ardupilot/libraries/AP_Mount/AP_Mount_Alexmos.h

252 lines
6.5 KiB
C++

/*
Alexmos Serial controlled mount backend class
*/
#pragma once
#include "AP_Mount_config.h"
#if HAL_MOUNT_ALEXMOS_ENABLED
#include "AP_Mount_Backend.h"
#include <AP_HAL/AP_HAL.h>
#include <AP_Param/AP_Param.h>
#include <AP_Math/AP_Math.h>
class AP_Mount_Alexmos : public AP_Mount_Backend
{
public:
//constructor
using AP_Mount_Backend::AP_Mount_Backend;
// init - performs any required initialisation for this instance
void init() override;
// update mount position - should be called periodically
void update() override;
// has_pan_control - returns true if this mount can control its pan (required for multicopters)
bool has_pan_control() const override;
protected:
// get attitude as a quaternion. returns true on success
bool get_attitude_quaternion(Quaternion& att_quat) override;
private:
// get_angles -
void get_angles();
// set_motor will activate motors if true, and disable them if false
void set_motor(bool on);
// get_boardinfo - get board version and firmware version
void get_boardinfo();
// send new angles to the gimbal at a fixed speed of 30 deg/s
void control_axis(const MountTarget& angle_target_rad);
// read_params - read current profile profile_id and global parameters from the gimbal settings
void read_params(uint8_t profile_id);
// write_params - write new parameters to the gimbal settings
void write_params();
bool get_realtimedata(Vector3f& angle);
// Alexmos Serial Protocol reading part implementation
// send_command - send a command to the Alemox Serial API
void send_command(uint8_t cmd, uint8_t* data, uint8_t size);
// Parse the body of the message received from the Alexmos gimbal
void parse_body();
// read_incoming - detect and read the header of the incoming message from the gimbal
void read_incoming();
// structure for the Serial Protocol
// CMD_BOARD_INFO
struct PACKED alexmos_version {
uint8_t _board_version;
uint16_t _firmware_version;
uint8_t debug_mode;
uint16_t _board_features;
};
// CMD_GET_ANGLES
struct PACKED alexmos_angles {
int16_t angle_roll;
int16_t rc_angle_roll;
int16_t rc_speed_roll;
int16_t angle_pitch;
int16_t rc_angle_pitch;
int16_t rc_speed_pitch;
int16_t angle_yaw;
int16_t rc_angle_yaw;
int16_t rc_speed_yaw;
};
// CMD_CONTROL
struct PACKED alexmos_angles_speed {
int8_t mode;
int16_t speed_roll;
int16_t angle_roll;
int16_t speed_pitch;
int16_t angle_pitch;
int16_t speed_yaw;
int16_t angle_yaw;
};
// CMD_READ_PARAMS
struct PACKED alexmos_params {
uint8_t profile_id;
uint8_t roll_P;
uint8_t roll_I;
uint8_t roll_D;
uint8_t roll_power;
uint8_t roll_invert;
uint8_t roll_poles;
uint8_t pitch_P;
uint8_t pitch_I;
uint8_t pitch_D;
uint8_t pitch_power;
uint8_t pitch_invert;
uint8_t pitch_poles;
uint8_t yaw_P;
uint8_t yaw_I;
uint8_t yaw_D;
uint8_t yaw_power;
uint8_t yaw_invert;
uint8_t yaw_poles;
uint8_t acc_limiter;
int8_t ext_fc_gain_roll;
int8_t ext_fc_gain_pitch;
int16_t roll_rc_min_angle;
int16_t roll_rc_max_angle;
uint8_t roll_rc_mode;
uint8_t roll_rc_lpf;
uint8_t roll_rc_speed;
uint8_t roll_rc_follow;
int16_t pitch_rc_min_angle;
int16_t pitch_rc_max_angle;
uint8_t pitch_rc_mode;
uint8_t pitch_rc_lpf;
uint8_t pitch_rc_speed;
uint8_t pitch_rc_follow;
int16_t yaw_rc_min_angle;
int16_t yaw_rc_max_angle;
uint8_t yaw_rc_mode;
uint8_t yaw_rc_lpf;
uint8_t yaw_rc_speed;
uint8_t yaw_rc_follow;
uint8_t gyro_trust;
uint8_t use_model;
uint8_t pwm_freq;
uint8_t serial_speed;
int8_t rc_trim_roll;
int8_t rc_trim_pitch;
int8_t rc_trim_yaw;
uint8_t rc_deadband;
uint8_t rc_expo_rate;
uint8_t rc_virt_mode;
uint8_t rc_map_roll;
uint8_t rc_map_pitch;
uint8_t rc_map_yaw;
uint8_t rc_map_cmd;
uint8_t rc_map_fc_roll;
uint8_t rc_map_fc_pitch;
uint8_t rc_mix_fc_roll;
uint8_t rc_mix_fc_pitch;
uint8_t follow_mode;
uint8_t follow_deadband;
uint8_t follow_expo_rate;
int8_t follow_offset_roll;
int8_t follow_offset_pitch;
int8_t follow_offset_yaw;
int8_t axis_top;
int8_t axis_right;
uint8_t gyro_lpf;
uint8_t gyro_sens;
uint8_t i2c_internal_pullups;
uint8_t sky_gyro_calib;
uint8_t rc_cmd_low;
uint8_t rc_cmd_mid;
uint8_t rc_cmd_high;
uint8_t menu_cmd_1;
uint8_t menu_cmd_2;
uint8_t menu_cmd_3;
uint8_t menu_cmd_4;
uint8_t menu_cmd_5;
uint8_t menu_cmd_long;
uint8_t output_roll;
uint8_t output_pitch;
uint8_t output_yaw;
int16_t bat_threshold_alarm;
int16_t bat_threshold_motors;
int16_t bat_comp_ref;
uint8_t beeper_modes;
uint8_t follow_roll_mix_start;
uint8_t follow_roll_mix_range;
uint8_t booster_power_roll;
uint8_t booster_power_pitch;
uint8_t booster_power_yaw;
uint8_t follow_speed_roll;
uint8_t follow_speed_pitch;
uint8_t follow_speed_yaw;
uint8_t frame_angle_from_motors;
uint8_t cur_profile_id;
};
union PACKED alexmos_parameters {
DEFINE_BYTE_ARRAY_METHODS
alexmos_version version;
alexmos_angles angles;
alexmos_params params;
alexmos_angles_speed angle_speed;
} _buffer,_current_parameters;
AP_HAL::UARTDriver *_port;
bool _initialised : 1;
// result of the get_boardinfo
uint8_t _board_version;
float _current_firmware_version;
uint8_t _firmware_beta_version;
bool _gimbal_3axis : 1;
bool _gimbal_bat_monitoring : 1;
// keep the last _current_angle values
Vector3f _current_angle;
// CMD_READ_PARAMS has been called once
bool _param_read_once : 1;
// Serial Protocol Variables
uint8_t _checksum;
uint8_t _step;
uint8_t _command_id;
uint8_t _payload_length;
uint8_t _payload_counter;
// confirmed that last command was ok
bool _last_command_confirmed : 1;
};
#endif // HAL_MOUNT_ALEXMOS_ENABLED