2021-05-27 13:08:15 -03:00
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#pragma once
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#include <AP_Arming/AP_Arming.h>
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#include <AP_ServoRelayEvents/AP_ServoRelayEvents.h>
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#include <AP_WheelEncoder/AP_WheelRateControl.h>
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2022-03-03 23:58:19 -04:00
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#include <SRV_Channel/SRV_Channel.h>
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2021-05-27 13:08:15 -03:00
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class AP_MotorsUGV {
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public:
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// Constructor
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AP_MotorsUGV(AP_ServoRelayEvents &relayEvents, AP_WheelRateControl& rate_controller);
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// singleton support
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static AP_MotorsUGV *get_singleton(void) { return _singleton; }
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enum motor_test_order {
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MOTOR_TEST_THROTTLE = 1,
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MOTOR_TEST_STEERING = 2,
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MOTOR_TEST_THROTTLE_LEFT = 3,
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MOTOR_TEST_THROTTLE_RIGHT = 4,
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MOTOR_TEST_MAINSAIL = 5,
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MOTOR_TEST_LAST
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};
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// supported omni motor configurations
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enum frame_type {
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FRAME_TYPE_UNDEFINED = 0,
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FRAME_TYPE_OMNI3 = 1,
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FRAME_TYPE_OMNIX = 2,
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FRAME_TYPE_OMNIPLUS = 3,
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};
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// initialise motors
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void init(uint8_t ftype);
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// return true if motors are active
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bool active() const;
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// setup output in case of main CPU failure
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void setup_safety_output();
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// setup servo output ranges
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void setup_servo_output();
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// get or set steering as a value from -4500 to +4500
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// apply_scaling should be set to false for manual modes where
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// no scaling by speed or angle should e performed
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float get_steering() const { return _steering; }
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void set_steering(float steering, bool apply_scaling = true);
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// get or set throttle as a value from -100 to 100
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float get_throttle() const { return _throttle; }
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void set_throttle(float throttle);
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// get or set roll as a value from -1 to 1
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float get_roll() const { return _roll; }
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void set_roll(float roll);
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// get or set pitch as a value from -1 to 1
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float get_pitch() const { return _pitch; }
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void set_pitch(float pitch);
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// get or set walking_height as a value from -1 to 1
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float get_walking_height() const { return _walking_height; }
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void set_walking_height(float walking_height);
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// get or set lateral input as a value from -100 to +100
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float get_lateral() const { return _lateral; }
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void set_lateral(float lateral);
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// set or get mainsail input as a value from 0 to 100
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void set_mainsail(float mainsail);
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float get_mainsail() const { return _mainsail; }
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// set or get wingsail input as a value from -100 to 100
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void set_wingsail(float wingsail);
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float get_wingsail() const { return _wingsail; }
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// set or get mast rotation input as a value from -100 to 100
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void set_mast_rotation(float mast_rotation);
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float get_mast_rotation() const { return _mast_rotation; }
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// get slew limited throttle
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// used by manual mode to avoid bad steering behaviour during transitions from forward to reverse
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// same as private slew_limit_throttle method (see below) but does not update throttle state
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float get_slew_limited_throttle(float throttle, float dt) const;
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// true if vehicle is capable of skid steering
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bool have_skid_steering() const;
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// true if vehicle has vectored thrust (i.e. boat with motor on steering servo)
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bool have_vectored_thrust() const { return is_positive(_vector_angle_max); }
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// output to motors and steering servos
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// ground_speed should be the vehicle's speed over the surface in m/s
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// dt should be expected time between calls to this function
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void output(bool armed, float ground_speed, float dt);
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// test steering or throttle output as a percentage of the total (range -100 to +100)
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// used in response to DO_MOTOR_TEST mavlink command
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bool output_test_pct(motor_test_order motor_seq, float pct);
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// test steering or throttle output using a pwm value
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bool output_test_pwm(motor_test_order motor_seq, float pwm);
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// returns true if checks pass, false if they fail. display_failure argument should be true to send text messages to GCS
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bool pre_arm_check(bool report) const;
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// return the motor mask
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2021-12-10 12:45:38 -04:00
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uint32_t get_motor_mask() const { return _motor_mask; }
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2021-05-27 13:08:15 -03:00
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2021-09-22 12:16:06 -03:00
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// returns true if the configured PWM type is digital and should have fixed endpoints
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bool is_digital_pwm_type() const;
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// structure for holding motor limit flags
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struct AP_MotorsUGV_limit {
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uint8_t steer_left : 1; // we have reached the steering controller's left most limit
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uint8_t steer_right : 1; // we have reached the steering controller's right most limit
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uint8_t throttle_lower : 1; // we have reached throttle's lower limit
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uint8_t throttle_upper : 1; // we have reached throttle's upper limit
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} limit;
