#pragma once #include #include #include class AP_SteerController { public: AP_SteerController() { AP_Param::setup_object_defaults(this, var_info); } /* Do not allow copies */ CLASS_NO_COPY(AP_SteerController); /* return a steering servo output from -4500 to 4500 given a desired lateral acceleration rate in m/s/s. Positive lateral acceleration is to the right. */ int32_t get_steering_out_lat_accel(float desired_accel); /* return a steering servo output from -4500 to 4500 given a desired yaw rate in degrees/sec. Positive yaw is to the right. */ int32_t get_steering_out_rate(float desired_rate); /* return a steering servo output from -4500 to 4500 given a yaw error in centi-degrees */ int32_t get_steering_out_angle_error(int32_t angle_err); /* return the steering radius (half diameter). Assumed to be half the P value. */ float get_turn_radius(void) const { return _K_P * 0.5f; } void reset_I(); static const struct AP_Param::GroupInfo var_info[]; const class AP_PIDInfo& get_pid_info(void) const { return _pid_info; } void set_reverse(bool reverse) { _reverse = reverse; } // Returns true if controller has been run recently bool active() const; private: AP_Float _tau; AP_Float _K_FF; AP_Float _K_P; AP_Float _K_I; AP_Float _K_D; AP_Float _minspeed; AP_Int16 _imax; uint32_t _last_t; float _last_out; AP_Float _deratespeed; AP_Float _deratefactor; AP_Float _mindegree; AP_PIDInfo _pid_info {}; bool _reverse; };