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2621d07574
- Added FlighSituation Module (development module for sensor fusion, mostly stub, possibly renamed later) - Added Navigation Module (development module for navigating towards a point in space - DEVELOPMENT CODE, NOT STABLE YET (I am testing around with this)) - Changed Stabilization Module (uses local reference frame now. Stable except for code cleanup/review. Tested in simulator and outperforms old code.) git-svn-id: svn://svn.openpilot.org/OpenPilot/trunk@1154 ebee16cc-31ac-478f-84a7-5cbb03baadba
531 lines
17 KiB
C
531 lines
17 KiB
C
/**
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******************************************************************************
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* @addtogroup OpenPilotModules OpenPilot Modules
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* @{
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* @addtogroup NavigationModule Navigation Module
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* @brief Feeds Stabilization with input to fly to a given coordinate in space
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* @note This object updates the @ref AttitudeDesired "Attitude Desired" based on the
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* comparison on the @ref NavigationDesired "Navigation Desired", @ref AttitudeActual
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* "Attitude Actual" and @ref FlightSituationActual "FlightSituation Actual"
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* @{
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*
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* @file navigation.h
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* @author The OpenPilot Team, http://www.openpilot.org Copyright (C) 2010.
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* @brief Position stabilization module.
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*
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* @see The GNU Public License (GPL) Version 3
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*
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*****************************************************************************/
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/*
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* This program is free software; you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation; either version 3 of the License, or
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* (at your option) any later version.
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*
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* This program is distributed in the hope that it will be useful, but
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* WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
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* or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
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* for more details.
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*
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* You should have received a copy of the GNU General Public License along
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* with this program; if not, write to the Free Software Foundation, Inc.,
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* 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
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*/
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#include "openpilot.h"
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#include "navigation.h"
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#include "navigationsettings.h"
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#include "navigationdesired.h"
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#include "attitudeactual.h"
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#include "attitudedesired.h"
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#include "flightsituationactual.h"
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#include "manualcontrolcommand.h"
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#include "systemsettings.h"
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// Private constants
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#define STACK_SIZE configMINIMAL_STACK_SIZE
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#define TASK_PRIORITY (tskIDLE_PRIORITY+3)
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#define DEG2RAD ( M_PI / 180.0 )
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#define RAD2DEG ( 180.0 / M_PI )
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#define MIN(a,b) ((a<b)?a:b)
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#define MAX(a,b) ((a>b)?a:b)
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#define SSQRT(x) ((x)>=0?sqrt(x):-sqrt(-x)) // signed square root
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#define EARTHRAD 6378137
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#define GRAVITY 9.81
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// Private types
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// Private variables
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static xTaskHandle taskHandle;
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// Private functions
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static void navigationTask(void* parameters);
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static float bound(float val, float min, float max);
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static float angleDifference(float val);
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static float fixAngle(float val,float min, float max);
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static float sphereDistance(float lat1,float long1,float lat2,float long2);
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static float sphereCourse(float lat1,float long1,float lat2,float long2);
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/**
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* Module initialization
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*/
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int32_t NavigationInitialize()
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{
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// Initialize variables
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// Start main task
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xTaskCreate(navigationTask, (signed char*)"Navigation", STACK_SIZE, NULL, TASK_PRIORITY, &taskHandle);
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return 0;
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}
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/**
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* Module task
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*/
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static void navigationTask(void* parameters)
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{
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NavigationSettingsData navSettings;
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NavigationDesiredData navigationDesired;
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AttitudeActualData attitudeActual;
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AttitudeDesiredData attitudeDesired;
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FlightSituationActualData situationActual;
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ManualControlCommandData manualControl;
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SystemSettingsData systemSettings;
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portTickType lastSysTime;
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// flight safety values
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float maxPitch;
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float minPitch;
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float maxAccel;
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// helper variables
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float safeAccel;
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float safeDistance;
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float aoa,saoa;
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// intended flight direction
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float targetDistance;
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float targetVspeed;
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float targetTruePitch;
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float targetHeading;
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float targetPitch;
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float targetYaw;
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// turn direction
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float turnDirection;
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float turnSpeed;
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float turnAccel;
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// Main task loop
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lastSysTime = xTaskGetTickCount();
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while (1)
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{
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// Read settings and other objects
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NavigationSettingsGet(&navSettings);
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SystemSettingsGet(&systemSettings);
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ManualControlCommandGet(&manualControl);
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FlightSituationActualGet(&situationActual);
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NavigationDesiredGet(&navigationDesired);
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AttitudeActualGet(&attitudeActual);
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// horizontal distance to waypoint
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// (not 100% exact since the earth is not a perfect sphere, but
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// close enough for our purpose...)
