ardupilot/libraries/AP_WheelEncoder/AP_WheelEncoder.h

/*
   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/>.
 */
#pragma once

#include <AP_Common/AP_Common.h>
#include <AP_HAL/AP_HAL.h>
#include <AP_Param/AP_Param.h>
#include <AP_Math/AP_Math.h>

// Maximum number of WheelEncoder measurement instances available on this platform
#define WHEELENCODER_MAX_INSTANCES      2
#define WHEELENCODER_CPR_DEFAULT        3200    // default encoder counts per full revolution of the wheel
#define WHEELENCODER_RADIUS_DEFAULT     0.05f   // default wheel radius of 5cm (0.05m)

class AP_WheelEncoder_Backend; 
 
class AP_WheelEncoder
{
public:
    friend class AP_WheelEncoder_Backend;
    friend class AP_WheelEncoder_Quadrature;

    AP_WheelEncoder(void);

    // WheelEncoder driver types
    enum WheelEncoder_Type {
        WheelEncoder_TYPE_NONE          = 0,
        WheelEncoder_TYPE_QUADRATURE    = 1
    };

    // The WheelEncoder_State structure is filled in by the backend driver
    struct WheelEncoder_State {
        uint8_t                instance;        // the instance number of this WheelEncoder
        int32_t                distance_count;  // cumulative number of forward + backwards events received from wheel encoder
        float                  distance;        // total distance measured
        uint32_t               total_count;     // total number of successful readings from sensor (used for sensor quality calcs)
        uint32_t               error_count;     // total number of errors reading from sensor (used for sensor quality calcs)
        uint32_t               last_reading_ms; // time of last reading
    };

    // detect and initialise any available rpm sensors
    void init(void);

    // update state of all sensors. Should be called from main loop
    void update(void);

    // return the number of wheel encoder sensor instances
    uint8_t num_sensors(void) const { return num_instances; }

    // return true if healthy
    bool healthy(uint8_t instance) const;

    // return true if the instance is enabled
    bool enabled(uint8_t instance) const;

    // get the counts per revolution of the encoder
    uint16_t get_counts_per_revolution(uint8_t instance) const;

    // get the wheel radius in meters
    float get_wheel_radius(uint8_t instance) const;

    // get the position of the wheel associated with the wheel encoder
    Vector3f get_position(uint8_t instance) const;

    // get total delta angle (in radians) measured by the wheel encoder
    float get_delta_angle(uint8_t instance) const;

    // get the total distance traveled in meters or radians
    float get_distance(uint8_t instance) const;

    // get the total number of sensor reading from the encoder
    uint32_t get_total_count(uint8_t instance) const;

    // get the total number of errors reading from the encoder
    uint32_t get_error_count(uint8_t instance) const;

    // get the signal quality for a sensor (0 = extremely poor quality, 100 = extremely good quality)
    float get_signal_quality(uint8_t instance) const;

    // get the system time (in milliseconds) of the last update
    uint32_t get_last_reading_ms(uint8_t instance) const;

    static const struct AP_Param::GroupInfo var_info[];

protected:
    // parameters for each instance
    AP_Int8  _type[WHEELENCODER_MAX_INSTANCES];
    AP_Int16 _counts_per_revolution[WHEELENCODER_MAX_INSTANCES];
    AP_Float _wheel_radius[WHEELENCODER_MAX_INSTANCES];
    AP_Vector3f _pos_offset[WHEELENCODER_MAX_INSTANCES];
    AP_Int8  _pina[WHEELENCODER_MAX_INSTANCES];
    AP_Int8  _pinb[WHEELENCODER_MAX_INSTANCES];

    WheelEncoder_State state[WHEELENCODER_MAX_INSTANCES];
    AP_WheelEncoder_Backend *drivers[WHEELENCODER_MAX_INSTANCES];
    uint8_t num_instances;
};
AP_WheelEncoder: library to read from wheel encoders 2017-07-11 23:01:48 -03:00			`/*`
			`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/>.`
			`*/`
			`#pragma once`

			`#include <AP_Common/AP_Common.h>`
			`#include <AP_HAL/AP_HAL.h>`
			`#include <AP_Param/AP_Param.h>`
			`#include <AP_Math/AP_Math.h>`

			`// Maximum number of WheelEncoder measurement instances available on this platform`
			`#define WHEELENCODER_MAX_INSTANCES 2`
AP_WheelEncoder: replace scaling with CPR and radius CPR is the wheel encoder's counts per revolution of the wheel radius is the radius of the wheel in meters 2017-07-19 09:28:45 -03:00			`#define WHEELENCODER_CPR_DEFAULT 3200 // default encoder counts per full revolution of the wheel`
			`#define WHEELENCODER_RADIUS_DEFAULT 0.05f // default wheel radius of 5cm (0.05m)`
AP_WheelEncoder: library to read from wheel encoders 2017-07-11 23:01:48 -03:00
			`class AP_WheelEncoder_Backend;`

