ardupilot/libraries/AP_Mount/AP_Mount.h

214 lines
8.3 KiB
C++

/************************************************************
* AP_mount -- library to control a 2 or 3 axis mount. *
* *
* Author: Joe Holdsworth; *
* Ritchie Wilson; *
* Amilcar Lucas; *
* Gregory Fletcher; *
* heavily modified by Randy Mackay *
* *
* Purpose: Move a 2 or 3 axis mount attached to vehicle, *
* Used for mount to track targets or stabilise *
* camera plus other modes. *
* *
* Usage: Use in main code to control mounts attached to *
* vehicle. *
* *
* Comments: All angles in degrees * 100, distances in meters*
* unless otherwise stated. *
************************************************************/
#pragma once
#include <AP_HAL/AP_HAL.h>
#include <AP_AHRS/AP_AHRS.h>
#ifndef HAL_MOUNT_ENABLED
#define HAL_MOUNT_ENABLED !HAL_MINIMIZE_FEATURES
#endif
#ifndef HAL_SOLO_GIMBAL_ENABLED
#define HAL_SOLO_GIMBAL_ENABLED HAL_MOUNT_ENABLED && BOARD_FLASH_SIZE > 1024
#endif
#if HAL_MOUNT_ENABLED
#include <AP_Math/AP_Math.h>
#include <AP_Common/AP_Common.h>
#include <AP_Common/Location.h>
#include <GCS_MAVLink/GCS_MAVLink.h>
// maximum number of mounts
#define AP_MOUNT_MAX_INSTANCES 1
// declare backend classes
class AP_Mount_Backend;
class AP_Mount_Servo;
class AP_Mount_SoloGimbal;
class AP_Mount_Alexmos;
class AP_Mount_SToRM32;
class AP_Mount_SToRM32_serial;
/*
This is a workaround to allow the MAVLink backend access to the
SmallEKF. It would be nice to find a neater solution to this
*/
class AP_Mount
{
// declare backends as friends
friend class AP_Mount_Backend;
friend class AP_Mount_Servo;
friend class AP_Mount_SoloGimbal;
friend class AP_Mount_Alexmos;
friend class AP_Mount_SToRM32;
friend class AP_Mount_SToRM32_serial;
public:
AP_Mount();
/* Do not allow copies */
AP_Mount(const AP_Mount &other) = delete;
AP_Mount &operator=(const AP_Mount&) = delete;
// get singleton instance
static AP_Mount *get_singleton() {
return _singleton;
}
// Enums
enum MountType {
Mount_Type_None = 0, /// no mount
Mount_Type_Servo = 1, /// servo controlled mount
Mount_Type_SoloGimbal = 2, /// Solo's gimbal
Mount_Type_Alexmos = 3, /// Alexmos mount
Mount_Type_SToRM32 = 4, /// SToRM32 mount using MAVLink protocol
Mount_Type_SToRM32_serial = 5 /// SToRM32 mount using custom serial protocol
};
// init - detect and initialise all mounts
void init();
// update - give mount opportunity to update servos. should be called at 10hz or higher
void update();
// used for gimbals that need to read INS data at full rate
void update_fast();
// get_mount_type - returns the type of mount
AP_Mount::MountType get_mount_type() const { return get_mount_type(_primary); }
AP_Mount::MountType get_mount_type(uint8_t instance) const;
// has_pan_control - returns true if the mount has yaw control (required for copters)
bool has_pan_control() const { return has_pan_control(_primary); }
bool has_pan_control(uint8_t instance) const;
// get_mode - returns current mode of mount (i.e. Retracted, Neutral, RC_Targeting, GPS Point)
enum MAV_MOUNT_MODE get_mode() const { return get_mode(_primary); }
enum MAV_MOUNT_MODE get_mode(uint8_t instance) const;
// set_mode - sets mount's mode
// returns true if mode is successfully set
void set_mode(enum MAV_MOUNT_MODE mode) { return set_mode(_primary, mode); }
void set_mode(uint8_t instance, enum MAV_MOUNT_MODE mode);
// set_mode_to_default - restores the mode to it's default mode held in the MNT_DEFLT_MODE parameter
// this operation requires 60us on a Pixhawk/PX4
void set_mode_to_default() { set_mode_to_default(_primary); }
void set_mode_to_default(uint8_t instance);
// set_angle_targets - sets angle targets in degrees
void set_angle_targets(float roll, float tilt, float pan) { set_angle_targets(_primary, roll, tilt, pan); }