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targetDistance = DEG2RAD * EARTHRAD * sphereDistance(
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situationActual.Latitude,situationActual.Longitude,
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navigationDesired.Latitude,navigationDesired.Longitude
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);
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// pitch to climb/sink to target altitude (attempts to reach
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// target altitude withing SettleTime seconds
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targetVspeed= (navigationDesired.Altitude - situationActual.Altitude)/navSettings.SettleTime;
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if ( targetVspeed >= situationActual.Airspeed )
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{
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targetTruePitch = 90.0;
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}
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else if ( targetVspeed <= -situationActual.Airspeed )
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{
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targetTruePitch = -90.0;
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}
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else
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{
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targetTruePitch = RAD2DEG * asin( targetVspeed / situationActual.Airspeed );
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}
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// course to target coordinate
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targetHeading = sphereCourse(
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situationActual.Latitude,situationActual.Longitude,
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navigationDesired.Latitude,navigationDesired.Longitude
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);
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//printf("\n\n\nTarget: Heading: %2f Distance: %2f climbing %2f°\n",targetHeading,targetDistance,targetTruePitch);
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//printf("distance: %f\n",sphereDistance(situationActual.Latitude,situationActual.Longitude,navigationDesired.Latitude,navigationDesired.Longitude));
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/**
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* navigation for fixed wing planes
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*/
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if (systemSettings.AirframeType != SYSTEMSETTINGS_AIRFRAMETYPE_VTOL)
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{
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/**
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* Fixed wing planes create lift through their airspeed
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* therefore most maneuver limits depend on the current
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* speed and situation.
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*/
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// acceleration:
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maxAccel=navSettings.AccelerationMax;
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/**
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* Idea: at minSpeed, the plane can JUST compensate 1g
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* safely. The StallSpeed at any load factor is
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* Vstall=Vs(0) / sqrt(load) so the maximum load for
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* the current speed is maxLoad = (Vs(0)/V)²
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*/
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maxAccel = MIN( maxAccel ,
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GRAVITY * (situationActual.Airspeed*situationActual.Airspeed)
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/ (navSettings.SpeedMin * navSettings.SpeedMin)
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);
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// maximum pitch:
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maxPitch=85.0;
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/**
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* Idea: any climb decreases speed. Aside from drag
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* speed decrease is vertical speed times g (9.81m/s²)
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* make sure speed stays above min speed within
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* SettleTime
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*/
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safeAccel = ( navSettings.SpeedSafe-situationActual.Airspeed ) / navSettings.SettleTime;
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if (safeAccel>=0)
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{
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// speed is below minimum speed. Do not allow any climbs!
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maxPitch = MIN(maxPitch,0);
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}
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else if (safeAccel>-GRAVITY)
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{
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// speed is getting low. Limit maximum climb!
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maxPitch = MIN(maxPitch,RAD2DEG*asin(-safeAccel/GRAVITY));
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}
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// minimum pitch:
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minPitch=-85.0;
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/**
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* Idea: any dive increases speed. Aside from drag
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* speed increase is vertical speed times g (9.81m/s²)
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* make sure speed stays below max speed within
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* SettleTime
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*/
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safeAccel = ( navSettings.SpeedMax-situationActual.Airspeed ) / navSettings.SettleTime;
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if (safeAccel<=0)
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{
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// speed is above maximum speed. Do not allow any dives!
