mirror of https://github.com/ArduPilot/ardupilot
473 lines
17 KiB
C++
473 lines
17 KiB
C++
#include "AP_Soaring.h"
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#include <AP_Logger/AP_Logger.h>
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#include <GCS_MAVLink/GCS.h>
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#include <stdint.h>
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extern const AP_HAL::HAL& hal;
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#if HAL_SOARING_ENABLED
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// ArduSoar parameters
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const AP_Param::GroupInfo SoaringController::var_info[] = {
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// @Param: ENABLE
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// @DisplayName: Is the soaring mode enabled or not
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// @Description: Toggles the soaring mode on and off
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// @Values: 0:Disable,1:Enable
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// @User: Advanced
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AP_GROUPINFO_FLAGS("ENABLE", 1, SoaringController, soar_active, 0, AP_PARAM_FLAG_ENABLE),
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// @Param: VSPEED
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// @DisplayName: Vertical v-speed
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// @Description: Rate of climb to trigger themalling speed
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// @Units: m/s
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// @Range: 0 10
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// @User: Advanced
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AP_GROUPINFO("VSPEED", 2, SoaringController, thermal_vspeed, 0.7f),
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// @Param: Q1
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// @DisplayName: Process noise
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// @Description: Standard deviation of noise in process for strength
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// @Range: 0.0001 0.01
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// @User: Advanced
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AP_GROUPINFO("Q1", 3, SoaringController, thermal_q1, 0.001f),
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// @Param: Q2
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// @DisplayName: Process noise
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// @Description: Standard deviation of noise in process for position and radius
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// @Range: 0.01 1
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// @User: Advanced
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AP_GROUPINFO("Q2", 4, SoaringController, thermal_q2, 0.03f),
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// @Param: R
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// @DisplayName: Measurement noise
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// @Description: Standard deviation of noise in measurement
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// @Range: 0.01 1
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// @User: Advanced
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AP_GROUPINFO("R", 5, SoaringController, thermal_r, 0.45f),
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// @Param: DIST_AHEAD
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// @DisplayName: Distance to thermal center
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// @Description: Initial guess of the distance to the thermal center
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// @Units: m
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// @Range: 0 100
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// @User: Advanced
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AP_GROUPINFO("DIST_AHEAD", 6, SoaringController, thermal_distance_ahead, 5.0f),
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// @Param: MIN_THML_S
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// @DisplayName: Minimum thermalling time
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// @Description: Minimum number of seconds to spend thermalling
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// @Units: s
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// @Range: 0 600
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// @User: Advanced
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AP_GROUPINFO("MIN_THML_S", 7, SoaringController, min_thermal_s, 20),
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// @Param: MIN_CRSE_S
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// @DisplayName: Minimum cruising time
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// @Description: Minimum number of seconds to spend cruising
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// @Units: s
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// @Range: 0 600
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// @User: Advanced
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AP_GROUPINFO("MIN_CRSE_S", 8, SoaringController, min_cruise_s, 10),
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// @Param: POLAR_CD0
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// @DisplayName: Zero lift drag coef.
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// @Description: Zero lift drag coefficient
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// @Range: 0.005 0.5
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// @User: Advanced
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AP_GROUPINFO("POLAR_CD0", 9, SoaringController, polar_CD0, 0.027),
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// @Param: POLAR_B
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// @DisplayName: Induced drag coeffient
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// @Description: Induced drag coeffient
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// @Range: 0.005 0.05
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// @User: Advanced
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AP_GROUPINFO("POLAR_B", 10, SoaringController, polar_B, 0.031),
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// @Param: POLAR_K
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// @DisplayName: Cl factor
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// @Description: Cl factor 2*m*g/(rho*S)
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// @Units: m.m/s/s
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// @Range: 20 400
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// @User: Advanced
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AP_GROUPINFO("POLAR_K", 11, SoaringController, polar_K, 25.6),
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// @Param: ALT_MAX
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// @DisplayName: Maximum soaring altitude, relative to the home location
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// @Description: Don't thermal any higher than this.
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// @Units: m
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// @Range: 0 5000.0
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// @User: Advanced
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AP_GROUPINFO("ALT_MAX", 12, SoaringController, alt_max, 350.0),
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// @Param: ALT_MIN
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// @DisplayName: Minimum soaring altitude, relative to the home location
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// @Description: Don't get any lower than this.
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// @Units: m
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// @Range: 0 1000.0
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// @User: Advanced
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AP_GROUPINFO("ALT_MIN", 13, SoaringController, alt_min, 50.0),
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// @Param: ALT_CUTOFF
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// @DisplayName: Maximum power altitude, relative to the home location
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// @Description: Cut off throttle at this alt.
