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/**
 * @file tecs.cpp
 *
 * @author Paul Riseborough
 */

#pragma once

#include <mathlib/mathlib.h>
#include <matrix/math.hpp>
#include <lib/ecl/AlphaFilter/AlphaFilter.hpp>

class TECS
{
public:
	TECS() = default;
	~TECS() = default;

	// no copy, assignment, move, move assignment
	TECS(const TECS &) = delete;
	TECS &operator=(const TECS &) = delete;
	TECS(TECS &&) = delete;
	TECS &operator=(TECS &&) = delete;

	/**
	 * Get the current airspeed status
	 *
	 * @return true if airspeed is enabled for control
	 */
	bool airspeed_sensor_enabled() { return _airspeed_enabled; }

	/**
	 * Set the airspeed enable state
	 */
	void enable_airspeed(bool enabled) { _airspeed_enabled = enabled; }

	/**
	 * Updates the following vehicle kineamtic state estimates:
	 * Vertical position, velocity and acceleration.
	 * Speed derivative
	 * Must be called prior to udating tecs control loops
	 * Must be called at 50Hz or greater
	 */
	void update_vehicle_state_estimates(float equivalent_airspeed, const float speed_deriv_forward, bool altitude_lock,
					    bool in_air,
					    float altitude, float vz);

	/**
	 * Update the control loop calculations
	 */
	void update_pitch_throttle(float pitch, float baro_altitude, float hgt_setpoint,
				   float EAS_setpoint, float equivalent_airspeed, float eas_to_tas, bool climb_out_setpoint, float pitch_min_climbout,
				   float throttle_min, float throttle_setpoint_max, float throttle_cruise,
				   float pitch_limit_min, float pitch_limit_max);

	float get_throttle_setpoint() { return _last_throttle_setpoint; }
	float get_pitch_setpoint() { return _last_pitch_setpoint; }
	float get_speed_weight() { return _pitch_speed_weight; }

	void reset_state() { _states_initialized = false; }

	enum ECL_TECS_MODE {
		ECL_TECS_MODE_NORMAL = 0,
		ECL_TECS_MODE_UNDERSPEED,
		ECL_TECS_MODE_BAD_DESCENT,
		ECL_TECS_MODE_CLIMBOUT
	};

	void set_detect_underspeed_enabled(bool enabled) { _detect_underspeed_enabled = enabled; }

	// setters for controller parameters
	void set_integrator_gain_throttle(float gain) { _integrator_gain_throttle = gain; }
	void set_integrator_gain_pitch(float gain) { _integrator_gain_pitch = gain; }

	void set_min_sink_rate(float rate) { _min_sink_rate = rate; }
	void set_max_sink_rate(float sink_rate) { _max_sink_rate = sink_rate; }
	void set_max_climb_rate(float climb_rate) { _max_climb_rate = climb_rate; }

	void set_heightrate_ff(float heightrate_ff) { _height_setpoint_gain_ff = heightrate_ff; }
	void set_height_error_time_constant(float time_const) { _height_error_gain = 1.0f / math::max(time_const, 0.1f); }

	void set_equivalent_airspeed_max(float airspeed) { _equivalent_airspeed_max = airspeed; }
	void set_equivalent_airspeed_min(float airspeed) { _equivalent_airspeed_min = airspeed; }

	void set_pitch_damping(float damping) { _pitch_damping_gain = damping; }
	void set_vertical_accel_limit(float limit) { _vert_accel_limit = limit; }

	void set_speed_comp_filter_omega(float omega) { _tas_estimate_freq = omega; }
	void set_speed_weight(float weight) { _pitch_speed_weight = weight; }
	void set_airspeed_error_time_constant(float time_const) { _airspeed_error_gain = 1.0f / math::max(time_const, 0.1f); }

	void set_throttle_damp(float throttle_damp) { _throttle_damping_gain = throttle_damp; }
	void set_throttle_slewrate(float slewrate) { _throttle_slewrate = slewrate; }