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minPitch = MAX(minPitch,0);
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}
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else if (safeAccel<GRAVITY)
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{
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// speed is getting high. Limit maximum dive!
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minPitch = MAX(minPitch,-1.*RAD2DEG*asin(safeAccel/GRAVITY));
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}
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/**
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* Idea: To change pitch, acceleration must be
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* applied. A pull up at maximum allowed pitch has a certain radius.
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* If we are lower than that we are not allowed to
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*/
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safeDistance = situationActual.Airspeed * situationActual.Airspeed / (maxAccel+GRAVITY);
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//printf("safe distance: %f\n",safeDistance);
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if (safeDistance <= 0 || situationActual.Altitude<=navigationDesired.Altitude)
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{
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// altitude is below wanted altitude. Do not allow any dive at all.
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minPitch = MAX(minPitch,0);
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}
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else if ( safeDistance >= situationActual.Altitude - navigationDesired.Altitude)
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{
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// altitude is close to target altitude, limit negative pitch
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minPitch = MAX(minPitch,-1 * RAD2DEG * asin( (situationActual.Altitude - navigationDesired.Altitude) / safeDistance ));
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}
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//printf("Safety: Pitch: %2f %2f Accel: %2fm/s²\n",minPitch,maxPitch,maxAccel);
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/**
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* Base anted yaw and pitch on calculated angle of
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* attack and side slip effects
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*
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* Note: This can lead to an oszillation between a
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* flight with positive and negative angle of attack.
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* Without this correction however, the plane will
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* always "lag behind" it's desired altitude.
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*/
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// angle of attack in X and Y
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aoa = attitudeActual.Pitch - (RAD2DEG * atan2( situationActual.Climbrate, situationActual.Groundspeed));
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saoa = attitudeActual.Yaw-situationActual.Course;
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targetPitch = bound(targetTruePitch+aoa,minPitch,maxPitch);
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targetYaw = fixAngle(targetHeading+saoa,0.,360.);
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//printf("Target Pitch: %2f Yaw: %2f \n",targetPitch,targetYaw);
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//printf("Current Roll: %2f Pitch: %2f Yaw: %2f \n",attitudeActual.Roll,attitudeActual.Pitch,attitudeActual.Yaw);
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/**
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* Now we have the current Pitch Yaw and Roll in
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* AttitudeActual and the wanted course in targetPitch
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* and targetYaw. We also have the safety limits. Now
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* make a smooth and save transition.
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* including all safety limits! Make a nice transition.
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*/
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// turn vector (Euler)
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/**
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* The naive approach wants to fly along an Orthodrome - the quickest way to get from one angle to another
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*/
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turnDirection = sphereCourse(attitudeActual.Pitch,attitudeActual.Yaw,targetPitch,targetYaw);
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/**
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* However if the target yaw is more than 90° away, this orthodrome would lead through a minimum or maximum point that
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* could be beyond safe min/max pitch values!
