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Ardupilot2/ArduCopter/control_hybrid.pde
Randy Mackay 55e7e1eb3e Copter: allow HYBRID to be disabled to save flash 
Hybrid flight mode costs 4.5k of flash which currently puts us over the
limit for APM1 and APM2 unless optical flow or other features are
disabled
2014-04-23 15:27:05 +09:00

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/// -*- tab-width: 4; Mode: C++; c-basic-offset: 4; indent-tabs-mode: nil -*-
#if HYBRID_ENABLED == ENABLED
/*
* control_hybrid.pde - init and run calls for hybrid flight mode
* hybrid tries to improve upon regular loiter by mixing the pilot input with the loiter controller
*/
#define HYBRID_SPEED_0 10 // speed below which it is always safe to switch to loiter
#if MAIN_LOOP_RATE == 100
// definitions for 100hz loop update rate
# define HYBRID_BRAKE_TIME_ESTIMATE_MAX 600 // max number of cycles the brake will be applied before we switch to loiter
# define HYBRID_BRAKE_TO_LOITER_TIMER 150 // Number of cycles to transition from brake mode to loiter mode.
# define HYBRID_CONTROLLER_TO_PILOT_MIX_TIMER 50 // Set it from 100 to 200, the number of centiseconds loiter and manual commands are mixed to make a smooth transition.
# define HYBRID_SMOOTH_RATE_FACTOR 0.05f // filter applied to pilot's roll/pitch input as it returns to center. A lower number will cause the roll/pitch to return to zero more slowly if the brake_rate is also low.
# define HYBRID_WIND_COMP_TIMER_10HZ 10 // counter value used to reduce wind compensation to 10hz
# define LOOP_RATE_FACTOR 1 // used to adapt hybrid params to loop_rate
# define TC_WIND_COMP 0.01f // Time constant for hybrid_update_wind_comp_estimate()
#else
// definitions for 400hz loop update rate
# define HYBRID_BRAKE_TIME_ESTIMATE_MAX (600*4) // max number of cycles the brake will be applied before we switch to loiter
# define HYBRID_BRAKE_TO_LOITER_TIMER (150*4) // Number of cycles to transition from brake mode to loiter mode. Must be lower than HYBRID_LOITER_STAB_TIMER
# define HYBRID_CONTROLLER_TO_PILOT_MIX_TIMER (50*4) // Set it from 100 to 200, the number of centiseconds loiter and manual commands are mixed to make a smooth transition.
# define HYBRID_SMOOTH_RATE_FACTOR 0.0125f // filter applied to pilot's roll/pitch input as it returns to center. A lower number will cause the roll/pitch to return to zero more slowly if the brake_rate is also low.
# define HYBRID_WIND_COMP_TIMER_10HZ 40 // counter value used to reduce wind compensation to 10hz
# define LOOP_RATE_FACTOR 4 // used to adapt hybrid params to loop_rate
# define TC_WIND_COMP 0.0025f // Time constant for hybrid_update_wind_comp_estimate()
#endif
// definitions that are independent of main loop rate
#define HYBRID_STICK_RELEASE_SMOOTH_ANGLE 1800 // max angle required (in centi-degrees) after which the smooth stick release effect is applied
#define HYBRID_WIND_COMP_START_TIMER 15 // delay (in 10zh increments) to start of wind compensation after loiter is engaged
#define HYBRID_WIND_COMP_ESTIMATE_SPEED_MAX 10 // wind compensation estimates will only run when velocity is at or below this speed in cm/s
// declare some function to keep compiler happy
static void hybrid_update_pilot_lean_angle(int16_t &lean_angle_filtered, int16_t &lean_angle_raw);
static int16_t hybrid_mix_controls(float mix_ratio, int16_t first_control, int16_t second_control);
static void hybrid_update_brake_angle_from_velocity(int16_t &brake_angle, float velocity);
static void hybrid_update_wind_comp_estimate();
static void hybrid_get_wind_comp_lean_angles(int16_t &roll_angle, int16_t &pitch_angle);
static void hybrid_roll_controller_to_pilot_override();
static void hybrid_pitch_controller_to_pilot_override();
// mission state enumeration
enum hybrid_rp_mode {
HYBRID_PILOT_OVERRIDE=0, // pilot is controlling this axis (i.e. roll or pitch)
HYBRID_BRAKE, // this axis is braking towards zero
HYBRID_BRAKE_READY_TO_LOITER, // this axis has completed braking and is ready to enter loiter mode (both modes must be this value before moving to next stage)
HYBRID_BRAKE_TO_LOITER, // both vehicle's axis (roll and pitch) are transitioning from braking to loiter mode (braking and loiter controls are mixed)
