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source: flair-src/trunk/lib/FlairMeta/src/UavStateMachine.cpp@ 135

Last change on this file since 135 was 129, checked in by Sanahuja Guillaume, 7 years ago
resolution bug vrpn client pas demarré
File size: 24.3 KB

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1	// %flair:license{
2	// This file is part of the Flair framework distributed under the
3	// CECILL-C License, Version 1.0.
4	// %flair:license}
5	// created: 2014/04/29
6	// filename: UavStateMachine.cpp
7	//
8	// author: Gildas Bayard, Guillaume Sanahuja
9	// Copyright Heudiasyc UMR UTC/CNRS 7253
10	//
11	// version: $Id: $
12	//
13	// purpose: meta class for UAV
14	//
15	//
16	/*********************************************************************/
17
18	#include "UavStateMachine.h"
19	#include "Uav.h"
20	#include <DataPlot1D.h>
21	#include <GridLayout.h>
22	#include <Tab.h>
23	#include <TabWidget.h>
24	#include <PushButton.h>
25	#include <SpinBox.h>
26	#include <DoubleSpinBox.h>
27	#include <X4X8Multiplex.h>
28	#include <Bldc.h>
29	#include <Ahrs.h>
30	#include <MetaUsRangeFinder.h>
31	#include <ControlLaw.h>
32	#include <Pid.h>
33	#include <PidThrust.h>
34	#include <NestedSat.h>
35	#include <MetaDualShock3.h>
36	#include <AhrsData.h>
37	#include <BatteryMonitor.h>
38	#include <FrameworkManager.h>
39	#include <Vector3D.h>
40	#include <Vector2D.h>
41	#include <cvmatrix.h>
42	#include <stdio.h>
43	#include <TrajectoryGenerator1D.h>
44	#include <math.h>
45
46	using namespace std;
47	using namespace flair::core;
48	using namespace flair::gui;
49	using namespace flair::sensor;
50	using namespace flair::actuator;
51	using namespace flair::filter;
52	using namespace flair::meta;
53
54	UavStateMachine::UavStateMachine(TargetController *controller):
55	Thread(getFrameworkManager(),"UavStateMachine",50),
56	uav(GetUav()),controller(controller),failSafeMode(true),flagConnectionLost(false),flagBatteryLow(false),flagCriticalSensorLost(false),flagZTrajectoryFinished(false),safeToFly(true){
57	altitudeState=AltitudeState_t::Stopped;
58	uav->UseDefaultPlot();
59
60	Tab *uavTab = new Tab(getFrameworkManager()->GetTabWidget(), "uav", 0);
61	buttonslayout = new GridLayout(uavTab->NewRow(), "buttons");
62	button_kill = new PushButton(buttonslayout->NewRow(), "kill");
63	button_start_log = new PushButton(buttonslayout->NewRow(), "start_log");
64	button_stop_log = new PushButton(buttonslayout->LastRowLastCol(), "stop_log");
65	button_take_off = new PushButton(buttonslayout->NewRow(), "take_off");
66	button_land = new PushButton(buttonslayout->LastRowLastCol(), "land");
67
68	Tab *lawTab = new Tab(getFrameworkManager()->GetTabWidget(), "control laws");
69	TabWidget *tabWidget = new TabWidget(lawTab->NewRow(), "laws");
70	setupLawTab = new Tab(tabWidget, "Setup");
71	graphLawTab = new Tab(tabWidget, "Graphes");
72
73	uRoll = new NestedSat(setupLawTab->At(0, 0), "u_roll");
74	uRoll->ConvertSatFromDegToRad();
75	uRoll->UseDefaultPlot(graphLawTab->NewRow());
76
77	uPitch = new NestedSat(setupLawTab->At(0, 1), "u_pitch");
78	uPitch->ConvertSatFromDegToRad();
79	uPitch->UseDefaultPlot(graphLawTab->LastRowLastCol());