	void set_roll_throttle_compensation(float compensation) { _load_factor_correction = compensation; }
	void set_load_factor(float load_factor) { _load_factor = load_factor; }

	void set_ste_rate_time_const(float time_const) { _STE_rate_time_const = time_const; }
	void set_speed_derivative_time_constant(float time_const) { _speed_derivative_time_const = time_const; }

	void set_seb_rate_ff_gain(float ff_gain) { _SEB_rate_ff = ff_gain; }


	// TECS status
	uint64_t timestamp() { return _pitch_update_timestamp; }
	ECL_TECS_MODE tecs_mode() { return _tecs_mode; }

	float hgt_setpoint_adj() { return _hgt_setpoint_adj; }
	float vert_pos_state() { return _vert_pos_state; }

	float TAS_setpoint_adj() { return _TAS_setpoint_adj; }
	float tas_state() { return _tas_state; }

	float hgt_rate_setpoint() { return _hgt_rate_setpoint; }
	float vert_vel_state() { return _vert_vel_state; }

	float get_EAS_setpoint() { return _EAS_setpoint; };
	float TAS_rate_setpoint() { return _TAS_rate_setpoint; }
	float speed_derivative() { return _speed_derivative; }

	float STE_error() { return _STE_error; }
	float STE_rate_error() { return _STE_rate_error; }

	float SEB_error() { return _SEB_error; }
	float SEB_rate_error() { return _SEB_rate_error; }

	float throttle_integ_state() { return _throttle_integ_state; }
	float pitch_integ_state() { return _pitch_integ_state; }

	float STE() { return _SPE_estimate + _SKE_estimate; }

	float STE_setpoint() { return _SPE_setpoint + _SKE_setpoint; }

	float STE_rate() { return _SPE_rate + _SKE_rate; }

	float STE_rate_setpoint() { return _SPE_rate_setpoint + _SKE_rate_setpoint; }

	float SEB() { return _SPE_estimate * _SPE_weighting - _SKE_estimate * _SKE_weighting; }

	float SEB_setpoint() { return _SPE_setpoint * _SPE_weighting - _SKE_setpoint * _SKE_weighting; }

	float SEB_rate() { return _SPE_rate * _SPE_weighting - _SKE_rate * _SKE_weighting; }

	float SEB_rate_setpoint() { return _SPE_rate_setpoint * _SPE_weighting - _SKE_rate_setpoint * _SKE_weighting; }


	/**
	 * Handle the altitude reset
	 *
	 * If the estimation system resets the height in one discrete step this
	 * will gracefully even out the reset over time.
	 */
	void handle_alt_step(float delta_alt, float altitude)
	{
		// add height reset delta to all variables involved
		// in filtering the demanded height
		_hgt_setpoint_in_prev += delta_alt;
		_hgt_setpoint_prev += delta_alt;
		_hgt_setpoint_adj_prev += delta_alt;

		// reset height states
		_vert_pos_state = altitude;
		_vert_vel_state = 0.0f;
	}

private:

	enum ECL_TECS_MODE _tecs_mode {ECL_TECS_MODE_NORMAL};

	// timestamps
	uint64_t _state_update_timestamp{0};				///< last timestamp of the 50 Hz function call
	uint64_t _speed_update_timestamp{0};				///< last timestamp of the speed function call
	uint64_t _pitch_update_timestamp{0};				///< last timestamp of the pitch function call