HYBRID_LOITER, // both vehicle axis are holding position
HYBRID_CONTROLLER_TO_PILOT_OVERRIDE // pilot has input controls on this axis and this axis is transitioning to pilot override (other axis will transition to brake if no pilot input)
};
static struct {
hybrid_rp_mode roll_mode : 3; // roll mode: pilot override, brake or loiter
hybrid_rp_mode pitch_mode : 3; // pitch mode: pilot override, brake or loiter
uint8_t braking_time_updated_roll : 1; // true once we have re-estimated the braking time. This is done once as the vehicle begins to flatten out after braking
uint8_t braking_time_updated_pitch : 1; // true once we have re-estimated the braking time. This is done once as the vehicle begins to flatten out after braking
uint8_t loiter_reset_I : 1; // true the very first time hybrid enters loiter, thereafter we trust the i terms loiter has
// pilot input related variables
int16_t pilot_roll; // pilot requested roll angle (filtered to slow returns to zero)
int16_t pilot_pitch; // pilot requested roll angle (filtered to slow returns to zero)
// braking related variables
float brake_gain; // gain used during conversion of vehicle's velocity to lean angle during braking (calculated from brake_rate)
int16_t brake_roll; // target roll angle during braking periods
int16_t brake_pitch; // target pitch angle during braking periods
int16_t brake_timeout_roll; // number of cycles allowed for the braking to complete, this timeout will be updated at half-braking
int16_t brake_timeout_pitch; // number of cycles allowed for the braking to complete, this timeout will be updated at half-braking
int16_t brake_angle_max_roll; // maximum lean angle achieved during braking. Used to determine when the vehicle has begun to flatten out so that we can re-estimate the braking time
int16_t brake_angle_max_pitch; // maximum lean angle achieved during braking Used to determine when the vehicle has begun to flatten out so that we can re-estimate the braking time
int16_t brake_to_loiter_timer; // cycles to mix brake and loiter controls in HYBRID_BRAKE_TO_LOITER
// loiter related variables
int16_t controller_to_pilot_timer_roll; // cycles to mix controller and pilot controls in HYBRID_CONTROLLER_TO_PILOT
int16_t controller_to_pilot_timer_pitch; // cycles to mix controller and pilot controls in HYBRID_CONTROLLER_TO_PILOT
int16_t controller_final_roll; // final roll angle from controller as we exit brake or loiter mode (used for mixing with pilot input)
int16_t controller_final_pitch; // final pitch angle from controller as we exit brake or loiter mode (used for mixing with pilot input)
// wind compensation related variables
Vector2f wind_comp_ef; // wind compensation in earth frame, filtered lean angles from position controller
int16_t wind_comp_roll; // roll angle to compensate for wind
int16_t wind_comp_pitch; // pitch angle to compensate for wind
int8_t wind_comp_start_timer; // counter to delay start of wind compensation for a short time after loiter is engaged
int8_t wind_comp_est_timer; // counter to reduce wind comp calcs to 10hz
int8_t wind_comp_lean_angle_timer; // counter to reduce wind comp roll/pitch lean angle calcs to 10hz
// final output
int16_t roll; // final roll angle sent to attitude controller
int16_t pitch; // final pitch angle sent to attitude controller
} hybrid;
// hybrid_init - initialise hybrid controller
static bool hybrid_init(bool ignore_checks)
{
// fail to initialise hybrid mode if no GPS lock
if (!GPS_ok() && !ignore_checks) {
return false;
}
// initialise altitude target to stopping point
pos_control.set_target_to_stopping_point_z();
// initialize vertical speeds and leash lengths
pos_control.set_speed_z(-g.pilot_velocity_z_max, g.pilot_velocity_z_max);
// initialise lean angles to current attitude
hybrid.pilot_roll = 0;
hybrid.pilot_pitch = 0;
// compute brake_gain
hybrid.brake_gain = (15.0f * (float)g.hybrid_brake_rate + 95.0f) / 100.0f;
if (ap.land_complete) {
// if landed begin in loiter mode
hybrid.roll_mode = HYBRID_LOITER;
hybrid.pitch_mode = HYBRID_LOITER;
// set target to current position
// only init here as we can switch to hybrid in flight with a velocity <> 0 that will be used as _last_vel in PosControl and never updated again as we inhibit Reset_I
