_Channels : : get_motor_function ( AP_MOTORS_HELI_SINGLE_EXTGYRO ) , 1000 , 2000 ) ;
}
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// reset swash servo range and endpoints
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for ( uint8_t i = 0 ; i < AP_MOTORS_HELI_SINGLE_NUM_SWASHPLATE_SERVOS ; i + + ) {
reset_swash_servo ( SRV_Channels : : get_motor_function ( i ) ) ;
}
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if ( _swashplate . get_swash_type ( ) = = SWASHPLATE_TYPE_H4_90 | | _swashplate . get_swash_type ( ) = = SWASHPLATE_TYPE_H4_45 ) {
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reset_swash_servo ( SRV_Channels : : get_motor_function ( 4 ) ) ;
}
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// yaw servo is an angle from -4500 to 4500
SRV_Channels : : set_angle ( SRV_Channel : : k_motor4 , YAW_SERVO_MAX_ANGLE ) ;
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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
// 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_Single : : output_test_seq ( uint8_t motor_seq , int16_t pwm )
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{
// exit immediately if not armed
if ( ! armed ( ) ) {
return ;
}
// output to motors and servos
switch ( motor_seq ) {
case 1 :
// swash servo 1
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rc_write ( AP_MOTORS_MOT_1 , pwm ) ;
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break ;
case 2 :
// swash servo 2
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rc_write ( AP_MOTORS_MOT_2 , pwm ) ;
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break ;
case 3 :
// swash servo 3
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rc_write ( AP_MOTORS_MOT_3 , pwm ) ;
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break ;
case 4 :
// external gyro & tail servo
if ( _tail_type = = AP_MOTORS_HELI_SINGLE_TAILTYPE_SERVO_EXTGYRO ) {
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if ( _acro_tail & & _ext_gyro_gain_acro > 0 ) {
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rc_write ( AP_MOTORS_HELI_SINGLE_EXTGYRO , _ext_gyro_gain_acro ) ;
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} else {
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rc_write ( AP_MOTORS_HELI_SINGLE_EXTGYRO , _ext_gyro_gain_std ) ;
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}
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}
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rc_write ( AP_MOTORS_MOT_4 , pwm ) ;
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break ;
case 5 :
// main rotor
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rc_write ( AP_MOTORS_HELI_SINGLE_RSC , pwm ) ;
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break ;
default :
// do nothing
break ;
}
}
// set_desired_rotor_speed
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void AP_MotorsHeli_Single : : set_desired_rotor_speed ( float desired_speed )
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{
_main_rotor . set_desired_speed ( desired_speed ) ;
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// always send desired speed to tail rotor control, will do nothing if not DDVP not enabled
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_tail_rotor . set_desired_speed ( _direct_drive_tailspeed * 0.001f ) ;
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}
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// calculate_scalars - recalculates various scalers used.
void AP_MotorsHeli_Single : : calculate_armed_scalars ( )
{
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float thrcrv [ 5 ] ;
for ( uint8_t i = 0 ; i < 5 ; i + + ) {
thrcrv [ i ] = _rsc_thrcrv [ i ] * 0.001f ;
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}
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_main_rotor . set_ramp_time ( _rsc_ramp_time ) ;
_main_rotor . set_runup_time ( _rsc_runup_time ) ;
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_main_rotor . set_critical_speed ( _rsc_critical * 0.001f ) ;
_main_rotor . set_idle_output ( _rsc_idle_output * 0.001f ) ;
_main_rotor . set_throttle_curve ( thrcrv , ( uint16_t ) _rsc_slewrate . get ( ) ) ;
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}
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// calculate_scalars - recalculates various scalers used.