80
81	uYaw = new Pid(setupLawTab->At(0, 2), "u_yaw");
82	uYaw->UseDefaultPlot(graphLawTab->LastRowLastCol());
83
84	uZ = new PidThrust(setupLawTab->At(1, 2), "u_z");
85	uZ->UseDefaultPlot(graphLawTab->LastRowLastCol());
86
87	getFrameworkManager()->AddDeviceToLog(uZ);
88	uZ->AddDeviceToLog(uRoll);
89	uZ->AddDeviceToLog(uPitch);
90	uZ->AddDeviceToLog(uYaw);
91
92	joy=new MetaDualShock3(getFrameworkManager(),"uav high level controller",controller);
93	uav->GetAhrs()->AddPlot(joy->GetReferenceOrientation(),DataPlot::Blue);
94
95	altitudeMode = AltitudeMode_t::Manual;
96	orientationMode = OrientationMode_t::Manual;
97	thrustMode = ThrustMode_t::Default;
98	torqueMode = TorqueMode_t::Default;
99
100	GroupBox *reglagesGroupbox =
101	new GroupBox(uavTab->NewRow(), "takeoff/landing");
102	desiredTakeoffAltitude =
103	new DoubleSpinBox(reglagesGroupbox->NewRow(), "desired takeoff altitude",
104	" m", 0, 5, 0.1, 2, 1);
105	desiredLandingAltitude =
106	new DoubleSpinBox(reglagesGroupbox->LastRowLastCol(),
107	"desired landing altitude", " m", 0, 1, 0.1, 1);
108	altitudeTrajectory =
109	new TrajectoryGenerator1D(uavTab->NewRow(), "alt cons", "m");
110	uav->GetMetaUsRangeFinder()->GetZPlot()->AddCurve(
111	altitudeTrajectory->Matrix()->Element(0), DataPlot::Green);
112	uav->GetMetaUsRangeFinder()->GetVzPlot()->AddCurve(
113	altitudeTrajectory->Matrix()->Element(1), DataPlot::Green);
114	}
115
116	UavStateMachine::~UavStateMachine() {}
117
118	void UavStateMachine::AddDeviceToControlLawLog(const IODevice *device) {
119	uZ->AddDeviceToLog(device);
120	}
121
122	void UavStateMachine::AddDataToControlLawLog(const core::io_data *data) {
123	uZ->AddDataToLog(data);
124	}
125
126	const TargetController *UavStateMachine::GetJoystick(void) const {
127	return controller;
128	}
129
130	const Quaternion &UavStateMachine::GetCurrentQuaternion(void) const {
131	return currentQuaternion;
132	}
133
134	const Vector3D &UavStateMachine::GetCurrentAngularSpeed(void) const {
135	return currentAngularSpeed;
136	}
137
138	void UavStateMachine::AltitudeValues(float &altitude,
139	float &verticalSpeed) const {
140	FailSafeAltitudeValues(altitude, verticalSpeed);
141	}
142
143	void UavStateMachine::FailSafeAltitudeValues(float &altitude,
144	float &verticalSpeed) const {
145	altitude = uav->GetMetaUsRangeFinder()->z();
146	verticalSpeed = uav->GetMetaUsRangeFinder()->Vz();
147	}
148
149	void UavStateMachine::Run() {
150	WarnUponSwitches(true);
151	uav->StartSensors();
152
153	if (getFrameworkManager()->ErrorOccured() == true) {
154	SafeStop();
155	}
156
157	while (!ToBeStopped()) {
158	SecurityCheck();
159
160	// get controller inputs
161	CheckJoystick();
162	CheckPushButton();
163
164	if (IsPeriodSet()) {
165	WaitPeriod();
166	} else {
167	WaitUpdate(uav->GetAhrs());
168	}
169	needToComputeDefaultTorques = true;
170	needToComputeDefaultThrust = true;
171
172	SignalEvent(Event_t::EnteringControlLoop);
173
174	ComputeOrientation();
175	ComputeAltitude();
176
177	// compute thrust and torques to apply
178	ComputeTorques();
179	ComputeThrust(); // logs are added to uz, so it must be updated at last
180
181	//check nan/inf problems