wp_nav.init_loiter_target();
}else{
// if not landed start in pilot override to avoid hard twitch
hybrid.roll_mode = HYBRID_PILOT_OVERRIDE;
hybrid.pitch_mode = HYBRID_PILOT_OVERRIDE;
}
// loiter's I terms should be reset the first time only
hybrid.loiter_reset_I = true;
// initialise wind_comp each time hybrid is switched on
hybrid.wind_comp_ef.zero();
hybrid.wind_comp_roll = 0;
hybrid.wind_comp_pitch = 0;
hybrid.wind_comp_est_timer = 0;
hybrid.wind_comp_lean_angle_timer = 0;
return true;
}
// hybrid_run - runs the hybrid controller
// should be called at 100hz or more
static void hybrid_run()
{
int16_t target_roll, target_pitch; // pilot's roll and pitch angle inputs
float target_yaw_rate = 0; // pilot desired yaw rate in centi-degrees/sec
int16_t target_climb_rate = 0; // pilot desired climb rate in centimeters/sec
float brake_to_loiter_mix; // mix of brake and loiter controls. 0 = fully brake controls, 1 = fully loiter controls
float controller_to_pilot_roll_mix; // mix of controller and pilot controls. 0 = fully last controller controls, 1 = fully pilot controls
float controller_to_pilot_pitch_mix; // mix of controller and pilot controls. 0 = fully last controller controls, 1 = fully pilot controls
float vel_fw, vel_right; // vehicle's current velocity in body-frame forward and right directions
const Vector3f& vel = inertial_nav.get_velocity();
// if not auto armed set throttle to zero and exit immediately
if(!ap.auto_armed || !inertial_nav.position_ok()) {
wp_nav.init_loiter_target();
attitude_control.init_targets();
attitude_control.set_throttle_out(0, false);
return;
}
// process pilot inputs
if (!failsafe.radio) {
// apply SIMPLE mode transform to pilot inputs
update_simple_mode();
// get pilot's desired yaw rate
target_yaw_rate = get_pilot_desired_yaw_rate(g.rc_4.control_in);
// get pilot desired climb rate (for alt-hold mode and take-off)
target_climb_rate = get_pilot_desired_climb_rate(g.rc_3.control_in);
// check for pilot requested take-off
if (ap.land_complete && target_climb_rate > 0) {
// indicate we are taking off
set_land_complete(false);
// clear i term when we're taking off
set_throttle_takeoff();
}
}
// if landed initialise loiter targets, set throttle to zero and exit
if (ap.land_complete) {
wp_nav.init_loiter_target();
attitude_control.init_targets();
attitude_control.set_throttle_out(0, false);
return;
}else{
// convert pilot input to lean angles
get_pilot_desired_lean_angles(g.rc_1.control_in, g.rc_2.control_in, target_roll, target_pitch);
// retrieve latest wind compensation lean angles
hybrid_get_wind_comp_lean_angles(hybrid.wind_comp_roll, hybrid.wind_comp_pitch);
// convert inertial nav earth-frame velocities to body-frame
// To-Do: move this to AP_Math (or perhaps we already have a function to do this)
vel_fw = vel.x*ahrs.cos_yaw() + vel.y*ahrs.sin_yaw();
vel_right = -vel.x*ahrs.sin_yaw() + vel.y*ahrs.cos_yaw();
// If not in LOITER, get wind_comp related to current yaw
if (hybrid.roll_mode != HYBRID_LOITER || hybrid.pitch_mode != HYBRID_LOITER)
hybrid_get_wind_comp_lean_angles(hybrid.wind_comp_roll, hybrid.wind_comp_pitch);
// Roll state machine
// Each state (aka mode) is responsible for:
// 1. dealing with pilot input
// 2. calculating the final roll output to the attitude controller
// 3. checking if the state (aka mode) should be changed and if 'yes' perform any required initialisation for the new state
switch (hybrid.roll_mode) {
case HYBRID_PILOT_OVERRIDE:
// update pilot desired roll angle using latest radio input
// this filters the input so that it returns to zero no faster than the brake-rate
hybrid_update_pilot_lean_angle(hybrid.pilot_roll, target_roll);
// switch to BRAKE mode for next iteration if no pilot input
if ((target_roll == 0) && (abs(hybrid.pilot_roll) < 2 * g.hybrid_brake_rate)) {
// initialise BRAKE mode
hybrid.roll_mode = HYBRID_BRAKE; // Set brake roll mode
hybrid.brake_roll = 0; // initialise braking angle to zero
hybrid.brake_angle_max_roll = 0; // reset brake_angle_max so we can detect when vehicle begins to flatten out during braking
hybrid.brake_timeout_roll = HYBRID_BRAKE_TIME_ESTIMATE_MAX; // number of cycles the brake will be applied, updated during braking mode.