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// @Units: m
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// @Range: 0 5000.0
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// @User: Advanced
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AP_GROUPINFO("ALT_CUTOFF", 14, SoaringController, alt_cutoff, 250.0),
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// 15 was SOAR_ENABLE_CH, now RCX_OPTION
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// @Param: MAX_DRIFT
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// @DisplayName: (Optional) Maximum drift distance to allow when thermalling.
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// @Description: The previous mode will be restored if the horizontal distance to the thermalling start location exceeds this value. -1 to disable.
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// @Range: 0 1000
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// @User: Advanced
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AP_GROUPINFO("MAX_DRIFT", 16, SoaringController, max_drift, -1),
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// @Param: MAX_RADIUS
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// @DisplayName: (Optional) Maximum distance from home
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// @Description: RTL will be entered when a thermal is exited and the plane is more than this distance from home. -1 to disable.
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// @Range: 0 1000
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// @User: Advanced
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AP_GROUPINFO("MAX_RADIUS", 17, SoaringController, max_radius, -1),
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// @Param: THML_BANK
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// @DisplayName: Thermalling bank angle
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// @Description: This parameter sets the bank angle to use when thermalling. Typically 30 - 45 degrees works well.
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// @Range: 20 50
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// @User: Advanced
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// @Units: deg
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AP_GROUPINFO("THML_BANK", 18, SoaringController, thermal_bank, 30.0),
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AP_GROUPEND
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};
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SoaringController::SoaringController(AP_TECS &tecs, const AP_Vehicle::FixedWing &parms) :
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_tecs(tecs),
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_vario(parms),
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_aparm(parms),
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_throttle_suppressed(true)
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{
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AP_Param::setup_object_defaults(this, var_info);
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}
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void SoaringController::get_target(Location &wp)
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{
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wp = AP::ahrs().get_home();
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wp.offset(_position_x_filter.get(), _position_y_filter.get());
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}
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bool SoaringController::suppress_throttle()
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{
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float alt = _vario.alt;
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if (_throttle_suppressed && (alt < alt_min)) {
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// Time to throttle up
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set_throttle_suppressed(false);
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} else if ((!_throttle_suppressed) && (alt > alt_cutoff)) {
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// Start glide
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set_throttle_suppressed(true);
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// Zero the pitch integrator - the nose is currently raised to climb, we need to go back to glide.
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_tecs.reset_pitch_I();
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_cruise_start_time_us = AP_HAL::micros64();
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// Reset the filtered vario rate - it is currently elevated due to the climb rate and would otherwise take a while to fall again,
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// leading to false positives.
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_vario.reset_trigger_filter(0.0f);
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}
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return _throttle_suppressed;
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}
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bool SoaringController::check_thermal_criteria()
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{
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return (_last_update_status == ActiveStatus::AUTO_MODE_CHANGE
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&& ((AP_HAL::micros64() - _cruise_start_time_us) > ((unsigned)min_cruise_s * 1e6))
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&& (_vario.get_trigger_value() - _vario.get_exp_thermalling_sink()) > thermal_vspeed
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&& _vario.alt < alt_max
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&& _vario.alt > alt_min);
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}
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SoaringController::LoiterStatus SoaringController::check_cruise_criteria(Vector2f prev_wp, Vector2f next_wp)
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{
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// Check conditions for re-entering cruise. Note that the aircraft needs to also be aligned with the appropriate
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// heading before some of these conditions will actually trigger.
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// The GCS messages are emitted in mode_thermal.cpp. Update these if the logic here is changed.