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*/
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if (fabs(angleDifference(attitudeActual.Yaw-targetYaw))>90)
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{
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if (fabs(turnDirection)<90)
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{
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/**
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* Positive turns (upward) can conflict with maxPitch
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*/
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if (RAD2DEG*acos(sin(fabs(DEG2RAD*turnDirection))*cos(DEG2RAD*attitudeActual.Pitch))>maxPitch)
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{
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/**
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* In this case the turn has to be adjusted to a circle that won't conflict with maxPitch
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*/
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//printf("maximum is %2f which is higher than %2f\n",RAD2DEG*acos(sin(DEG2RAD*turnDirection)*cos(DEG2RAD*attitudeActual.Pitch)),maxPitch);
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if (cos(DEG2RAD*attitudeActual.Pitch)>cos(DEG2RAD*maxPitch))
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{
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if (turnDirection>0)
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{
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turnDirection = RAD2DEG * asin( cos(DEG2RAD*maxPitch)/cos(DEG2RAD*attitudeActual.Pitch));
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}
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else
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{
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turnDirection = -RAD2DEG * asin( cos(DEG2RAD*maxPitch)/cos(DEG2RAD*attitudeActual.Pitch));
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}
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}
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else
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{
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/**
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* something went wrong (attitude outside safe bounds?)- compensate safely
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*/
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turnDirection=(turnDirection>0?110:-110);
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}
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//printf("limiting because of max!\n");
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}
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}
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else
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{
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/**
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* Downward turns can conflict with minPitch
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*/
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if (RAD2DEG*acos(sin(fabs(DEG2RAD*turnDirection))*cos(DEG2RAD*attitudeActual.Pitch))>-minPitch)
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{
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//printf("minimum is %2f which is less than %2f\n",-1*RAD2DEG*acos(sin(fabs(DEG2RAD*turnDirection))*cos(DEG2RAD*attitudeActual.Pitch)),minPitch);
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/**
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* In this case the turn has to be adjusted to a circle that won't conflict with minPitch
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*/
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if (cos(DEG2RAD*attitudeActual.Pitch)>cos(DEG2RAD*minPitch))
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{
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if (turnDirection>0) {
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turnDirection = 180 - RAD2DEG * asin( cos(DEG2RAD*minPitch)/cos(DEG2RAD*attitudeActual.Pitch));
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}
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else
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{
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turnDirection = -180 + RAD2DEG * asin( cos(DEG2RAD*minPitch)/cos(DEG2RAD*attitudeActual.Pitch));
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}
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}
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else
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{
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/**
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* something went wrong (attitude outside safe bounds?)- compensate safely
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*/
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turnDirection=(turnDirection>0?45:-45);
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}
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//printf("limiting because of min!\n");
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}
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}
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}
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/**
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* Turn speed in °/s is the minimum of
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* TurnSpeedFactor * degrees to turn
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* and
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* the maximum angular velocity achievable with
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* less than maxAccel centripetal acceleration
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* (taking gravity effect into account)
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* but not less than 0
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* Formula: acceleration = (DEG2RAD*turnSpeed)
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* * airspeed
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*/
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turnSpeed = MAX(0,MIN(
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navSettings.TurnSpeedFactor * sphereDistance(
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attitudeActual.Pitch,attitudeActual.Yaw,
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targetPitch,targetYaw)
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,
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RAD2DEG * (maxAccel-( MIN(0,cos(DEG2RAD*turnDirection))*GRAVITY )) / situationActual.Airspeed
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));
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//printf("turn distance is %2f °\n", sphereDistance(attitudeActual.Pitch,attitudeActual.Yaw,targetPitch,targetYaw));
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//printf("safe speed is %2f °/s\n",RAD2DEG * (maxAccel-( MIN(0,cos(DEG2RAD*turnDirection))*GRAVITY )) / situationActual.Airspeed);
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//printf("turn speed is %2f °/s\n",turnSpeed);
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//printf("Airspeed is %2f °/s\n",situationActual.Airspeed);
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/**
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* Compute wanted centripetal acceleration
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*/
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turnAccel = DEG2RAD* turnSpeed * situationActual.Airspeed;
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//printf("Turn with: %2f at %2fm/s²\n",turnDirection,turnAccel);
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// Desired Attitude
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/**
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* Now that we know which way the plane is supposed to
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* go and at what acceleration, calculate the required
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* roll angle to also compensate gravity during the
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* turn
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*/
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attitudeDesired.Roll = RAD2DEG*atan2(
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turnAccel * sin(DEG2RAD*turnDirection),
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turnAccel * cos(DEG2RAD*turnDirection) + cos(DEG2RAD*attitudeActual.Pitch)*GRAVITY
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);
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/**
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* However this can also result in an upright flight
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* with a load of less than 1g
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* In this case, the effect on yaw is reversed.
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* (Imagine rolling 45° right, then push the stick
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* slightly. You will go left and down!)
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* In this case we reverse the roll to descent into the
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* right direction!