hybrid.braking_time_updated_roll = false; // flag the braking time can be re-estimated
}
// final lean angle should be pilot input plus wind compensation
hybrid.roll = hybrid.pilot_roll + hybrid.wind_comp_roll;
break;
case HYBRID_BRAKE:
case HYBRID_BRAKE_READY_TO_LOITER:
// calculate brake_roll angle to counter-act velocity
hybrid_update_brake_angle_from_velocity(hybrid.brake_roll, vel_right);
// update braking time estimate
if (!hybrid.braking_time_updated_roll) {
// check if brake angle is increasing
if (abs(hybrid.brake_roll) >= hybrid.brake_angle_max_roll) {
hybrid.brake_angle_max_roll = abs(hybrid.brake_roll);
} else {
// braking angle has started decreasing so re-estimate braking time
hybrid.brake_timeout_roll = 1+(uint16_t)(LOOP_RATE_FACTOR*15L*(int32_t)(abs(hybrid.brake_roll))/(10L*(int32_t)g.hybrid_brake_rate)); // the 1.2 (12/10) factor has to be tuned in flight, here it means 120% of the "normal" time.
hybrid.braking_time_updated_roll = true;
}
}
// if velocity is very low reduce braking time to 0.5seconds
if ((fabs(vel_right) <= HYBRID_SPEED_0) && (hybrid.brake_timeout_roll > 50*LOOP_RATE_FACTOR)) {
hybrid.brake_timeout_roll = 50*LOOP_RATE_FACTOR;
}
// reduce braking timer
if (hybrid.brake_timeout_roll > 0) {
hybrid.brake_timeout_roll--;
} else {
// indicate that we are ready to move to Loiter.
// Loiter will only actually be engaged once both roll_mode and pitch_mode are changed to HYBRID_BRAKE_READY_TO_LOITER
// logic for engaging loiter is handled below the roll and pitch mode switch statements
hybrid.roll_mode = HYBRID_BRAKE_READY_TO_LOITER;
}
// final lean angle is braking angle + wind compensation angle
hybrid.roll = hybrid.brake_roll + hybrid.wind_comp_roll;
// check for pilot input
if (target_roll != 0) {
// init transition to pilot override
hybrid_roll_controller_to_pilot_override();
}
break;
case HYBRID_BRAKE_TO_LOITER:
case HYBRID_LOITER:
// these modes are combined roll-pitch modes and are handled below
break;
case HYBRID_CONTROLLER_TO_PILOT_OVERRIDE:
// update pilot desired roll angle using latest radio input
// this filters the input so that it returns to zero no faster than the brake-rate
hybrid_update_pilot_lean_angle(hybrid.pilot_roll, target_roll);
// count-down loiter to pilot timer
if (hybrid.controller_to_pilot_timer_roll > 0) {
hybrid.controller_to_pilot_timer_roll--;
} else {
// when timer runs out switch to full pilot override for next iteration
hybrid.roll_mode = HYBRID_PILOT_OVERRIDE;
}
// calculate controller_to_pilot mix ratio
controller_to_pilot_roll_mix = (float)hybrid.controller_to_pilot_timer_roll / (float)HYBRID_CONTROLLER_TO_PILOT_MIX_TIMER;
// mix final loiter lean angle and pilot desired lean angles
hybrid.roll = hybrid_mix_controls(controller_to_pilot_roll_mix, hybrid.controller_final_roll, hybrid.pilot_roll + hybrid.wind_comp_roll);
break;
}
// Pitch state machine
// Each state (aka mode) is responsible for:
// 1. dealing with pilot input
// 2. calculating the final pitch output to the attitude contpitcher
// 3. checking if the state (aka mode) should be changed and if 'yes' perform any required initialisation for the new state
switch (hybrid.pitch_mode) {
case HYBRID_PILOT_OVERRIDE:
// update pilot desired pitch angle using latest radio input
// this filters the input so that it returns to zero no faster than the brake-rate
hybrid_update_pilot_lean_angle(hybrid.pilot_pitch, target_pitch);
// switch to BRAKE mode for next iteration if no pilot input
if ((target_pitch == 0) && (abs(hybrid.pilot_pitch) < 2 * g.hybrid_brake_rate)) {
// initialise BRAKE mode
hybrid.pitch_mode = HYBRID_BRAKE; // set brake pitch mode
hybrid.brake_pitch = 0; // initialise braking angle to zero
hybrid.brake_angle_max_pitch = 0; // reset brake_angle_max so we can detect when vehicle begins to flatten out during braking
hybrid.brake_timeout_pitch = HYBRID_BRAKE_TIME_ESTIMATE_MAX; // number of cycles the brake will be applied, updated during braking mode.