182	if(!IsValuePossible(currentTorques.roll,"roll torque")
183	\|\| !IsValuePossible(currentTorques.pitch,"pitch torque")
184	\|\| !IsValuePossible(currentTorques.yaw,"yaw torque")
185	\|\| !IsValuePossible(currentThrust,"thrust")) {
186
187	if(altitudeState==AltitudeState_t::Stopped) {
188	SafeStop();
189	} else {
190
191	if(failSafeMode) {
192	Warn("We are already in safe mode, the uav is going to crash!\n");
193	} else {
194	Thread::Warn("switching back to safe mode\n");
195	EnterFailSafeMode();
196	needToComputeDefaultTorques = true;//should not be necessary, but put it to be sure to compute default thrust/torques
197	needToComputeDefaultThrust = true;
198
199	ComputeTorques();
200	ComputeThrust();
201	}
202	}
203	}
204
205	// Set torques for roll, pitch and yaw angles (value between -1 and 1). Set
206	// thrust (value between 0 and 1)
207	uav->GetUavMultiplex()->SetRoll(-currentTorques.roll);
208	uav->GetUavMultiplex()->SetPitch(-currentTorques.pitch);
209	uav->GetUavMultiplex()->SetYaw(-currentTorques.yaw);
210	uav->GetUavMultiplex()->SetThrust(-currentThrust); // on raisonne en negatif
211	// sur l'altitude, a
212	// revoir avec les
213	// equations
214	uav->GetUavMultiplex()->SetRollTrim(joy->RollTrim());
215	uav->GetUavMultiplex()->SetPitchTrim(joy->PitchTrim());
216	uav->GetUavMultiplex()->SetYawTrim(0);
217	uav->GetUavMultiplex()->Update(GetTime());
218	}
219
220	WarnUponSwitches(false);
221	}
222
223	bool UavStateMachine::IsValuePossible(float value,std::string desc) {
224	if(isnan(value)) {
225	Warn("%s is not an number\n",desc.c_str());
226	return false;
227	} else if(isinf(value)) {
228	Warn("%s is infinite\n",desc.c_str());
229	return false;
230	} else {
231	return true;
232	}
233	}
234
235
236	void UavStateMachine::ComputeOrientation(void) {
237	if (failSafeMode) {
238	GetDefaultOrientation()->GetQuaternionAndAngularRates(currentQuaternion,
239	currentAngularSpeed);
240	} else {
241	GetOrientation()->GetQuaternionAndAngularRates(currentQuaternion,
242	currentAngularSpeed);
243	}
244	}
245
246	const AhrsData *UavStateMachine::GetOrientation(void) const {
247	return GetDefaultOrientation();
248	}
249
250	const AhrsData *UavStateMachine::GetDefaultOrientation(void) const {
251	return uav->GetAhrs()->GetDatas();
252	}
253
254	void UavStateMachine::ComputeAltitude(void) {
255	if (failSafeMode) {
256	FailSafeAltitudeValues(currentAltitude, currentVerticalSpeed);
257	} else {
258	AltitudeValues(currentAltitude, currentVerticalSpeed);
259	}
260	}
261
262	void UavStateMachine::ComputeReferenceAltitude(float &refAltitude,
263	float &refVerticalVelocity) {
264	if (altitudeMode == AltitudeMode_t::Manual) {
265	GetDefaultReferenceAltitude(refAltitude, refVerticalVelocity);
266	} else {
267	GetReferenceAltitude(refAltitude, refVerticalVelocity);
268	}
269	}
270
271	void UavStateMachine::GetDefaultReferenceAltitude(float &refAltitude,
272	float &refVerticalVelocity) {
273	float zc, dzc;
274
275	switch (altitudeState) {
276	// initiate a takeoff: increase motor speed in open loop (see ComputeThrust)
277	// until we detect a take off of 0.03m (hard coded value) above the ground.