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if (_last_update_status == ActiveStatus::SOARING_DISABLED) {
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return LoiterStatus::DISABLED;
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}
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LoiterStatus result = LoiterStatus::GOOD_TO_KEEP_LOITERING;
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const float alt = _vario.alt;
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if (_exit_commanded) {
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result = LoiterStatus::EXIT_COMMANDED;
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} else if (alt > alt_max) {
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result = LoiterStatus::ALT_TOO_HIGH;
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} else if (alt < alt_min) {
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result = LoiterStatus::ALT_TOO_LOW;
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} else if ((AP_HAL::micros64() - _thermal_start_time_us) > ((unsigned)min_thermal_s * 1e6)) {
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const float mcCreadyAlt = McCready(alt);
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if (_thermalability < mcCreadyAlt) {
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result = LoiterStatus::THERMAL_WEAK;
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} else if (alt < (-_thermal_start_pos.z) || _vario.get_filtered_climb() < 0.0) {
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result = LoiterStatus::ALT_LOST;
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} else if (check_drift(prev_wp, next_wp)) {
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result = LoiterStatus::DRIFT_EXCEEDED;
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}
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}
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return result;
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}
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void SoaringController::init_thermalling()
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{
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// Calc filter matrices - so that changes to parameters can be updated by switching in and out of thermal mode
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float r = powf(thermal_r, 2); // Measurement noise
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float cov_q1 = powf(thermal_q1, 2); // Process noise for strength
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float cov_q2 = powf(thermal_q2, 2); // Process noise for position and radius
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const float init_q[4] = {cov_q1,
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cov_q2,
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cov_q2,
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cov_q2};
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const MatrixN<float,4> q{init_q};
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const float init_p[4] = {INITIAL_STRENGTH_COVARIANCE,
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INITIAL_RADIUS_COVARIANCE,
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INITIAL_POSITION_COVARIANCE,
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INITIAL_POSITION_COVARIANCE};
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const MatrixN<float,4> p{init_p};
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Vector3f position;
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const AP_AHRS &_ahrs = AP::ahrs();
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if (!_ahrs.get_relative_position_NED_home(position)) {
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return;
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}
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// New state vector filter will be reset. Thermal location is placed in front of a/c
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const float init_xr[4] = {_vario.get_trigger_value(),
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INITIAL_THERMAL_RADIUS,
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position.x + thermal_distance_ahead * cosf(_ahrs.yaw),
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position.y + thermal_distance_ahead * sinf(_ahrs.yaw)};
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const VectorN<float,4> xr{init_xr};
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// Also reset covariance matrix p so filter is not affected by previous data
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_ekf.reset(xr, p, q, r);
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_prev_update_time = AP_HAL::micros64();
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_thermal_start_time_us = AP_HAL::micros64();
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_thermal_start_pos = position;
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_vario.reset_climb_filter(0.0);
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_position_x_filter.reset(_ekf.X[2]);
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_position_y_filter.reset(_ekf.X[3]);
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_exit_commanded = false;
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}
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void SoaringController::init_cruising()
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{
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if (_last_update_status >= ActiveStatus::MANUAL_MODE_CHANGE) {
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_cruise_start_time_us = AP_HAL::micros64();
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// Start glide. Will be updated on the next loop.
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set_throttle_suppressed(true);
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}
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}
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void SoaringController::update_thermalling()
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{
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float deltaT = (AP_HAL::micros64() - _prev_update_time) * 1e-6;
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Vector3f current_position;
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const AP_AHRS &_ahrs = AP::ahrs();
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if (!_ahrs.get_relative_position_NED_home(current_position)) {
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return;
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}
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Vector3f wind_drift = _ahrs.wind_estimate()*deltaT*_vario.get_filtered_climb()/_ekf.X[0];
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// update the filter
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_ekf.update(_vario.reading, current_position.x, current_position.y, wind_drift.x, wind_drift.y);
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_thermalability = (_ekf.X[0]*expf(-powf(get_thermalling_radius()/_ekf.X[1], 2))) - _vario.get_exp_thermalling_sink();
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_prev_update_time = AP_HAL::micros64();
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// Compute smoothed estimate of position
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_position_x_filter.set_cutoff_frequency(1/(3*_vario.tau));
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_position_y_filter.set_cutoff_frequency(1/(3*_vario.tau));
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_position_x_filter.apply(_ekf.X[2], deltaT);
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_position_y_filter.apply(_ekf.X[3], deltaT);
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// write log - save the data.
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// @LoggerMessage: SOAR
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// @Vehicles: Plane
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// @Description: Logged data from soaring feature
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// @URL: https://ardupilot.org/plane/docs/soaring.html
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// @Field: TimeUS: microseconds since system startup
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// @Field: nettorate: Estimate of vertical speed of surrounding airmass
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// @Field: x0: Thermal strength estimate
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// @Field: x1: Thermal radius estimate
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// @Field: x2: Thermal position estimate north from home
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// @Field: x3: Thermal position estimate east from home
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// @Field: north: Aircraft position north from home
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// @Field: east: Aircraft position east from home
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// @Field: alt: Aircraft altitude
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// @Field: dx_w: Wind speed north
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// @Field: dy_w: Wind speed east
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// @Field: th: Estimate of achievable climbrate in thermal
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AP::logger().WriteStreaming("SOAR", "TimeUS,nettorate,x0,x1,x2,x3,north,east,alt,dx_w,dy_w,th", "Qfffffffffff",
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AP_HAL::micros64(),
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(double)_vario.reading,
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(double)_ekf.X[0],
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(double)_ekf.X[1],
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(double)_ekf.X[2],
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(double)_ekf.X[3],
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current_position.x,
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current_position.y,
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(double)_vario.alt,
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(double)wind_drift.x,
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(double)wind_drift.y,
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(double)_thermalability);
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}
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void SoaringController::update_cruising()
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{
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// Reserved for future tasks that need to run continuously while in FBWB or AUTO mode,
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// for example, calculation of optimal airspeed and flap angle.