hybrid.braking_time_updated_pitch = false; // flag the braking time can be re-estimated
}
// final lean angle should be pilot input plus wind compensation
hybrid.pitch = hybrid.pilot_pitch + hybrid.wind_comp_pitch;
break;
case HYBRID_BRAKE:
case HYBRID_BRAKE_READY_TO_LOITER:
// calculate brake_pitch angle to counter-act velocity
hybrid_update_brake_angle_from_velocity(hybrid.brake_pitch, -vel_fw);
// update braking time estimate
if (!hybrid.braking_time_updated_pitch) {
// check if brake angle is increasing
if (abs(hybrid.brake_pitch) >= hybrid.brake_angle_max_pitch) {
hybrid.brake_angle_max_pitch = abs(hybrid.brake_pitch);
} else {
// braking angle has started decreasing so re-estimate braking time
hybrid.brake_timeout_pitch = 1+(uint16_t)(LOOP_RATE_FACTOR*15L*(int32_t)(abs(hybrid.brake_pitch))/(10L*(int32_t)g.hybrid_brake_rate)); // the 1.2 (12/10) factor has to be tuned in flight, here it means 120% of the "normal" time.
hybrid.braking_time_updated_pitch = true;
}
}
// if velocity is very low reduce braking time to 0.5seconds
if ((fabs(vel_fw) <= HYBRID_SPEED_0) && (hybrid.brake_timeout_pitch > 50*LOOP_RATE_FACTOR)) {
hybrid.brake_timeout_pitch = 50*LOOP_RATE_FACTOR;
}
// reduce braking timer
if (hybrid.brake_timeout_pitch > 0) {
hybrid.brake_timeout_pitch--;
} else {
// indicate that we are ready to move to Loiter.
// Loiter will only actually be engaged once both pitch_mode and pitch_mode are changed to HYBRID_BRAKE_READY_TO_LOITER
// logic for engaging loiter is handled below the pitch and pitch mode switch statements
hybrid.pitch_mode = HYBRID_BRAKE_READY_TO_LOITER;
}
// final lean angle is braking angle + wind compensation angle
hybrid.pitch = hybrid.brake_pitch + hybrid.wind_comp_pitch;
// check for pilot input
if (target_pitch != 0) {
// init transition to pilot override
hybrid_pitch_controller_to_pilot_override();
}
break;
case HYBRID_BRAKE_TO_LOITER:
case HYBRID_LOITER:
// these modes are combined pitch-pitch modes and are handled below
break;
case HYBRID_CONTROLLER_TO_PILOT_OVERRIDE:
// update pilot desired pitch angle using latest radio input
// this filters the input so that it returns to zero no faster than the brake-rate
hybrid_update_pilot_lean_angle(hybrid.pilot_pitch, target_pitch);
// count-down loiter to pilot timer
if (hybrid.controller_to_pilot_timer_pitch > 0) {
hybrid.controller_to_pilot_timer_pitch--;
} else {
// when timer runs out switch to full pilot override for next iteration
hybrid.pitch_mode = HYBRID_PILOT_OVERRIDE;
}
// calculate controller_to_pilot mix ratio
controller_to_pilot_pitch_mix = (float)hybrid.controller_to_pilot_timer_pitch / (float)HYBRID_CONTROLLER_TO_PILOT_MIX_TIMER;
// mix final loiter lean angle and pilot desired lean angles
hybrid.pitch = hybrid_mix_controls(controller_to_pilot_pitch_mix, hybrid.controller_final_pitch, hybrid.pilot_pitch + hybrid.wind_comp_pitch);
break;
}
//
// Shared roll & pitch states (HYBRID_BRAKE_TO_LOITER and HYBRID_LOITER)
//
// switch into LOITER mode when both roll and pitch are ready
if (hybrid.roll_mode == HYBRID_BRAKE_READY_TO_LOITER && hybrid.pitch_mode == HYBRID_BRAKE_READY_TO_LOITER) {
hybrid.roll_mode = HYBRID_BRAKE_TO_LOITER;
hybrid.pitch_mode = HYBRID_BRAKE_TO_LOITER;
hybrid.brake_to_loiter_timer = HYBRID_BRAKE_TO_LOITER_TIMER;
// init loiter controller
Vector3f curr_pos = inertial_nav.get_position();
curr_pos.z = pos_control.get_alt_target(); // We don't set alt_target to current altitude but to the current alt_target... the easiest would be to set only x/y as it was on pre-onion code
wp_nav.set_loiter_target(curr_pos, hybrid.loiter_reset_I); // (false) to avoid I_term reset. In original code, velocity(0,0,0) was used instead of current velocity: wp_nav.init_loiter_target(inertial_nav.get_position(), Vector3f(0,0,0));