278	case AltitudeState_t::TakingOff: {
279	if (currentAltitude > groundAltitude + 0.03) {
280	altitudeTrajectory->StartTraj(currentAltitude,
281	desiredTakeoffAltitude->Value());
282	altitudeState = AltitudeState_t::Stabilized;
283	SignalEvent(Event_t::Stabilized);
284	}
285	break;
286	}
287	// landing, only check if we reach desired landing altitude
288	case AltitudeState_t::StartLanding: {
289	if (altitudeTrajectory->Position() == desiredLandingAltitude->Value()) {
290	// The Uav target altitude has reached its landing value (typically 0)
291	// but the real Uav altitude may not have reach this value yet because of
292	// command delay. Moreover, it may never exactly reach this value if the
293	// ground is not perfectly leveled (critical case: there's a
294	// deep and narrow hole right in the sensor line of sight). That's why we
295	// have a 2 phases landing strategy.
296	altitudeState = AltitudeState_t::FinishLanding;
297	SignalEvent(Event_t::FinishLanding);
298	joy->SetLedOFF(1); // DualShock3::led1
299	}
300	}
301	// stabilized: check if z trajectory is finished
302	case AltitudeState_t::Stabilized: {
303	if (!altitudeTrajectory->IsRunning() && !flagZTrajectoryFinished) {
304	SignalEvent(Event_t::ZTrajectoryFinished);
305	flagZTrajectoryFinished = true;
306	}
307	if (flagZTrajectoryFinished && desiredTakeoffAltitude->ValueChanged()) {
308	flagZTrajectoryFinished = false;
309	altitudeTrajectory->StartTraj(currentAltitude,
310	desiredTakeoffAltitude->Value());
311	joy->SetZRef(0);
312	}
313	}
314	}
315
316	// Récupère les consignes (du joystick dans l'implémentation par défaut). La
317	// consigne joystick est une vitesse ("delta_z", dzc). le zc est calculé par
318	// la manette
319	zc = joy->ZRef(); // a revoir, la position offset devrait se calculer dans le
320	// generator
321	dzc = joy->DzRef();
322
323	// z control law
324	altitudeTrajectory->SetPositionOffset(zc);
325	altitudeTrajectory->SetSpeedOffset(dzc);
326
327	altitudeTrajectory->Update(GetTime());
328	refAltitude = altitudeTrajectory->Position();
329	refVerticalVelocity = altitudeTrajectory->Speed();
330	}
331
332	void UavStateMachine::GetReferenceAltitude(float &refAltitude,
333	float &refVerticalVelocity) {
334	Thread::Warn("Default GetReferenceAltitude method is not overloaded => "
335	"switching back to safe mode\n");
336	EnterFailSafeMode();
337	};
338
339	void UavStateMachine::ComputeThrust(void) {
340	if (altitudeMode == AltitudeMode_t::Manual) {
341	currentThrust = ComputeDefaultThrust();
342	} else {
343	currentThrust = ComputeCustomThrust();
344	}
345	}
346
347	float UavStateMachine::ComputeDefaultThrust(void) {
348	if (needToComputeDefaultThrust) {
349	// compute desired altitude
350	float refAltitude, refVerticalVelocity;
351	ComputeReferenceAltitude(refAltitude, refVerticalVelocity);
352
353	switch (altitudeState) {
354	case AltitudeState_t::TakingOff: {
355	// The progressive increase in motor speed is used to evaluate the motor