void AP_MotorsHeli_Single : : calculate_scalars ( )
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{
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// range check collective min, max and mid
if ( _collective_min > = _collective_max ) {
_collective_min = AP_MOTORS_HELI_COLLECTIVE_MIN ;
_collective_max = AP_MOTORS_HELI_COLLECTIVE_MAX ;
}
_collective_mid = constrain_int16 ( _collective_mid , _collective_min , _collective_max ) ;
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// calculate collective mid point as a number from 0 to 1
_collective_mid_pct = ( ( float ) ( _collective_mid - _collective_min ) ) / ( ( float ) ( _collective_max - _collective_min ) ) ;
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// configure swashplate and update scalars
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_swashplate . configure ( ) ;
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_swashplate . calculate_roll_pitch_collective_factors ( ) ;
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// send setpoints to main rotor controller and trigger recalculation of scalars
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_main_rotor . set_control_mode ( static_cast < RotorControlMode > ( _rsc_mode . get ( ) ) ) ;
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calculate_armed_scalars ( ) ;
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// send setpoints to DDVP rotor controller and trigger recalculation of scalars
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if ( _tail_type = = AP_MOTORS_HELI_SINGLE_TAILTYPE_DIRECTDRIVE_VARPITCH ) {
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_tail_rotor . set_control_mode ( ROTOR_CONTROL_MODE_SPEED_SETPOINT ) ;
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_tail_rotor . set_ramp_time ( _rsc_ramp_time ) ;
_tail_rotor . set_runup_time ( _rsc_runup_time ) ;
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_tail_rotor . set_critical_speed ( _rsc_critical * 0.001f ) ;
_tail_rotor . set_idle_output ( _rsc_idle_output * 0.001f ) ;
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} else {
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_tail_rotor . set_control_mode ( ROTOR_CONTROL_MODE_DISABLED ) ;
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_tail_rotor . set_ramp_time ( 0 ) ;
_tail_rotor . set_runup_time ( 0 ) ;
_tail_rotor . set_critical_speed ( 0 ) ;
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_tail_rotor . set_idle_output ( 0 ) ;
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}
}
// get_motor_mask - returns a bitmask of which outputs are being used for motors or servos (1 means being used)
// this can be used to ensure other pwm outputs (i.e. for servos) do not conflict
uint16_t AP_MotorsHeli_Single : : get_motor_mask ( )
{
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// heli uses channels 1,2,3,4 and 8
// setup fast channels
uint32_t mask = 1U < < 0 | 1U < < 1 | 1U < < 2 | 1U < < 3 | 1U < < AP_MOTORS_HELI_SINGLE_RSC ;
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if ( _swashplate . get_swash_type ( ) = = SWASHPLATE_TYPE_H4_90 | | _swashplate . get_swash_type ( ) = = SWASHPLATE_TYPE_H4_45 ) {
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mask | = 1U < < 4 ;
}
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if ( _tail_type = = AP_MOTORS_HELI_SINGLE_TAILTYPE_SERVO_EXTGYRO ) {
mask | = 1U < < AP_MOTORS_HELI_SINGLE_EXTGYRO ;
}
if ( _tail_type = = AP_MOTORS_HELI_SINGLE_TAILTYPE_DIRECTDRIVE_VARPITCH ) {
mask | = 1U < < AP_MOTORS_HELI_SINGLE_TAILRSC ;
}
return rc_map_mask ( mask ) ;
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}
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// update_motor_controls - sends commands to motor controllers
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void AP_MotorsHeli_Single : : update_motor_control ( RotorControlState state )
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{
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// Send state update to motors
_tail_rotor . output ( state ) ;
_main_rotor . output ( state ) ;
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if ( state = = ROTOR_CONTROL_STOP ) {
// 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 {
// 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 both rotors are run-up, tail rotor controller always returns true if not enabled
_heliflags . rotor_runup_complete = ( _main_rotor . is_runup_complete ( ) & & _tail_rotor . is_runup_complete ( ) ) ;
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}
//
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// move_actuators - moves swash plate and tail rotor
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// - expected ranges:
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// roll : -1 ~ +1
// pitch: -1 ~ +1
// collective: 0 ~ 1
// yaw: -1 ~ +1
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//
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void AP_MotorsHeli_Single : : move_actuators ( float roll_out , float pitch_out , float coll_in , float yaw_out )
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{
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float yaw_offset = 0.0f ;
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// initialize limits flag
limit . roll_pitch = false ;
limit . yaw = false ;
limit . throttle_lower = false ;
limit . throttle_upper = false ;
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if ( _heliflags . inverted_flight ) {
coll_in = 1 - coll_in ;
}