// at this stage, we are going to run update_loiter that will reset I_term once. From now, we ensure next time that we will enter loiter and update it, I_term won't be reset anymore
hybrid.loiter_reset_I = false;
// set delay to start of wind compensation estimate updates
hybrid.wind_comp_start_timer = HYBRID_WIND_COMP_START_TIMER;
}
// roll-mode is used as the combined roll+pitch mode when in BRAKE_TO_LOITER or LOITER modes
if (hybrid.roll_mode == HYBRID_BRAKE_TO_LOITER || hybrid.roll_mode == HYBRID_LOITER) {
// force pitch mode to be same as roll_mode just to keep it consistent (it's not actually used in these states)
hybrid.pitch_mode = hybrid.roll_mode;
// handle combined roll+pitch mode
switch (hybrid.roll_mode) {
case HYBRID_BRAKE_TO_LOITER:
// reduce brake_to_loiter timer
if (hybrid.brake_to_loiter_timer > 0) {
hybrid.brake_to_loiter_timer--;
} else {
// progress to full loiter on next iteration
hybrid.roll_mode = HYBRID_LOITER;
hybrid.pitch_mode = HYBRID_LOITER;
}
// calculate percentage mix of loiter and brake control
brake_to_loiter_mix = (float)hybrid.brake_to_loiter_timer / (float)HYBRID_BRAKE_TO_LOITER_TIMER;
// calculate brake_roll and pitch angles to counter-act velocity
hybrid_update_brake_angle_from_velocity(hybrid.brake_roll, vel_right);
hybrid_update_brake_angle_from_velocity(hybrid.brake_pitch, -vel_fw);
// run loiter controller
wp_nav.update_loiter();
// calculate final roll and pitch output by mixing loiter and brake controls
hybrid.roll = hybrid_mix_controls(brake_to_loiter_mix, hybrid.brake_roll + hybrid.wind_comp_roll, wp_nav.get_roll());
hybrid.pitch = hybrid_mix_controls(brake_to_loiter_mix, hybrid.brake_pitch + hybrid.wind_comp_pitch, wp_nav.get_pitch());
// check for pilot input
if (target_roll != 0 || target_pitch != 0) {
// if roll input switch to pilot override for roll
if (target_roll != 0) {
// init transition to pilot override
hybrid_roll_controller_to_pilot_override();
// switch pitch-mode to brake (but ready to go back to loiter anytime)
// no need to reset hybrid.brake_pitch here as wind comp has not been updated since last brake_pitch computation
hybrid.pitch_mode = HYBRID_BRAKE_READY_TO_LOITER;
}
// if pitch input switch to pilot override for pitch
if (target_pitch != 0) {
// init transition to pilot override
hybrid_pitch_controller_to_pilot_override();
if (target_roll == 0) {
// switch roll-mode to brake (but ready to go back to loiter anytime)
// no need to reset hybrid.brake_roll here as wind comp has not been updated since last brake_roll computation
hybrid.roll_mode = HYBRID_BRAKE_READY_TO_LOITER;
}
}
}
break;
case HYBRID_LOITER:
// run loiter controller
wp_nav.update_loiter();
// set roll angle based on loiter controller outputs
hybrid.roll = wp_nav.get_roll();
hybrid.pitch = wp_nav.get_pitch();
// update wind compensation estimate
hybrid_update_wind_comp_estimate();
// check for pilot input
if (target_roll != 0 || target_pitch != 0) {
// if roll input switch to pilot override for roll
if (target_roll != 0) {
// init transition to pilot override
hybrid_roll_controller_to_pilot_override();
// switch pitch-mode to brake (but ready to go back to loiter anytime)
hybrid.pitch_mode = HYBRID_BRAKE_READY_TO_LOITER;
// reset brake_pitch because wind_comp is now different and should give the compensation of the whole previous loiter angle
hybrid.brake_pitch = 0;
}
// if pitch input switch to pilot override for pitch
if (target_pitch != 0) {
// init transition to pilot override
hybrid_pitch_controller_to_pilot_override();
// if roll not overriden switch roll-mode to brake (but be ready to go back to loiter any time)
if (target_roll == 0) {
hybrid.roll_mode = HYBRID_BRAKE_READY_TO_LOITER;