356	// speed that compensate the uav weight. This value
357	// will be used as an offset for altitude control afterwards
358	uZ->OffsetStepUp();
359	break;
360	}
361	case AltitudeState_t::StartLanding:
362	case AltitudeState_t::Stabilized: {
363	float p_error = currentAltitude - refAltitude;
364	float d_error = currentVerticalSpeed - refVerticalVelocity;
365	uZ->SetValues(p_error, d_error);
366	break;
367	}
368	// decrease motor speed in open loop until value offset_g , uav should have
369	// already landed or be very close to at this point
370	case AltitudeState_t::FinishLanding: {
371	if (uZ->OffsetStepDown() == false) {
372	StopMotors();
373	}
374	break;
375	}
376	}
377	uZ->Update(GetTime());
378
379	savedDefaultThrust = uZ->Output();
380	needToComputeDefaultThrust = false;
381	}
382
383	return savedDefaultThrust;
384	}
385
386	float UavStateMachine::ComputeCustomThrust(void) {
387	Thread::Warn("Default GetThrust method is not overloaded => switching back "
388	"to safe mode\n");
389	EnterFailSafeMode();
390	return ComputeDefaultThrust();
391	}
392
393	const AhrsData *UavStateMachine::ComputeReferenceOrientation(void) {
394	if (orientationMode == OrientationMode_t::Manual) {
395	return GetDefaultReferenceOrientation();
396	} else {
397	return GetReferenceOrientation();
398	}
399	}
400
401	const AhrsData *UavStateMachine::GetDefaultReferenceOrientation(void) const {
402	// We directly control yaw, pitch, roll angles
403	return joy->GetReferenceOrientation();
404	}
405
406	const AhrsData *UavStateMachine::GetReferenceOrientation(void) {
407	Thread::Warn("Default GetReferenceOrientation method is not overloaded => "
408	"switching back to safe mode\n");
409	EnterFailSafeMode();
410	return GetDefaultReferenceOrientation();
411	}
412
413	void UavStateMachine::ComputeTorques(void) {
414	if (torqueMode == TorqueMode_t::Default) {
415	ComputeDefaultTorques(currentTorques);
416	} else {
417	ComputeCustomTorques(currentTorques);
418	}
419	}
420
421	void UavStateMachine::ComputeDefaultTorques(Euler &torques) {
422	if (needToComputeDefaultTorques) {
423	const AhrsData *refOrientation = ComputeReferenceOrientation();
424	Quaternion refQuaternion;
425	Vector3D refAngularRates;
426	refOrientation->GetQuaternionAndAngularRates(refQuaternion,
427	refAngularRates);
428	Euler refAngles = refQuaternion.ToEuler();
429	Euler currentAngles = currentQuaternion.ToEuler();
430
431	uYaw->SetValues(currentAngles.YawDistanceFrom(refAngles.yaw),
432	currentAngularSpeed.z - refAngularRates.z);
433	uYaw->Update(GetTime());
434	torques.yaw = uYaw->Output();
435
436	uPitch->SetValues(refAngles.pitch, currentAngles.pitch,
437	currentAngularSpeed.y);
438	uPitch->Update(GetTime());
439	torques.pitch = uPitch->Output();
440
441	uRoll->SetValues(refAngles.roll, currentAngles.roll, currentAngularSpeed.x);
442	uRoll->Update(GetTime());
443	torques.roll = uRoll->Output();
444
445	savedDefaultTorques = torques;