void set_angle_targets(uint8_t instance, float roll, float tilt, float pan);
// set_roi_target - sets target location that mount should attempt to point towards
void set_roi_target(const struct Location &target_loc) { set_roi_target(_primary,target_loc); }
void set_roi_target(uint8_t instance, const struct Location &target_loc);
// point at system ID sysid
void set_target_sysid(uint8_t instance, const uint8_t sysid);
void set_target_sysid(const uint8_t sysid) { set_target_sysid(_primary, sysid); }
// mavlink message handling:
MAV_RESULT handle_command_long(const mavlink_command_long_t &packet);
void handle_param_value(const mavlink_message_t &msg);
void handle_message(mavlink_channel_t chan, const mavlink_message_t &msg);
// send a GIMBAL_REPORT message to GCS
void send_gimbal_report(mavlink_channel_t chan);
// send a MOUNT_STATUS message to GCS:
void send_mount_status(mavlink_channel_t chan);
// parameter var table
static const struct AP_Param::GroupInfo var_info[];
protected:
static AP_Mount *_singleton;
// frontend parameters
AP_Int8 _joystick_speed; // joystick gain
// front end members
uint8_t _num_instances; // number of mounts instantiated
uint8_t _primary; // primary mount
AP_Mount_Backend *_backends[AP_MOUNT_MAX_INSTANCES]; // pointers to instantiated mounts
// backend state including parameters
struct mount_state {
// Parameters
AP_Int8 _type; // mount type (None, Servo or MAVLink, see MountType enum)
AP_Int8 _default_mode; // default mode on startup and when control is returned from autopilot
AP_Int8 _stab_roll; // 1 = mount should stabilize earth-frame roll axis, 0 = no stabilization
AP_Int8 _stab_tilt; // 1 = mount should stabilize earth-frame pitch axis
AP_Int8 _stab_pan; // 1 = mount should stabilize earth-frame yaw axis
// RC input channels from receiver used for direct angular input from pilot
AP_Int8 _roll_rc_in; // pilot provides roll input on this channel
AP_Int8 _tilt_rc_in; // pilot provides tilt input on this channel
AP_Int8 _pan_rc_in; // pilot provides pan input on this channel
// Mount's physical limits
AP_Int16 _roll_angle_min; // min roll in 0.01 degree units
AP_Int16 _roll_angle_max; // max roll in 0.01 degree units
AP_Int16 _tilt_angle_min; // min tilt in 0.01 degree units
AP_Int16 _tilt_angle_max; // max tilt in 0.01 degree units
AP_Int16 _pan_angle_min; // min pan in 0.01 degree units
AP_Int16 _pan_angle_max; // max pan in 0.01 degree units
AP_Vector3f _retract_angles; // retracted position for mount, vector.x = roll vector.y = tilt, vector.z=pan
AP_Vector3f _neutral_angles; // neutral position for mount, vector.x = roll vector.y = tilt, vector.z=pan
AP_Float _roll_stb_lead; // roll lead control gain
AP_Float _pitch_stb_lead; // pitch lead control gain
MAV_MOUNT_MODE _mode; // current mode (see MAV_MOUNT_MODE enum)
struct Location _roi_target; // roi target location
bool _roi_target_set;
uint8_t _target_sysid; // sysid to track
Location _target_sysid_location; // sysid target location
bool _target_sysid_location_set;
} state[AP_MOUNT_MAX_INSTANCES];
private:
// Check if instance backend is ok
bool check_primary() const;
bool check_instance(uint8_t instance) const;
void handle_gimbal_report(mavlink_channel_t chan, const mavlink_message_t &msg);
void handle_mount_configure(const mavlink_message_t &msg);
void handle_mount_control(const mavlink_message_t &msg);
MAV_RESULT handle_command_do_mount_configure(const mavlink_command_long_t &packet);
MAV_RESULT handle_command_do_mount_control(const mavlink_command_long_t &packet);
void handle_global_position_int(const mavlink_message_t &msg);
};
namespace AP {
AP_Mount *mount();
};
#endif // HAL_MOUNT_ENABLED