hybrid.brake_roll = 0;
}
}
}
break;
default:
// do nothing for uncombined roll and pitch modes
break;
}
}
// constrain target pitch/roll angles
hybrid.roll = constrain_int16(hybrid.roll, -aparm.angle_max, aparm.angle_max);
hybrid.pitch = constrain_int16(hybrid.pitch, -aparm.angle_max, aparm.angle_max);
// update attitude controller targets
attitude_control.angle_ef_roll_pitch_rate_ef_yaw(hybrid.roll, hybrid.pitch, target_yaw_rate);
// throttle control
if (sonar_alt_health >= SONAR_ALT_HEALTH_MAX) {
// if sonar is ok, use surface tracking
target_climb_rate = get_throttle_surface_tracking(target_climb_rate, pos_control.get_alt_target(), G_Dt);
}
// update altitude target and call position controller
pos_control.set_alt_target_from_climb_rate(target_climb_rate, G_Dt);
pos_control.update_z_controller();
}
}
// hybrid_update_pilot_lean_angle - update the pilot's filtered lean angle with the latest raw input received
static void hybrid_update_pilot_lean_angle(int16_t &lean_angle_filtered, int16_t &lean_angle_raw)
{
// if raw input is large or reversing the vehicle's lean angle immediately set the fitlered angle to the new raw angle
if ((lean_angle_filtered > 0 && lean_angle_raw < 0) || (lean_angle_filtered < 0 && lean_angle_raw > 0) || (abs(lean_angle_raw) > HYBRID_STICK_RELEASE_SMOOTH_ANGLE)) {
lean_angle_filtered = lean_angle_raw;
} else {
// lean_angle_raw must be pulling lean_angle_filtered towards zero, smooth the decrease
if (lean_angle_filtered > 0) {
// reduce the filtered lean angle at 5% or the brake rate (whichever is faster).
lean_angle_filtered -= max((float)lean_angle_filtered * HYBRID_SMOOTH_RATE_FACTOR, max(1, g.hybrid_brake_rate/LOOP_RATE_FACTOR));
// do not let the filtered angle fall below the pilot's input lean angle.
// the above line pulls the filtered angle down and the below line acts as a catch
lean_angle_filtered = max(lean_angle_filtered, lean_angle_raw);
}else{
lean_angle_filtered += max(-(float)lean_angle_filtered * HYBRID_SMOOTH_RATE_FACTOR, max(1, g.hybrid_brake_rate/LOOP_RATE_FACTOR));
lean_angle_filtered = min(lean_angle_filtered, lean_angle_raw);
}
}
}
// hybrid_mix_controls - mixes two controls based on the mix_ratio
// mix_ratio of 1 = use first_control completely, 0 = use second_control completely, 0.5 = mix evenly
static int16_t hybrid_mix_controls(float mix_ratio, int16_t first_control, int16_t second_control)
{
mix_ratio = constrain_float(mix_ratio, 0.0f, 1.0f);
return (int16_t)((mix_ratio * first_control) + ((1.0f-mix_ratio)*second_control));
}
// hybrid_update_brake_angle_from_velocity - updates the brake_angle based on the vehicle's velocity and brake_gain
// brake_angle is slewed with the wpnav.hybrid_brake_rate and constrained by the wpnav.hybrid_braking_angle_max
// velocity is assumed to be in the same direction as lean angle so for pitch you should provide the velocity backwards (i.e. -ve forward velocity)
static void hybrid_update_brake_angle_from_velocity(int16_t &brake_angle, float velocity)
{
float lean_angle;
int16_t brake_rate = g.hybrid_brake_rate;
#if MAIN_LOOP_RATE == 400
brake_rate /= 4;
if (brake_rate <= 0) {
brake_rate = 1;
}
#endif
// calculate velocity-only based lean angle
if (velocity >= 0) {
lean_angle = -hybrid.brake_gain * velocity * (1.0f+500.0f/(velocity+60.0f));
} else {
lean_angle = -hybrid.brake_gain * velocity * (1.0f+500.0f/(-velocity+60.0f));
}
// do not let lean_angle be too far from brake_angle
brake_angle = constrain_int16((int16_t)lean_angle, brake_angle - brake_rate, brake_angle + brake_rate);
// constrain final brake_angle
brake_angle = constrain_int16(brake_angle, -g.hybrid_brake_angle_max, g.hybrid_brake_angle_max);
}
// hybrid_update_wind_comp_estimate - updates wind compensation estimate