446	needToComputeDefaultTorques = false;
447	} else {
448	torques = savedDefaultTorques;
449	}
450	}
451
452	void UavStateMachine::ComputeCustomTorques(Euler &torques) {
453	Thread::Warn("Default ComputeCustomTorques method is not overloaded => "
454	"switching back to safe mode\n");
455	EnterFailSafeMode();
456	ComputeDefaultTorques(torques);
457	}
458
459	void UavStateMachine::TakeOff(void) {
460	flagZTrajectoryFinished = false;
461
462	if((altitudeState==AltitudeState_t::Stopped) && safeToFly) {// && GetBatteryMonitor()->IsBatteryLow()==false)
463	//The uav always takes off in fail safe mode
464	EnterFailSafeMode();
465	joy->SetLedOFF(4);//DualShock3::led4
466	joy->SetLedOFF(1);//DualShock3::led1
467	joy->Rumble(0x70);
468	joy->SetZRef(0);
469
470	uZ->SetOffset(); // positionne l'offset de compensation de la gravité à sa
471	// valeur initiale (station sol)
472
473	uav->GetUavMultiplex()->LockUserInterface();
474	// Active les moteurs. Pouvoir les désactiver permet de pouvoir observer les
475	// consignes moteurs
476	// sans les faire tourner effectivement (en déplaçant à la main le drone)
477	uav->GetBldc()->SetEnabled(true);
478	groundAltitude = currentAltitude;
479	altitudeState = AltitudeState_t::TakingOff;
480
481	SignalEvent(Event_t::TakingOff);
482	} else {
483	joy->ErrorNotify();
484	}
485	}
486
487	void UavStateMachine::Land(void) {
488	if (altitudeMode != AltitudeMode_t::Manual) {
489	SetAltitudeMode(AltitudeMode_t::Manual);
490	}
491	if (altitudeState == AltitudeState_t::Stabilized) {
492	joy->SetLedOFF(4); // DualShock3::led4
493	joy->Rumble(0x70);
494
495	altitudeTrajectory->StopTraj();
496	joy->SetZRef(0);
497	altitudeTrajectory->StartTraj(currentAltitude,desiredLandingAltitude->Value()); //shouldn't it be groundAltitude?
498	SignalEvent(Event_t::StartLanding);
499	altitudeState=AltitudeState_t::StartLanding;
500	} else if (altitudeState==AltitudeState_t::TakingOff) {
501	EmergencyLand();
502	} else {
503	joy->ErrorNotify();
504	}
505	}
506
507	void UavStateMachine::EmergencyLand(void) {
508	//Gradually decrease motor speed
509	//Called if landing is required during take off (motors are accelerating but Uav did not actually left the ground yet), or if critical sensors have been lost (attitude is lost)
510	altitudeState=AltitudeState_t::FinishLanding;
511	safeToFly=false;
512	Printf("Emergency landing!\n");
513	}
514
515	void UavStateMachine::SignalEvent(Event_t event) {
516	switch (event) {
517	case Event_t::StartLanding:
518	Thread::Info("Altitude: entering 'StartLanding' state\n");
519	break;
520	case Event_t::Stopped:
521	Thread::Info("Altitude: entering 'Stopped' state\n");
522	break;
523	case Event_t::TakingOff:
524	Thread::Info("Altitude: taking off\n");
525	break;
526	case Event_t::Stabilized:
527	Thread::Info("Altitude: entering 'Stabilized' state\n");
528	break;
529	case Event_t::FinishLanding:
530	Thread::Info("Altitude: entering 'FinishLanding' state\n");