			`class AP_WheelEncoder`
			`{`
			`public:`
			`friend class AP_WheelEncoder_Backend;`
			`friend class AP_WheelEncoder_Quadrature;`

			`AP_WheelEncoder(void);`

			`// WheelEncoder driver types`
			`enum WheelEncoder_Type {`
			`WheelEncoder_TYPE_NONE = 0,`
			`WheelEncoder_TYPE_QUADRATURE = 1`
			`};`

			`// The WheelEncoder_State structure is filled in by the backend driver`
			`struct WheelEncoder_State {`
			`uint8_t instance; // the instance number of this WheelEncoder`
			`int32_t distance_count; // cumulative number of forward + backwards events received from wheel encoder`
			`float distance; // total distance measured`
			`uint32_t total_count; // total number of successful readings from sensor (used for sensor quality calcs)`
			`uint32_t error_count; // total number of errors reading from sensor (used for sensor quality calcs)`
			`uint32_t last_reading_ms; // time of last reading`
			`};`

			`// detect and initialise any available rpm sensors`
			`void init(void);`

			`// update state of all sensors. Should be called from main loop`
			`void update(void);`

			`// return the number of wheel encoder sensor instances`
			`uint8_t num_sensors(void) const { return num_instances; }`

			`// return true if healthy`
			`bool healthy(uint8_t instance) const;`

			`// return true if the instance is enabled`
			`bool enabled(uint8_t instance) const;`

AP_WheelEncoder: replace scaling with CPR and radius CPR is the wheel encoder's counts per revolution of the wheel radius is the radius of the wheel in meters 2017-07-19 09:28:45 -03:00			`// get the counts per revolution of the encoder`
			`uint16_t get_counts_per_revolution(uint8_t instance) const;`

			`// get the wheel radius in meters`
			`float get_wheel_radius(uint8_t instance) const;`

AP_WheelEncoder: library to read from wheel encoders 2017-07-11 23:01:48 -03:00			`// get the position of the wheel associated with the wheel encoder`
AP_WheelEncoder: 3d position offset 2017-07-19 09:27:35 -03:00			`Vector3f get_position(uint8_t instance) const;`
AP_WheelEncoder: library to read from wheel encoders 2017-07-11 23:01:48 -03:00
AP_WheelEncoder: add get_delta_angle The total angular change measured by the wheel encoder in radians 2017-07-20 03:11:45 -03:00			`// get total delta angle (in radians) measured by the wheel encoder`
			`float get_delta_angle(uint8_t instance) const;`

			`// get the total distance traveled in meters or radians`
AP_WheelEncoder: library to read from wheel encoders 2017-07-11 23:01:48 -03:00			`float get_distance(uint8_t instance) const;`

			`// get the total number of sensor reading from the encoder`
			`uint32_t get_total_count(uint8_t instance) const;`

			`// get the total number of errors reading from the encoder`
			`uint32_t get_error_count(uint8_t instance) const;`

			`// get the signal quality for a sensor (0 = extremely poor quality, 100 = extremely good quality)`
			`float get_signal_quality(uint8_t instance) const;`

			`// get the system time (in milliseconds) of the last update`
			`uint32_t get_last_reading_ms(uint8_t instance) const;`

			`static const struct AP_Param::GroupInfo var_info[];`

			`protected:`
			`// parameters for each instance`
			`AP_Int8 _type[WHEELENCODER_MAX_INSTANCES];`
AP_WheelEncoder: replace scaling with CPR and radius CPR is the wheel encoder's counts per revolution of the wheel radius is the radius of the wheel in meters 2017-07-19 09:28:45 -03:00			`AP_Int16 _counts_per_revolution[WHEELENCODER_MAX_INSTANCES];`
			`AP_Float _wheel_radius[WHEELENCODER_MAX_INSTANCES];`
AP_WheelEncoder: 3d position offset 2017-07-19 09:27:35 -03:00			`AP_Vector3f _pos_offset[WHEELENCODER_MAX_INSTANCES];`
AP_WheelEncoder: library to read from wheel encoders 2017-07-11 23:01:48 -03:00			`AP_Int8 _pina[WHEELENCODER_MAX_INSTANCES];`
			`AP_Int8 _pinb[WHEELENCODER_MAX_INSTANCES];`

			`WheelEncoder_State state[WHEELENCODER_MAX_INSTANCES];`
			`AP_WheelEncoder_Backend *drivers[WHEELENCODER_MAX_INSTANCES];`
			`uint8_t num_instances;`
			`};`