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}
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void SoaringController::update_vario()
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{
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_vario.update(thermal_bank, polar_K, polar_CD0, polar_B);
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}
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float SoaringController::McCready(float alt)
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{
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// A method shell to be filled in later
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return thermal_vspeed;
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}
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SoaringController::ActiveStatus SoaringController::active_state(bool override_disable) const
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{
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if (override_disable || !soar_active) {
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return ActiveStatus::SOARING_DISABLED;
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}
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return _pilot_desired_state;
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}
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void SoaringController::update_active_state(bool override_disable)
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{
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ActiveStatus status = active_state(override_disable);
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bool state_changed = !(status == _last_update_status);
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if (state_changed) {
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switch (status) {
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case ActiveStatus::SOARING_DISABLED:
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// It's not enabled, but was enabled on the last loop.
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gcs().send_text(MAV_SEVERITY_INFO, "Soaring: Disabled.");
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set_throttle_suppressed(false);
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break;
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case ActiveStatus::MANUAL_MODE_CHANGE:
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// It's enabled, but wasn't on the last loop.
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gcs().send_text(MAV_SEVERITY_INFO, "Soaring: Enabled, manual mode changes.");
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break;
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case ActiveStatus::AUTO_MODE_CHANGE:
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gcs().send_text(MAV_SEVERITY_INFO, "Soaring: Enabled, automatic mode changes.");
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break;
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}
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if (_last_update_status == ActiveStatus::SOARING_DISABLED) {
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// We have switched from disabled into an active mode, start cruising.
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init_cruising();
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} else if (status != ActiveStatus::SOARING_DISABLED) {
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// We switched between active modes. If we're in THERMAL this means we should exit gracefully.
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// This has no effect if we're cruising as it is reset on thermal entry.
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_exit_commanded = true;
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}
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}
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_last_update_status = status;
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}
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void SoaringController::set_throttle_suppressed(bool suppressed)
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{
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_throttle_suppressed = suppressed;
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// Let the TECS know.
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_tecs.set_gliding_requested_flag(suppressed);
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}
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bool SoaringController::check_drift(Vector2f prev_wp, Vector2f next_wp)
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{
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// Check for -1 (disabled)
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if (max_drift<0) {
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return false;
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}
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// Check against the estimated thermal.
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Vector2f position(_ekf.X[2], _ekf.X[3]);
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Vector2f start_pos(_thermal_start_pos.x, _thermal_start_pos.y);
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Vector2f mission_leg = next_wp - prev_wp;
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if (prev_wp.is_zero() || mission_leg.length() < 0.1) {
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// Simple check of distance from initial start point.
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return (position - start_pos).length() > max_drift;
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} else {
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// Regard the effective start point as projected onto mission leg.
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// Calculate drift parallel and perpendicular to mission leg.
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// Drift parallel and in direction of mission leg is acceptable.
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Vector2f effective_start, vec1, vec2;
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// Calculate effective start point (on mission leg).
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vec1 = (start_pos - prev_wp).projected(mission_leg);
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effective_start = prev_wp + vec1;
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// Calculate parallel and perpendicular offsets.
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vec2 = position - effective_start;
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float parallel = vec2 * mission_leg.normalized();
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float perpendicular = (vec2 - mission_leg.normalized()*parallel).length();
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// Check if we've drifted beyond the next wp.
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if (parallel>(next_wp - effective_start).length()) {
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return true;
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}
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// Check if we've drifted too far laterally or backwards. We don't count positive parallel offsets
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// as these are favourable (towards next wp)
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parallel = parallel>0 ? 0 : parallel;
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return (powf(parallel,2)+powf(perpendicular,2)) > powf(max_drift,2);;
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}
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}
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float SoaringController::get_thermalling_radius() const
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{
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// Thermalling radius is controlled by parameter SOAR_THML_BANK and true target airspeed.
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const float target_aspd = _tecs.get_target_airspeed() * AP::ahrs().get_EAS2TAS();
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const float radius = (target_aspd*target_aspd) / (GRAVITY_MSS * tanf(thermal_bank*DEG_TO_RAD));
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return radius;
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}
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#endif // HAL_SOARING_ENABLED
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