source: flair-src/trunk/demos/OpticalFlow/uav/src/DemoOpticalFlow.cpp@ 315

Last change on this file since 315 was 314, checked in by Sanahuja Guillaume, 6 years ago

maj joystick

File size: 9.8 KB
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[122]1// created: 2011/05/01
2// filename: DemoOpticalFlow.cpp
3//
4// author: Guillaume Sanahuja
5// Copyright Heudiasyc UMR UTC/CNRS 7253
6//
7// version: $Id: $
8//
9// purpose: demo optical flow
10//
11//
12/*********************************************************************/
13
14#include "DemoOpticalFlow.h"
15#include <Uav.h>
16#include <Camera.h>
[165]17#include <V4LCamera.h>
[122]18#include <CvtColor.h>
19#include <OpticalFlow.h>
[155]20#include <OpticalFlowCompensated.h>
[122]21#include <OpticalFlowSpeed.h>
22#include <LowPassFilter.h>
[142]23#include <EulerDerivative.h>
[214]24#include <Matrix.h>
[122]25#include <GridLayout.h>
26#include <DataPlot1D.h>
27#include <Tab.h>
28#include <TabWidget.h>
29#include <GroupBox.h>
30#include <DoubleSpinBox.h>
[124]31#include <PushButton.h>
[122]32#include <FrameworkManager.h>
33#include <MetaDualShock3.h>
34#include <Vector2D.h>
35#include <AhrsData.h>
36#include <Ahrs.h>
37#include <Pid.h>
38
39#include <stdio.h>
40
41using namespace std;
42using namespace flair::core;
43using namespace flair::gui;
44using namespace flair::filter;
45using namespace flair::meta;
46using namespace flair::sensor;
47
48DemoOpticalFlow::DemoOpticalFlow(TargetController *controller): UavStateMachine(controller) {
49 Uav* uav=GetUav();
50 if (uav->GetVerticalCamera() == NULL) {
[131]51 Err("no vertical camera found\n");
[122]52 exit(1);
53 }
[124]54
55 startOpticalflow=new PushButton(GetButtonsLayout()->NewRow(),"start optical flow");
[122]56
[124]57 greyCameraImage=new CvtColor(uav->GetVerticalCamera(),"gray",CvtColor::Conversion_t::ToGray);
[122]58
[124]59 uav->GetVerticalCamera()->UseDefaultPlot(greyCameraImage->Output()); // Le defaultPlot de la caméra peut afficher n'importe quoi?
[122]60
[124]61 //optical flow stack
[147]62 //opticalFlow= matrice de déplacements en pixels entre 2 images consécutives
63 opticalFlow=new OpticalFlow(greyCameraImage,uav->GetVerticalCamera()->GetLayout()->NewRow(),"flux optique");
[156]64 opticalFlowCompensated=new OpticalFlowCompensated(opticalFlow,uav->GetAhrs(),uav->GetVerticalCamera()->GetLayout()->NewRow(),"flux optique compense");
[274]65 opticalFlowSpeedRaw=new OpticalFlowSpeed(opticalFlowCompensated,uav->GetVerticalCamera()->GetLayout()->NewRow(),"vitesse du Flux Optique");
[147]66 //opticalFlowSpeed=vitesse de déplacement en pixels par seconde (moyenne sur tous les points et division par le delta T)
[214]67 Matrix* twoByOneOFS=new Matrix((const Thread*)this,2,1,floatType);
68 Matrix* twoByOneOFAR=new Matrix((const Thread*)this,2,1,floatType);
69 Matrix* twoByOneOFA=new Matrix((const Thread*)this,2,1,floatType);
[155]70 opticalFlowSpeed=new LowPassFilter(opticalFlowSpeedRaw,uav->GetVerticalCamera()->GetLayout()->NewRow(),"Speed lowPass",twoByOneOFS);
71 opticalFlowAccelerationRaw=new EulerDerivative(opticalFlowSpeed,uav->GetVerticalCamera()->GetLayout()->NewRow(),"derivative",twoByOneOFAR);
72 opticalFlowAcceleration=new LowPassFilter(opticalFlowAccelerationRaw,uav->GetVerticalCamera()->GetLayout()->NewRow(),"Acceleration lowPass",twoByOneOFA);
[147]73
74 getFrameworkManager()->AddDeviceToLog(opticalFlowSpeedRaw);
[122]75
[155]76 Tab* opticalFlowTab=new Tab(getFrameworkManager()->GetTabWidget(),"flux optique");
77 DataPlot1D* xVelocityPlot=new DataPlot1D(opticalFlowTab->NewRow(),"x speed (px/s)",-250,250);