	// controller parameters
	float _tas_estimate_freq{0.0f};					///< cross-over frequency of the true airspeed complementary filter (rad/sec)
	float _max_climb_rate{2.0f};					///< climb rate produced by max allowed throttle (m/sec)
	float _min_sink_rate{1.0f};					///< sink rate produced by min allowed throttle (m/sec)
	float _max_sink_rate{2.0f};					///< maximum safe sink rate (m/sec)
	float _pitch_damping_gain{0.0f};				///< damping gain of the pitch demand calculation (sec)
	float _throttle_damping_gain{0.0f};				///< damping gain of the throttle demand calculation (sec)
	float _integrator_gain_throttle{0.0f};				///< integrator gain used by the throttle demand calculation
	float _integrator_gain_pitch{0.0f};				///< integrator gain used by the pitch demand calculation
	float _vert_accel_limit{0.0f};					///< magnitude of the maximum vertical acceleration allowed (m/sec**2)
	float _load_factor{0.0f};					///< additional normal load factor
	float _load_factor_correction{0.0f};				///< gain from normal load factor increase to total energy rate demand (m**2/sec**3)
	float _pitch_speed_weight{1.0f};				///< speed control weighting used by pitch demand calculation
	float _height_error_gain{0.2f};					///< height error inverse time constant [1/s]
	float _height_setpoint_gain_ff{0.0f};				///< gain from height demand derivative to demanded climb rate
	float _airspeed_error_gain{0.1f};				///< airspeed error inverse time constant [1/s]
	float _equivalent_airspeed_min{3.0f};				///< equivalent airspeed demand lower limit (m/sec)
	float _equivalent_airspeed_max{30.0f};				///< equivalent airspeed demand upper limit (m/sec)
	float _throttle_slewrate{0.0f};					///< throttle demand slew rate limit (1/sec)
	float _STE_rate_time_const{0.1f};				///< filter time constant for specific total energy rate (damping path) (s)
	float _speed_derivative_time_const{0.01f};			///< speed derivative filter time constant (s)
	float _SEB_rate_ff{1.0f};

	// complimentary filter states
	float _vert_vel_state{0.0f};					///< complimentary filter state - height rate (m/sec)
	float _vert_pos_state{0.0f};					///< complimentary filter state - height (m)
	float _tas_rate_state{0.0f};					///< complimentary filter state - true airspeed first derivative (m/sec**2)
	float _tas_state{0.0f};						///< complimentary filter state - true airspeed (m/sec)

	// controller states
	float _throttle_integ_state{0.0f};				///< throttle integrator state
	float _pitch_integ_state{0.0f};					///< pitch integrator state (rad)
	float _last_throttle_setpoint{0.0f};				///< throttle demand rate limiter state (1/sec)
	float _last_pitch_setpoint{0.0f};				///< pitch demand rate limiter state (rad/sec)
	float _speed_derivative{0.0f};					///< rate of change of speed along X axis (m/sec**2)

	// speed demand calculations
	float _EAS{0.0f};						///< equivalent airspeed (m/sec)
	float _TAS_max{30.0f};						///< true airpeed demand upper limit (m/sec)
	float _TAS_min{3.0f};						///< true airpeed demand lower limit (m/sec)
	float _TAS_setpoint{0.0f};					///< current airpeed demand (m/sec)
	float _TAS_setpoint_last{0.0f};					///< previous true airpeed demand (m/sec)
	float _EAS_setpoint{0.0f};					///< Equivalent airspeed demand (m/sec)
	float _TAS_setpoint_adj{0.0f};					///< true airspeed demand tracked by the TECS algorithm (m/sec)
	float _TAS_rate_setpoint{0.0f};					///< true airspeed rate demand tracked by the TECS algorithm (m/sec**2)

	// height demand calculations
	float _hgt_setpoint{0.0f};					///< demanded height tracked by the TECS algorithm (m)
	float _hgt_setpoint_in_prev{0.0f};				///< previous value of _hgt_setpoint after noise filtering (m)
	float _hgt_setpoint_prev{0.0f};					///< previous value of _hgt_setpoint after noise filtering and rate limiting (m)
	float _hgt_setpoint_adj{0.0f};					///< demanded height used by the control loops after all filtering has been applied (m)
	float _hgt_setpoint_adj_prev{0.0f};				///< value of _hgt_setpoint_adj from previous frame (m)
	float _hgt_rate_setpoint{0.0f};					///< demanded climb rate tracked by the TECS algorithm