531	break;
532	case Event_t::EmergencyStop:
533	Thread::Info("Emergency stop!\n");
534	break;
535	}
536	}
537
538	void UavStateMachine::EmergencyStop(void) {
539	if(altitudeState!=AltitudeState_t::Stopped) {
540	StopMotors();
541	EnterFailSafeMode();
542	joy->Rumble(0x70);
543	SignalEvent(Event_t::EmergencyStop);
544	}
545	safeToFly=false;
546	Warn("Emergency stop, UAV will not take off again until program is rerunned\n");
547	}
548
549	void UavStateMachine::StopMotors(void) {
550	joy->FlashLed(1, 10, 10); // DualShock3::led1
551	uav->GetBldc()->SetEnabled(false);
552	uav->GetUavMultiplex()->UnlockUserInterface();
553	SignalEvent(Event_t::Stopped);
554	altitudeState = AltitudeState_t::Stopped;
555	uav->GetAhrs()->UnlockUserInterface();
556
557	uZ->SetValues(0, 0);
558	uZ->Reset();
559	}
560
561	GridLayout *UavStateMachine::GetButtonsLayout(void) const {
562	return buttonslayout;
563	}
564
565	void UavStateMachine::SecurityCheck(void) {
566	MandatorySecurityCheck();
567	ExtraSecurityCheck();
568	}
569
570	void UavStateMachine::MandatorySecurityCheck(void) {
571	if (getFrameworkManager()->ConnectionLost() && !flagConnectionLost) {
572	flagConnectionLost = true;
573	Thread::Err("Connection lost\n");
574	EnterFailSafeMode();
575	if (altitudeState == AltitudeState_t::Stopped) {
576	SafeStop();
577	} else {
578	Land();
579	}
580	}
581	if((altitudeState==AltitudeState_t::TakingOff \|\| altitudeState==AltitudeState_t::Stabilized) && uav->GetBatteryMonitor()->IsBatteryLow() && !flagBatteryLow) {
582	flagBatteryLow=true;
583	Thread::Err("Low Battery\n");
584	EnterFailSafeMode();
585	Land();
586	}/*
587	Time now=GetTime();
588	if ((altitudeState==AltitudeState_t::Stopped) && (now-uav->GetAhrs()->lastUpdate>(Time)10010001000)) { //100ms
589	flagCriticalSensorLost=true;
590	Thread::Err("Critical sensor lost\n");
591	EnterFailSafeMode();
592	EmergencyLand();
593	}*/
594	}
595
596	void UavStateMachine::CheckJoystick(void) {
597	GenericCheckJoystick();
598	ExtraCheckJoystick();
599	}
600
601	void UavStateMachine::GenericCheckJoystick(void) {
602	static bool isEmergencyStopButtonPressed = false;
603	static bool isTakeOffButtonPressed = false;
604	static bool isSafeModeButtonPressed = false;
605
606	if (controller->IsButtonPressed(1)) { // select
607	if (!isEmergencyStopButtonPressed) {
608	isEmergencyStopButtonPressed = true;
609	Thread::Info("Emergency stop from joystick\n");
610	EmergencyStop();
611	}
612	} else
613	isEmergencyStopButtonPressed = false;
614
615	if (controller->IsButtonPressed(0)) { // start
616	if (!isTakeOffButtonPressed) {
617	isTakeOffButtonPressed = true;
618	switch (altitudeState) {
619	case AltitudeState_t::Stopped:
620	TakeOff();
621	break;
622	case AltitudeState_t::Stabilized:
623	Land();
624	break;
625	default:
626	joy->ErrorNotify();
627	break;
628	}
629	}
630	} else
631	isTakeOffButtonPressed = false;
632
633	// cross
634	// gsanahuj:conflict with Majd programs.