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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 cyclic_max
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// coming into this equation at 4500 or less
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float total_out = norm ( pitch_out , roll_out ) ;
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if ( total_out > ( _cyclic_max / 4500.0f ) ) {
float ratio = ( float ) ( _cyclic_max / 4500.0f ) / total_out ;
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roll_out * = ratio ;
pitch_out * = ratio ;
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limit . roll_pitch = true ;
}
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// constrain collective input
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float collective_out = coll_in ;
if ( collective_out < = 0.0f ) {
collective_out = 0.0f ;
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limit . throttle_lower = true ;
}
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if ( collective_out > = 1.0f ) {
collective_out = 1.0f ;
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limit . throttle_upper = true ;
}
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// ensure not below landed/landing collective
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if ( _heliflags . landing_collective & & collective_out < ( _land_collective_min * 0.001f ) ) {
collective_out = ( _land_collective_min * 0.001f ) ;
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limit . throttle_lower = true ;
}
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// if servo output not in manual mode, process pre-compensation factors
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if ( _servo_mode = = SERVO_CONTROL_MODE_AUTOMATED ) {
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// rudder feed forward based on collective
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// the feed-forward is not required when the motor is stopped or at idle, and thus not creating torque
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// also not required if we are using external gyro
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if ( ( _main_rotor . get_control_output ( ) > _main_rotor . get_idle_output ( ) ) & & _tail_type ! = AP_MOTORS_HELI_SINGLE_TAILTYPE_SERVO_EXTGYRO ) {
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// sanity check collective_yaw_effect
_collective_yaw_effect = constrain_float ( _collective_yaw_effect , - AP_MOTORS_HELI_SINGLE_COLYAW_RANGE , AP_MOTORS_HELI_SINGLE_COLYAW_RANGE ) ;
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// the 4.5 scaling factor is to bring the values in line with previous releases
yaw_offset = _collective_yaw_effect * fabsf ( collective_out - _collective_mid_pct ) / 4.5f ;
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}
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} else {
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yaw_offset = 0.0f ;
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}
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// feed power estimate into main rotor controller
// ToDo: include tail rotor power?
// ToDo: add main rotor cyclic power?
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_main_rotor . set_collective ( fabsf ( collective_out ) ) ;
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// scale collective pitch for swashplate servos
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float collective_scalar = ( ( float ) ( _collective_max - _collective_min ) ) * 0.001f ;
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float collective_out_scaled = collective_out * collective_scalar + ( _collective_min - 1000 ) * 0.001f ;
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// get servo positions from swashplate library
_servo1_out = _swashplate . get_servo_out ( CH_1 , pitch_out , roll_out , collective_out_scaled ) ;
_servo2_out = _swashplate . get_servo_out ( CH_2 , pitch_out , roll_out , collective_out_scaled ) ;
_servo3_out = _swashplate . get_servo_out ( CH_3 , pitch_out , roll_out , collective_out_scaled ) ;
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if ( _swashplate . get_swash_type ( ) = = SWASHPLATE_TYPE_H4_90 | | _swashplate . get_swash_type ( ) = = SWASHPLATE_TYPE_H4_45 ) {
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_servo5_out = _swashplate . get_servo_out ( CH_4 , pitch_out , roll_out , collective_out_scaled ) ;
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}
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// update the yaw rate using the tail rotor/servo
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move_yaw ( yaw_out + yaw_offset ) ;
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}
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// move_yaw
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void AP_MotorsHeli_Single : : move_yaw ( float yaw_out )
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{
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// sanity check yaw_out
if ( yaw_out < - 1.0f ) {
yaw_out = - 1.0f ;
limit . yaw = true ;
}
if ( yaw_out > 1.0f ) {
yaw_out = 1.0f ;
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limit . yaw = true ;
}
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_servo4_out = yaw_out ;
}
void AP_MotorsHeli_Single : : output_to_motors ( )
{
if ( ! _flags . initialised_ok ) {
return ;
}
// actually move the servos. PWM is sent based on nominal 1500 center. servo output shifts center based on trim value.