	// vehicle physical limits
	float _pitch_setpoint_unc{0.0f};				///< pitch demand before limiting (rad)
	float _STE_rate_max{0.0f};					///< specific total energy rate upper limit achieved when throttle is at _throttle_setpoint_max (m**2/sec**3)
	float _STE_rate_min{0.0f};					///< specific total energy rate lower limit acheived when throttle is at _throttle_setpoint_min (m**2/sec**3)
	float _throttle_setpoint_max{0.0f};				///< normalised throttle upper limit
	float _throttle_setpoint_min{0.0f};				///< normalised throttle lower limit
	float _pitch_setpoint_max{0.5f};				///< pitch demand upper limit (rad)
	float _pitch_setpoint_min{-0.5f};				///< pitch demand lower limit (rad)

	// specific energy quantities
	float _SPE_setpoint{0.0f};					///< specific potential energy demand (m**2/sec**2)
	float _SKE_setpoint{0.0f};					///< specific kinetic energy demand (m**2/sec**2)
	float _SPE_rate_setpoint{0.0f};					///< specific potential energy rate demand (m**2/sec**3)
	float _SKE_rate_setpoint{0.0f};					///< specific kinetic energy rate demand (m**2/sec**3)
	float _SPE_estimate{0.0f};					///< specific potential energy estimate (m**2/sec**2)
	float _SKE_estimate{0.0f};					///< specific kinetic energy estimate (m**2/sec**2)
	float _SPE_rate{0.0f};						///< specific potential energy rate estimate (m**2/sec**3)
	float _SKE_rate{0.0f};						///< specific kinetic energy rate estimate (m**2/sec**3)

	// specific energy error quantities
	float _STE_error{0.0f};						///< specific total energy error (m**2/sec**2)
	float _STE_rate_error{0.0f};					///< specific total energy rate error (m**2/sec**3)
	float _SEB_error{0.0f};						///< specific energy balance error (m**2/sec**2)
	float _SEB_rate_error{0.0f};					///< specific energy balance rate error (m**2/sec**3)

	// speed height weighting
	float _SPE_weighting{1.0f};
	float _SKE_weighting{1.0f};

	// time steps (non-fixed)
	float _dt{DT_DEFAULT};						///< Time since last update of main TECS loop (sec)
	static constexpr float DT_DEFAULT = 0.02f;			///< default value for _dt (sec)

	// controller mode logic
	bool _underspeed_detected{false};				///< true when an underspeed condition has been detected
	bool _detect_underspeed_enabled{true};				///< true when underspeed detection is enabled
	bool _uncommanded_descent_recovery{false};			///< true when a continuous descent caused by an unachievable airspeed demand has been detected
	bool _climbout_mode_active{false};				///< true when in climbout mode
	bool _airspeed_enabled{false};					///< true when airspeed use has been enabled
	bool _states_initialized{false};					///< true when TECS states have been iniitalized
	bool _in_air{false};						///< true when the vehicle is flying

	/**
	 * Update the airspeed internal state using a second order complementary filter
	 */
	void _update_speed_states(float airspeed_setpoint, float equivalent_airspeed, float cas_to_tas);

	/**
	 * Update the desired airspeed
	 */
	void _update_speed_setpoint();

	/**
	 * Update the desired height
	 */
	void _update_height_setpoint(float desired, float state);

	/**
	 * Detect if the system is not capable of maintaining airspeed
	 */
	void _detect_underspeed();

	/**
	 * Update specific energy
	 */
	void _update_energy_estimates();

	/**
	 * Update throttle setpoint
	 */
	void _update_throttle_setpoint(float throttle_cruise);

	/**
	 * Detect an uncommanded descent
	 */
	void _detect_uncommanded_descent();

	/**
	 * Update the pitch setpoint
	 */
	void _update_pitch_setpoint();

	/**
	 * Initialize the controller
	 */
	void _initialize_states(float pitch, float throttle_cruise, float baro_altitude, float pitch_min_climbout,
				float eas_to_tas);

	/**
	 * Calculate specific total energy rate limits
	 */
	void _update_STE_rate_lim();

	void _update_speed_height_weights();

	AlphaFilter<float> _STE_rate_error_filter;

	AlphaFilter<float> _TAS_rate_filter;

};