635	// check if l1,l2,r1 and r2 are not pressed
636	// to allow a combination in user program
637	if (controller->IsButtonPressed(5) && !controller->IsButtonPressed(6) &&
638	!controller->IsButtonPressed(7) && !controller->IsButtonPressed(9) &&
639	!controller->IsButtonPressed(10)) {
640	if (!isSafeModeButtonPressed) {
641	isSafeModeButtonPressed = true;
642	Thread::Info("Entering fail safe mode\n");
643	EnterFailSafeMode();
644	}
645	} else
646	isSafeModeButtonPressed = false;
647	}
648
649	void UavStateMachine::CheckPushButton(void) {
650	GenericCheckPushButton();
651	ExtraCheckPushButton();
652	}
653
654	void UavStateMachine::GenericCheckPushButton(void) {
655	if (button_kill->Clicked() == true)
656	SafeStop();
657	if (button_take_off->Clicked() == true)
658	TakeOff();
659	if (button_land->Clicked() == true)
660	Land();
661	if (button_start_log->Clicked() == true)
662	getFrameworkManager()->StartLog();
663	if (button_stop_log->Clicked() == true)
664	getFrameworkManager()->StopLog();
665	}
666
667	void UavStateMachine::EnterFailSafeMode(void) {
668	if(altitudeState!=AltitudeState_t::StartLanding) SetAltitudeMode(AltitudeMode_t::Manual);//
669	SetOrientationMode(OrientationMode_t::Manual);
670	SetThrustMode(ThrustMode_t::Default);
671	SetTorqueMode(TorqueMode_t::Default);
672
673	GetDefaultOrientation()->GetQuaternionAndAngularRates(currentQuaternion,
674	currentAngularSpeed);
675	joy->SetYawRef(currentQuaternion);
676	uYaw->Reset();
677	uPitch->Reset();
678	uRoll->Reset();
679
680	failSafeMode = true;
681	SignalEvent(Event_t::EnteringFailSafeMode);
682	}
683
684	bool UavStateMachine::ExitFailSafeMode(void) {
685	// only exit fail safe mode if in Stabilized altitude state
686	// gsanahuj: pour la demo inaugurale on ne peut pas etre en failsafe
687	// le ruban perturbe l'us
688	/*
689	if (altitudeState!=AltitudeState_t::Stabilized) {
690	return false;
691	} else*/ {
692	failSafeMode = false;
693	return true;
694	}
695	}
696
697	bool UavStateMachine::SetTorqueMode(TorqueMode_t const &newTorqueMode) {
698	if ((newTorqueMode == TorqueMode_t::Custom) && (failSafeMode)) {
699	if (!ExitFailSafeMode())
700	return false;
701	}
702	// When transitionning from Custom to Default torque mode, we should reset the
703	// default control laws
704	if ((torqueMode == TorqueMode_t::Custom) &&
705	(newTorqueMode == TorqueMode_t::Default)) {
706	uYaw->Reset();
707	uPitch->Reset();
708	uRoll->Reset();
709	}
710	torqueMode = newTorqueMode;
711	return true;
712	}
713
714	bool UavStateMachine::SetAltitudeMode(AltitudeMode_t const &newAltitudeMode) {
715	if ((newAltitudeMode == AltitudeMode_t::Custom) && (failSafeMode)) {
716	if (!ExitFailSafeMode())
717	return false;
718	}
719	altitudeMode = newAltitudeMode;
720	GotoAltitude(desiredTakeoffAltitude->Value());
721
722	return true;
723	}
724
725	bool UavStateMachine::GotoAltitude(float desiredAltitude) {
726	if (altitudeMode != AltitudeMode_t::Manual) {
727	return false;
728	}
729	altitudeTrajectory->StartTraj(uav->GetMetaUsRangeFinder()->z(),
730	desiredAltitude);
731	return true;
732	}
733
734	bool UavStateMachine::SetOrientationMode(
735	OrientationMode_t const &newOrientationMode) {
736	if ((newOrientationMode == OrientationMode_t::Custom) && (failSafeMode)) {
737	if (!ExitFailSafeMode())
738	return false;
739	}
740	// When transitionning from Custom to Manual mode we must reset to yaw
741	// reference to the current absolute yaw angle,
742	// overwise the Uav will abruptly change orientation
743	if ((orientationMode == OrientationMode_t::Custom) &&
744	(newOrientationMode == OrientationMode_t::Manual)) {
745	joy->SetYawRef(currentQuaternion);
746	}
747	orientationMode = newOrientationMode;
748	return true;
749	}
750
751	bool UavStateMachine::SetThrustMode(ThrustMode_t const &newThrustMode) {
752	if ((newThrustMode == ThrustMode_t::Custom) && (failSafeMode)) {
753	if (!ExitFailSafeMode())
754	return false;
755	}
756	thrustMode = newThrustMode;
757	return true;
758	}

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