// should be called at the maximum loop rate when loiter is engaged
static void hybrid_update_wind_comp_estimate()
{
// reduce rate to 10hz
hybrid.wind_comp_est_timer++;
if (hybrid.wind_comp_est_timer < HYBRID_WIND_COMP_TIMER_10HZ) {
return;
}
hybrid.wind_comp_est_timer = 0;
// check wind estimate start has not been delayed
if (hybrid.wind_comp_start_timer > 0) {
hybrid.wind_comp_start_timer--;
return;
}
// check horizontal velocity is low
if (inertial_nav.get_velocity_xy() > HYBRID_WIND_COMP_ESTIMATE_SPEED_MAX) {
return;
}
// get position controller accel target
// To-Do: clean this up by using accessor in loiter controller (or move entire hybrid controller to a library shared with loiter)
const Vector3f& accel_target = pos_control.get_accel_target();
// update wind compensation in earth-frame lean angles
if (hybrid.wind_comp_ef.x == 0) {
// if wind compensation has not been initialised set it immediately to the pos controller's desired accel in north direction
hybrid.wind_comp_ef.x = accel_target.x;
} else {
// low pass filter the position controller's lean angle output
hybrid.wind_comp_ef.x = (1.0f-TC_WIND_COMP)*hybrid.wind_comp_ef.x + TC_WIND_COMP*accel_target.x;
}
if (hybrid.wind_comp_ef.y == 0) {
// if wind compensation has not been initialised set it immediately to the pos controller's desired accel in north direction
hybrid.wind_comp_ef.y = accel_target.y;
} else {
// low pass filter the position controller's lean angle output
hybrid.wind_comp_ef.y = (1.0f-TC_WIND_COMP)*hybrid.wind_comp_ef.y + TC_WIND_COMP*accel_target.y;
}
}
// hybrid_get_wind_comp_lean_angles - retrieve wind compensation angles in body frame roll and pitch angles
// should be called at the maximum loop rate
static void hybrid_get_wind_comp_lean_angles(int16_t &roll_angle, int16_t &pitch_angle)
{
// reduce rate to 10hz
hybrid.wind_comp_lean_angle_timer++;
if (hybrid.wind_comp_lean_angle_timer < HYBRID_WIND_COMP_TIMER_10HZ) {
return;
}
hybrid.wind_comp_lean_angle_timer = 0;
// convert earth frame desired accelerations to body frame roll and pitch lean angles
roll_angle = (float)fast_atan((-hybrid.wind_comp_ef.x*ahrs.sin_yaw() + hybrid.wind_comp_ef.y*ahrs.cos_yaw())/981)*(18000/M_PI);
pitch_angle = (float)fast_atan(-(hybrid.wind_comp_ef.x*ahrs.cos_yaw() + hybrid.wind_comp_ef.y*ahrs.sin_yaw())/981)*(18000/M_PI);
}
// hybrid_roll_controller_to_pilot_override - initialises transition from a controller submode (brake or loiter) to a pilot override on roll axis
static void hybrid_roll_controller_to_pilot_override()
{
hybrid.roll_mode = HYBRID_CONTROLLER_TO_PILOT_OVERRIDE;
hybrid.controller_to_pilot_timer_roll = HYBRID_CONTROLLER_TO_PILOT_MIX_TIMER;
// initialise pilot_roll to 0, wind_comp will be updated to compensate and hybrid_update_pilot_lean_angle function shall not smooth this transition at next iteration. so 0 is the right value
hybrid.pilot_roll = 0;
// store final controller output for mixing with pilot input
hybrid.controller_final_roll = hybrid.roll;
}
// hybrid_pitch_controller_to_pilot_override - initialises transition from a controller submode (brake or loiter) to a pilot override on roll axis
static void hybrid_pitch_controller_to_pilot_override()
{
hybrid.pitch_mode = HYBRID_CONTROLLER_TO_PILOT_OVERRIDE;
hybrid.controller_to_pilot_timer_pitch = HYBRID_CONTROLLER_TO_PILOT_MIX_TIMER;
// initialise pilot_pitch to 0, wind_comp will be updated to compensate and hybrid_update_pilot_lean_angle function shall not smooth this transition at next iteration. so 0 is the right value
hybrid.pilot_pitch = 0;
// store final loiter outputs for mixing with pilot input
hybrid.controller_final_pitch = hybrid.pitch;
}
#endif // HYBRID_ENABLED == ENABLED
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