78 DataPlot1D* yVelocityPlot=new DataPlot1D(opticalFlowTab->LastRowLastCol(),"y speed (px/s)",-250,250);
79 DataPlot1D* xFirstPointPlot=new DataPlot1D(opticalFlowTab->NewRow(),"x movement first point",-25,25);
80 DataPlot1D* yFirstPointPlot=new DataPlot1D(opticalFlowTab->LastRowLastCol(),"y movement first point",-25,25);
81// DataPlot1D* xAccelerationPlot=new DataPlot1D(opticalFlowTab->NewRow(),"x_acceleration",-250,250);
82// DataPlot1D* yAccelerationPlot=new DataPlot1D(opticalFlowTab->LastRowLastCol(),"y_acceleration",-250,250);
[122]83
[155]84 xVelocityPlot->AddCurve(opticalFlowSpeedRaw->Output()->Element(0,0));
[214]85 xVelocityPlot->AddCurve(opticalFlowSpeed->GetMatrix()->Element(0,0),DataPlot::Blue);
[155]86 yVelocityPlot->AddCurve(opticalFlowSpeedRaw->Output()->Element(1,0));
[214]87 yVelocityPlot->AddCurve(opticalFlowSpeed->GetMatrix()->Element(1,0),DataPlot::Blue);
[155]88 xFirstPointPlot->AddCurve(opticalFlowCompensated->GetFirstPointDisplacement()->Element(0,0));
89 xFirstPointPlot->AddCurve(opticalFlowCompensated->GetFirstPointDisplacement()->Element(1,0),DataPlot::Blue);
90 xFirstPointPlot->AddCurve(opticalFlowCompensated->GetFirstPointDisplacement()->Element(2,0),DataPlot::Green);
[156]91 yFirstPointPlot->AddCurve(opticalFlowCompensated->GetFirstPointDisplacement()->Element(0,1));
92 yFirstPointPlot->AddCurve(opticalFlowCompensated->GetFirstPointDisplacement()->Element(1,1),DataPlot::Blue);
93 yFirstPointPlot->AddCurve(opticalFlowCompensated->GetFirstPointDisplacement()->Element(2,1),DataPlot::Green);
[155]94// xAccelerationPlot->AddCurve(opticalFlowAccelerationRaw->Matrix()->Element(0,0));
95// xAccelerationPlot->AddCurve(opticalFlowAcceleration->Matrix()->Element(0,0),DataPlot::Blue);
96// yAccelerationPlot->AddCurve(opticalFlowAccelerationRaw->Matrix()->Element(1,0));
97// yAccelerationPlot->AddCurve(opticalFlowAcceleration->Matrix()->Element(1,0),DataPlot::Blue);
[122]98
[155]99 u_x=new Pid(setupLawTab->At(1,0),"u_x");
100 u_x->UseDefaultPlot(graphLawTab->NewRow());
101 u_y=new Pid(setupLawTab->At(1,1),"u_y");
102 u_y->UseDefaultPlot(graphLawTab->LastRowLastCol());
[122]103
[314]104 opticalFlowGroupBox=new GroupBox(GetTargetController()->GetTab()->NewRow(),"consignes fo");
[155]105 maxXSpeed=new DoubleSpinBox(opticalFlowGroupBox->NewRow(),"debattement x"," m/s",-5,5,0.1,1);
106 maxYSpeed=new DoubleSpinBox(opticalFlowGroupBox->LastRowLastCol(),"debattement y"," m/s",-5,5,0.1,1);
[154]107
108 Tab* opticalFlowRealTab=new Tab(getFrameworkManager()->GetTabWidget(),"real speed");
[214]109 opticalFlowRealSpeed=new Matrix((const Thread*)this,2,1,floatType);
110 opticalFlowReference=new Matrix((const Thread*)this,2,1,floatType);
111 opticalFlowRealAcceleration=new Matrix((const Thread*)this,2,1,floatType);
[154]112 DataPlot1D* xRealVelocityPlot=new DataPlot1D(opticalFlowRealTab->NewRow(),"x speed (m/s)",-2,2);
[155]113 DataPlot1D* yRealVelocityPlot=new DataPlot1D(opticalFlowRealTab->LastRowLastCol(),"y speed (m/s)",-2,2);
[154]114 DataPlot1D* xRealAccelerationPlot=new DataPlot1D(opticalFlowRealTab->NewRow(),"x acceleration (m/s2)",-2,2);
[155]115 DataPlot1D* yRealAccelerationPlot=new DataPlot1D(opticalFlowRealTab->LastRowLastCol(),"y acceleration (m/s2)",-2,2);
[154]116 xRealVelocityPlot->AddCurve(opticalFlowRealSpeed->Element(0));
[155]117 xRealVelocityPlot->AddCurve(opticalFlowReference->Element(0),DataPlot::Blue,"consigne");
118 yRealVelocityPlot->AddCurve(opticalFlowRealSpeed->Element(1));
[154]119 yRealVelocityPlot->AddCurve(opticalFlowReference->Element(1),DataPlot::Blue,"consigne");
120 xRealAccelerationPlot->AddCurve(opticalFlowRealAcceleration->Element(0));