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// var_info for holding Parameter information
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static const struct AP_Param::GroupInfo var_info[];
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2021-09-22 12:16:06 -03:00
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private:
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enum pwm_type {
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PWM_TYPE_NORMAL = 0,
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PWM_TYPE_ONESHOT = 1,
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PWM_TYPE_ONESHOT125 = 2,
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PWM_TYPE_BRUSHED_WITH_RELAY = 3,
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PWM_TYPE_BRUSHED_BIPOLAR = 4,
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PWM_TYPE_DSHOT150 = 5,
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PWM_TYPE_DSHOT300 = 6,
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PWM_TYPE_DSHOT600 = 7,
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PWM_TYPE_DSHOT1200 = 8
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};
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2021-05-27 13:08:15 -03:00
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// sanity check parameters
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void sanity_check_parameters();
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// setup pwm output type
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void setup_pwm_type();
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// setup for frames with omni motors
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void setup_omni();
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// add omni motor using separate throttle, steering and lateral factors
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void add_omni_motor(int8_t motor_num, float throttle_factor, float steering_factor, float lateral_factor);
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// add a motor and set up output function
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void add_omni_motor_num(int8_t motor_num);
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// disable omni motor and remove all throttle, steering and lateral factor for this motor
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void clear_omni_motors(int8_t motor_num);
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// output to regular steering and throttle channels
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void output_regular(bool armed, float ground_speed, float steering, float throttle);
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// output to skid steering channels
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void output_skid_steering(bool armed, float steering, float throttle, float dt);
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// output for omni motors
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void output_omni(bool armed, float steering, float throttle, float lateral);
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// output throttle (-100 ~ +100) to a throttle channel. Sets relays if required
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// dt is the main loop time interval and is required when rate control is required
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void output_throttle(SRV_Channel::Aux_servo_function_t function, float throttle, float dt = 0.0f);
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// output for sailboat's mainsail in the range of 0 to 100 and wing sail in the range +- 100
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void output_sail();
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// true if the vehicle has a mainsail or wing sail
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bool has_sail() const;
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// slew limit throttle for one iteration
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void slew_limit_throttle(float dt);
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// set limits based on steering and throttle input
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void set_limits_from_input(bool armed, float steering, float throttle);
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// scale a throttle using the _thrust_curve_expo parameter. throttle should be in the range -100 to +100
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float get_scaled_throttle(float throttle) const;
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// use rate controller to achieve desired throttle
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float get_rate_controlled_throttle(SRV_Channel::Aux_servo_function_t function, float throttle, float dt);
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// external references
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AP_ServoRelayEvents &_relayEvents;
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AP_WheelRateControl &_rate_controller;
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static const int8_t AP_MOTORS_NUM_MOTORS_MAX = 4;
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// parameters
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AP_Int8 _pwm_type; // PWM output type
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AP_Int8 _pwm_freq; // PWM output freq for brushed motors
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AP_Int8 _disarm_disable_pwm; // disable PWM output while disarmed
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AP_Int16 _slew_rate; // slew rate expressed as a percentage / second
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AP_Int8 _throttle_min; // throttle minimum percentage
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AP_Int8 _throttle_max; // throttle maximum percentage
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AP_Float _thrust_curve_expo; // thrust curve exponent from -1 to +1 with 0 being linear
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AP_Float _vector_angle_max; // angle between steering's middle position and maximum position when using vectored thrust. zero to disable vectored thrust
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AP_Float _speed_scale_base; // speed above which steering is scaled down when using regular steering/throttle vehicles. zero to disable speed scaling
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AP_Float _steering_throttle_mix; // Steering vs Throttle priorisation. Higher numbers prioritise steering, lower numbers prioritise throttle. Only valid for Skid Steering vehicles
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// internal variables
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float _steering; // requested steering as a value from -4500 to +4500
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float _throttle; // requested throttle as a value from -100 to 100
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float _throttle_prev; // throttle input from previous iteration
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bool _scale_steering = true; // true if we should scale steering by speed or angle
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float _lateral; // requested lateral input as a value from -100 to +100
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float _roll; // requested roll as a value from -1 to +1
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float _pitch; // requested pitch as a value from -1 to +1
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float _walking_height; // requested height as a value from -1 to +1
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float _mainsail; // requested mainsail input as a value from 0 to 100
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float _wingsail; // requested wing sail input as a value in the range +- 100
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float _mast_rotation; // requested mast rotation input as a value in the range +- 100
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2021-12-10 12:45:38 -04:00
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uint32_t _motor_mask; // mask of motors configured with pwm_type
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2021-06-07 04:59:11 -03:00
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frame_type _frame_type; // frame type requested at initialisation
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2021-05-27 13:08:15 -03:00
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// omni variables
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float _throttle_factor[AP_MOTORS_NUM_MOTORS_MAX];
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float _steering_factor[AP_MOTORS_NUM_MOTORS_MAX];
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float _lateral_factor[AP_MOTORS_NUM_MOTORS_MAX];
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uint8_t _motors_num;
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static AP_MotorsUGV *_singleton;
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};
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namespace AP {
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AP_MotorsUGV *motors_ugv();
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2022-02-03 22:57:38 -04:00
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};
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