mirror of https://github.com/ArduPilot/ardupilot
110 lines
6.0 KiB
C
110 lines
6.0 KiB
C
#pragma once
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#include <AP_HAL/AP_HAL.h>
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#include <AP_HAL/AP_HAL_Boards.h>
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#ifndef HAL_WITH_POSTYPE_DOUBLE
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#define HAL_WITH_POSTYPE_DOUBLE BOARD_FLASH_SIZE > 1024
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#endif
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#if HAL_WITH_POSTYPE_DOUBLE
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typedef double postype_t;
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typedef Vector2d Vector2p;
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typedef Vector3d Vector3p;
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#define topostype todouble
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#else
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typedef float postype_t;
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typedef Vector2f Vector2p;
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typedef Vector3f Vector3p;
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#define topostype tofloat
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#endif
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/*
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common controller helper functions
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*/
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// update_vel_accel projects the velocity, vel, forward in time based on a time step of dt and acceleration of accel.
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// update_vel_accel - single axis projection.
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void update_vel_accel(float& vel, float accel, float dt, float limit);
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// update_vel_accel projects the velocity, vel, forward in time based on a time step of dt and acceleration of accel.
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// update_vel_accel - single axis projection.
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void update_pos_vel_accel(postype_t & pos, float& vel, float accel, float dt, float limit);
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// update_pos_vel_accel_xy - dual axis projection operating on the x, y axis of Vector2f or Vector3f inputs.
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void update_vel_accel_xy(Vector2f& vel, const Vector2f& accel, float dt, Vector2f limit);
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// update_pos_vel_accel_xy - dual axis projection operating on the x, y axis of Vector2f or Vector3f inputs.
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void update_pos_vel_accel_xy(Vector2p& pos, Vector2f& vel, const Vector2f& accel, float dt, Vector2f limit);
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/* shape_accel calculates a jerk limited path from the current acceleration to an input acceleration.
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The function takes the current acceleration and calculates the required jerk limited adjustment to the acceleration for the next time dt.
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The kinematic path is constrained by :
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acceleration limits - accel_min, accel_max,
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time constant - tc.
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The time constant defines the acceleration error decay in the kinematic path as the system approaches constant acceleration.
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The time constant also defines the time taken to achieve the maximum acceleration.
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The time constant must be positive.
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The function alters the variable accel to follow a jerk limited kinematic path to accel_input
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*/
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void shape_accel(const float accel_input, float& accel,
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const float accel_min, const float accel_max,
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const float tc, const float dt);
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void shape_accel_xy(const Vector2f& accel_input, Vector2f& accel,
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const float accel_max, const float tc, const float dt);
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/* shape_vel calculates a jerk limited path from the current velocity and acceleration to an input velocity.
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The function takes the current velocity, and acceleration and calculates the required jerk limited adjustment to the acceleration for the next time dt.
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The kinematic path is constrained by :
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velocity limits - vel_min, vel_max,
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acceleration limits - accel_min, accel_max,
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time constant - tc.
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The time constant defines the acceleration error decay in the kinematic path as the system approaches constant acceleration.
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The time constant also defines the time taken to achieve the maximum acceleration.
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The time constant must be positive.
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The function alters the variable accel to follow a jerk limited kinematic path to vel_input and accel_input
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*/
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void shape_vel_accel(const float vel_input, const float accel_input,
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const float vel, float& accel,
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const float vel_min, const float vel_max,
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const float accel_min, const float accel_max,
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const float tc, const float dt);
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void shape_vel_accel_xy(const Vector2f &vel_input, const Vector2f& accel_input,
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const Vector2f& vel, Vector2f& accel,
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const float vel_max, const float accel_max, const float tc, const float dt);
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/* shape_pos_vel calculate a jerk limited path from the current position, velocity and acceleration to an input position and velocity.
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The function takes the current position, velocity, and acceleration and calculates the required jerk limited adjustment to the acceleration for the next time dt.
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The kinematic path is constrained by :
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maximum velocity - vel_max,
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maximum acceleration - accel_max,
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time constant - tc.
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The time constant defines the acceleration error decay in the kinematic path as the system approaches constant acceleration.
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The time constant also defines the time taken to achieve the maximum acceleration.
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The time constant must be positive.
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The function alters the variable accel to follow a jerk limited kinematic path to pos_input, vel_input and accel_input
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*/
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void shape_pos_vel_accel(const postype_t pos_input, const float vel_input, const float accel_input,
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const postype_t pos, const float vel, float& accel,
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const float vel_correction_max, const float vel_min, const float vel_max,
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const float accel_min, const float accel_max, const float tc, const float dt);
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void shape_pos_vel_accel_xy(const Vector2p& pos_input, const Vector2f& vel_input, const Vector2f& accel_input,
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const Vector2p& pos, const Vector2f& vel, Vector2f& accel,
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const float vel_correction_max, const float vel_max, const float accel_max, const float tc, const float dt);
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// proportional controller with piecewise sqrt sections to constrain second derivative
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float sqrt_controller(float error, float p, float second_ord_lim, float dt);
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// proportional controller with piecewise sqrt sections to constrain second derivative
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Vector2f sqrt_controller(const Vector2f& error, float p, float second_ord_lim, float dt);
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// inverse of the sqrt controller. calculates the input (aka error) to the sqrt_controller required to achieve a given output
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float inv_sqrt_controller(float output, float p, float D_max);
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// calculate the stopping distance for the square root controller based deceleration path
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float stopping_distance(float velocity, float p, float accel_max);
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// calculate the maximum acceleration or velocity in a given direction
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// based on horizontal and vertical limits.
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float kinematic_limit(Vector3f direction, float max_xy, float max_z_pos, float max_z_neg);
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