121 yRealAccelerationPlot->AddCurve(opticalFlowRealAcceleration->Element(1));
[122]122
[155]123 customReferenceOrientation= new AhrsData(this,"reference");
124 uav->GetAhrs()->AddPlot(customReferenceOrientation,DataPlot::Yellow);
125 AddDataToControlLawLog(customReferenceOrientation);
[165]126
127 flagCameraLost=false;
[122]128}
129
130void DemoOpticalFlow::SignalEvent(Event_t event) {
131 switch(event) {
132 case Event_t::EnteringControlLoop:
[314]133 opticalFlowReference->SetValue(0,0,GetTargetController()->GetAxisValue(1)*maxXSpeed->Value());//joy axis 0 maps to x displacement
134 opticalFlowReference->SetValue(1,0,GetTargetController()->GetAxisValue(0)*maxYSpeed->Value());//joy axis 1 maps to y displacement
[154]135 float focal=271.76;
136 float z,dz;
137 AltitudeValues(z, dz);
138 float scale=z/focal;
139 opticalFlowRealSpeed->SetValue(0,0,opticalFlowSpeed->Output(0,0)*scale);
140 opticalFlowRealSpeed->SetValue(1,0,opticalFlowSpeed->Output(1,0)*scale);
141 opticalFlowRealAcceleration->SetValue(0,0,opticalFlowAcceleration->Output(0,0)*scale);
142 opticalFlowRealAcceleration->SetValue(1,0,opticalFlowAcceleration->Output(1,0)*scale);
[122]143 break;
144 }
145}
146
[124]147void DemoOpticalFlow::StartOpticalFlow(void) {
148 if (SetOrientationMode(OrientationMode_t::Custom)) {
149 Thread::Info("(Re)entering optical flow mode\n");
150 u_x->Reset();
151 u_y->Reset();
152 } else {
153 Thread::Warn("Could not enter optical flow mode\n");
154 }
155}
156
157void DemoOpticalFlow::ExtraCheckPushButton(void) {
158 if(startOpticalflow->Clicked()) {
[142]159 StartOpticalFlow();
[124]160 }
161}
162
[122]163void DemoOpticalFlow::ExtraCheckJoystick(void) {
164 static bool wasOpticalFlowModeButtonPressed=false;
165 // controller button R1 enters optical flow mode
[314]166 if(GetTargetController()->IsButtonPressed(9)) { // R1
[122]167 if (!wasOpticalFlowModeButtonPressed) {
168 wasOpticalFlowModeButtonPressed=true;
[124]169 StartOpticalFlow();
[122]170 }
171 } else {
172 wasOpticalFlowModeButtonPressed=false;
173 }
174}
175
176const AhrsData *DemoOpticalFlow::GetReferenceOrientation(void) {
177 Euler refAngles=GetDefaultReferenceOrientation()->GetQuaternion().ToEuler();//to keep default yaw reference
178
[143]179 // /!\ in this demo, the target value is a speed (in m/s). As a consequence the error is the difference between the current speed and the target speed
[167]180 Vector2Df error, errorVariation; // in Uav coordinate system
[154]181
182 error.x=opticalFlowRealSpeed->Value(0,0)-opticalFlowReference->Value(0,0);
183 error.y=opticalFlowRealSpeed->Value(1,0)-opticalFlowReference->Value(1,0);
184 errorVariation.x=opticalFlowRealAcceleration->Value(0,0);
185 errorVariation.y=opticalFlowRealAcceleration->Value(1,0);
[143]186//Printf("Altitude=%f, Error=(%f,%f)\n",z,error.x,error.y);
[122]187
188 u_x->SetValues(error.x, errorVariation.x);
189 u_x->Update(GetTime());
190 refAngles.pitch=u_x->Output();
191
192 u_y->SetValues(error.y, errorVariation.y);
193 u_y->Update(GetTime());
194 refAngles.roll=-u_y->Output();
195
[167]196 customReferenceOrientation->SetQuaternionAndAngularRates(refAngles.ToQuaternion(),Vector3Df(0,0,0));
[122]197
198 return customReferenceOrientation;
199}
200
[165]201void DemoOpticalFlow::ExtraSecurityCheck(void) {
202 if(GetUav()->GetType()=="hds_x8") {
203 if(((V4LCamera*)GetUav()->GetVerticalCamera())->HasProblems() && !flagCameraLost) {
204 flagCameraLost = true;
205 Thread::Err("Camera lost\n");
206 SafeStop();
207 Land();
208 }
209 }
210}
211
[122]212DemoOpticalFlow::~DemoOpticalFlow() {
213}
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