rc_write_swash ( AP_MOTORS_MOT_1 , _servo1_out ) ;
rc_write_swash ( AP_MOTORS_MOT_2 , _servo2_out ) ;
rc_write_swash ( AP_MOTORS_MOT_3 , _servo3_out ) ;
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// get servo positions from swashplate library and write to servo for 4 servo of 4 servo swashplate
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if ( _swashplate . get_swash_type ( ) = = SWASHPLATE_TYPE_H4_90 | | _swashplate . get_swash_type ( ) = = SWASHPLATE_TYPE_H4_45 ) {
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rc_write_swash ( AP_MOTORS_MOT_5 , _servo5_out ) ;
}
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if ( _tail_type ! = AP_MOTORS_HELI_SINGLE_TAILTYPE_DIRECTDRIVE_FIXEDPITCH ) {
rc_write_angle ( AP_MOTORS_MOT_4 , _servo4_out * YAW_SERVO_MAX_ANGLE ) ;
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}
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if ( _tail_type = = AP_MOTORS_HELI_SINGLE_TAILTYPE_SERVO_EXTGYRO ) {
// output gain to exernal gyro
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if ( _acro_tail & & _ext_gyro_gain_acro > 0 ) {
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rc_write ( AP_MOTORS_HELI_SINGLE_EXTGYRO , 1000 + _ext_gyro_gain_acro ) ;
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} else {
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rc_write ( AP_MOTORS_HELI_SINGLE_EXTGYRO , 1000 + _ext_gyro_gain_std ) ;
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}
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}
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switch ( _spool_state ) {
case SpoolState : : SHUT_DOWN :
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// sends minimum values out to the motors
update_motor_control ( ROTOR_CONTROL_STOP ) ;
if ( _tail_type = = AP_MOTORS_HELI_SINGLE_TAILTYPE_DIRECTDRIVE_FIXEDPITCH ) {
rc_write_angle ( AP_MOTORS_MOT_4 , - YAW_SERVO_MAX_ANGLE ) ;
}
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)
update_motor_control ( ROTOR_CONTROL_IDLE ) ;
if ( _tail_type = = AP_MOTORS_HELI_SINGLE_TAILTYPE_DIRECTDRIVE_FIXEDPITCH ) {
rc_write_angle ( AP_MOTORS_MOT_4 , - YAW_SERVO_MAX_ANGLE ) ;
}
break ;
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case SpoolState : : SPOOLING_UP :
case SpoolState : : THROTTLE_UNLIMITED :
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// set motor output based on thrust requests
update_motor_control ( ROTOR_CONTROL_ACTIVE ) ;
if ( _tail_type = = AP_MOTORS_HELI_SINGLE_TAILTYPE_DIRECTDRIVE_FIXEDPITCH ) {
// constrain output so that motor never fully stops
_servo4_out = constrain_float ( _servo4_out , - 0.9f , 1.0f ) ;
// output yaw servo to tail rsc
rc_write_angle ( AP_MOTORS_MOT_4 , _servo4_out * YAW_SERVO_MAX_ANGLE ) ;
}
break ;
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case SpoolState : : SPOOLING_DOWN :
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// sends idle output to motors and wait for rotor to stop
update_motor_control ( ROTOR_CONTROL_IDLE ) ;
if ( _tail_type = = AP_MOTORS_HELI_SINGLE_TAILTYPE_DIRECTDRIVE_FIXEDPITCH ) {
rc_write_angle ( AP_MOTORS_MOT_4 , - YAW_SERVO_MAX_ANGLE ) ;
}
break ;
}
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}
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// servo_test - move servos through full range of movement
void AP_MotorsHeli_Single : : servo_test ( )
{
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_servo_test_cycle_time + = 1.0f / _loop_rate ;
if ( ( _servo_test_cycle_time > = 0.0f & & _servo_test_cycle_time < 0.5f ) | | // Tilt swash back
( _servo_test_cycle_time > = 6.0f & & _servo_test_cycle_time < 6.5f ) ) {
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_pitch_test + = ( 1.0f / ( _loop_rate / 2.0f ) ) ;
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_oscillate_angle + = 8 * M_PI / _loop_rate ;
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_yaw_test = 0.5f * sinf ( _oscillate_angle ) ;
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} else if ( ( _servo_test_cycle_time > = 0.5f & & _servo_test_cycle_time < 4.5f ) | | // Roll swash around
( _servo_test_cycle_time > = 6.5f & & _servo_test_cycle_time < 10.5f ) ) {