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*/
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if (fabs(angleDifference(attitudeDesired.Roll-turnDirection))>90) {
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attitudeDesired.Roll=-attitudeDesired.Roll;
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}
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//printf("FINALS: roll %2f ",attitudeDesired.Roll);
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/**
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* The desired Yaw and Pitch values are tricky.
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* The current Stabilization module doesn't allow us to
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* specify an angular speed or even centripetal
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* acceleration instead we have to specify an
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* orientation.
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* According to tests, a formula of
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* sqrt(turnAccel) * StabilizationForceFactor
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* degrees lookahead gives reasonable results.
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*/
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attitudeDesired.Pitch = bound(
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attitudeActual.Pitch + navSettings.StabilizationForceFactor * SSQRT(turnAccel * cos(DEG2RAD*turnDirection)),
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minPitch,
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maxPitch);
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attitudeDesired.Yaw = attitudeActual.Yaw + navSettings.StabilizationForceFactor * SSQRT(turnAccel * sin(DEG2RAD*turnDirection)) ;
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//printf("pitch %2f yaw %2f\n",attitudeDesired.Pitch-attitudeActual.Pitch,attitudeDesired.Yaw-attitudeActual.Yaw);
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/**
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* TODO: Make a real PID loop for the throttle.
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*/
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attitudeDesired.Throttle=0.8;
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}
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// Write actuator desired (if not in manual mode)
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if ( manualControl.FlightMode == MANUALCONTROLCOMMAND_FLIGHTMODE_AUTO )
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{
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AttitudeDesiredSet(&attitudeDesired);
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}
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// Wait until next update
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vTaskDelayUntil(&lastSysTime, navSettings.UpdatePeriod / portTICK_RATE_MS );
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}
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}
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/**
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* Bound input value between limits
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*/
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static float bound(float val, float min, float max)
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{
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if ( val < min )
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{
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val = min;
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}
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else if ( val > max )
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{
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val = max;
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}
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return val;
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}
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/**
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* Fix result of angular differences
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*/
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static float angleDifference(float val)
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{
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while ( val < -180.0 )
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{
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val += 360.0;
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}
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while ( val > 180.0 )
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{
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val -= 360.0;
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}
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return val;
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}
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/**
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* Make sure an angular value stays between correct bounds
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*/
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static float fixAngle(float val,float min, float max)
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{
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while ( val < min )
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{
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val += 360.0;
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}
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while ( val >= max )
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|
{
|
|
val -= 360.0;
|
|
}
|
|
return val;
|
|
}
|
|
|
|
/**
|
|
* calculate spherical distance and course between two coordinate pairs
|
|
* see http://de.wikipedia.org/wiki/Orthodrome for details
|
|
*/
|
|
static float sphereDistance(float lat1, float long1, float lat2, float long2)
|
|
{
|
|
float zeta=(RAD2DEG * acos (
|
|
sin(DEG2RAD*lat1) * sin(DEG2RAD*lat2)
|
|
+ cos(DEG2RAD*lat1) * cos(DEG2RAD*lat2) * cos(DEG2RAD*(long2-long1))
|
|
));
|
|
if (isnan(zeta)) {
|
|
zeta=0;
|
|
}
|
|
return zeta;
|
|
|
|
}
|
|
static float sphereCourse(float lat1, float long1, float lat2, float long2)
|
|
{
|
|
float zeta = sphereDistance(lat1,long1,lat2,long2);
|
|
float angle = RAD2DEG * acos(
|
|
( sin(DEG2RAD*lat2) - sin(DEG2RAD*lat1) * cos(DEG2RAD*zeta) )
|
|
/ ( cos(DEG2RAD*lat1) * sin(DEG2RAD*zeta) )
|
|
);
|
|
if (isnan(angle)) angle=0;
|
|
if (angleDifference(long2-long1)>=0) {
|
|
return angle;
|
|
} else {
|
|
return -angle;
|
|
}
|
|
}
|
|
|
|
/**
|
|
* @}
|
|
* @}
|
|
*/
|