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_oscillate_angle + = M_PI / ( 2 * _loop_rate ) ;
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_roll_test = sinf ( _oscillate_angle ) ;
_pitch_test = cosf ( _oscillate_angle ) ;
_yaw_test = sinf ( _oscillate_angle ) ;
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} else if ( ( _servo_test_cycle_time > = 4.5f & & _servo_test_cycle_time < 5.0f ) | | // Return swash to level
( _servo_test_cycle_time > = 10.5f & & _servo_test_cycle_time < 11.0f ) ) {
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_pitch_test - = ( 1.0f / ( _loop_rate / 2.0f ) ) ;
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_oscillate_angle + = 8 * M_PI / _loop_rate ;
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_yaw_test = 0.5f * sinf ( _oscillate_angle ) ;
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} else if ( _servo_test_cycle_time > = 5.0f & & _servo_test_cycle_time < 6.0f ) { // Raise swash to top
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_collective_test + = ( 1.0f / _loop_rate ) ;
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_oscillate_angle + = 2 * M_PI / _loop_rate ;
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_yaw_test = sinf ( _oscillate_angle ) ;
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} else if ( _servo_test_cycle_time > = 11.0f & & _servo_test_cycle_time < 12.0f ) { // Lower swash to bottom
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_collective_test - = ( 1.0f / _loop_rate ) ;
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_oscillate_angle + = 2 * M_PI / _loop_rate ;
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_yaw_test = sinf ( _oscillate_angle ) ;
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} else { // reset cycle
_servo_test_cycle_time = 0.0f ;
_oscillate_angle = 0.0f ;
_collective_test = 0.0f ;
_roll_test = 0.0f ;
_pitch_test = 0.0f ;
_yaw_test = 0.0f ;
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// decrement servo test cycle counter at the end of the cycle
if ( _servo_test_cycle_counter > 0 ) {
_servo_test_cycle_counter - - ;
}
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}
// over-ride servo commands to move servos through defined ranges
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_throttle_filter . reset ( constrain_float ( _collective_test , 0.0f , 1.0f ) ) ;
_roll_in = constrain_float ( _roll_test , - 1.0f , 1.0f ) ;
_pitch_in = constrain_float ( _pitch_test , - 1.0f , 1.0f ) ;
_yaw_in = constrain_float ( _yaw_test , - 1.0f , 1.0f ) ;
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}
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// parameter_check - check if helicopter specific parameters are sensible
bool AP_MotorsHeli_Single : : parameter_check ( bool display_msg ) const
{
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// returns false if Phase Angle is outside of range for H3 swashplate
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if ( _swashplate . get_swash_type ( ) = = SWASHPLATE_TYPE_H3 & & ( _swashplate . get_phase_angle ( ) > 30 | | _swashplate . get_phase_angle ( ) < - 30 ) ) {
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if ( display_msg ) {
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gcs ( ) . send_text ( MAV_SEVERITY_CRITICAL , " PreArm: H_H3_PHANG out of range " ) ;
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}
return false ;
}
// returns false if Acro External Gyro Gain is outside of range
if ( ( _ext_gyro_gain_acro < 0 ) | | ( _ext_gyro_gain_acro > 1000 ) ) {
if ( display_msg ) {
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gcs ( ) . send_text ( MAV_SEVERITY_CRITICAL , " PreArm: H_GYR_GAIN_ACRO out of range " ) ;
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}
return false ;
}
// returns false if Standard External Gyro Gain is outside of range
if ( ( _ext_gyro_gain_std < 0 ) | | ( _ext_gyro_gain_std > 1000 ) ) {
if ( display_msg ) {
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gcs ( ) . send_text ( MAV_SEVERITY_CRITICAL , " PreArm: H_GYR_GAIN out of range " ) ;
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}
return false ;
}
// check parent class parameters
return AP_MotorsHeli : : parameter_check ( display_msg ) ;
}