createOrte();
createRobots();
createActions();
+ createMap();
+
+// connect(vidle, SIGNAL(valueChanged(int)),
+// robotEstPosBest, SLOT(setVidle(int)));
setFocusPolicy(Qt::StrongFocus);
sharedMemoryOpened = false;
void RobomonAtlantis::createLeftLayout()
{
leftLayout = new QVBoxLayout();
-
+
createDebugGroupBox();
debugWindowEnabled = true;
createPlaygroundGroupBox();
void RobomonAtlantis::createRightLayout()
{
rightLayout = new QVBoxLayout();
-
+
createPositionGroupBox();
createMiscGroupBox();
createFSMGroupBox();
playgroundSceneView->setMatrix(QMatrix(1,0,0,-1,0,0), true);
playgroundSceneView->fitInView(playgroundScene->itemsBoundingRect());
playgroundSceneView->setSizePolicy(QSizePolicy::Expanding, QSizePolicy::Expanding);
+ playgroundSceneView->setMouseTracking(true);
layout->addWidget(playgroundSceneView);
playgroundGroupBox->setLayout(layout);
positionGroupBox = new QGroupBox(tr("Position state"));
positionGroupBox->setSizePolicy(QSizePolicy::Fixed, QSizePolicy::Expanding);
QGridLayout *layout = new QGridLayout();
-
+
actPosX = new QLineEdit();
actPosY = new QLineEdit();
actPosPhi = new QLineEdit();
estPosX = new QLineEdit();
estPosY = new QLineEdit();
estPosPhi = new QLineEdit();
-
+
actPosX->setReadOnly(true);
actPosY->setReadOnly(true);
actPosPhi->setReadOnly(true);
obstacleSimulationCheckBox->setShortcut(tr("o"));
layout->addWidget(obstacleSimulationCheckBox);
- startPlug = new QCheckBox("Start plug");
+ startPlug = new QCheckBox("&Start plug");
layout->addWidget(startPlug);
-
- puckInside = new QCheckBox("Puck inside");
- layout->addWidget(puckInside);
-
+
+ colorChoser = new QCheckBox("&Team color");
+ layout->addWidget(colorChoser);
+
+ strategyButton= new QPushButton(tr("Strategy"));
+ layout->addWidget(strategyButton);
+
miscGroupBox->setLayout(layout);
}
actuatorsGroupBox = new QGroupBox(tr("Actuators"));
actuatorsGroupBox->setSizePolicy(QSizePolicy::Fixed, QSizePolicy::Preferred);
QHBoxLayout *layout = new QHBoxLayout();
+// vidle = new QDial();
+
+// vidle->setMinimum(VIDLE_VYSIP);
+// vidle->setMaximum((VIDLE_UP-VIDLE_VYSIP)+VIDLE_VYSIP);
+// vidle->setEnabled(true);
//createMotorsGroupBox();
layout->setAlignment(Qt::AlignLeft);
+// layout->addWidget(vidle);
//layout->addWidget(enginesGroupBox);
actuatorsGroupBox->setLayout(layout);
}
powerGroupBox->setLayout(layout);
}
-#if 0
-void RobomonAtlantis::createMotorsGroupBox()
-{
- enginesGroupBox = new QGroupBox(tr("Motors"));
- QVBoxLayout *layout = new QVBoxLayout();
- QHBoxLayout *layout1 = new QHBoxLayout();
- QHBoxLayout *layout2 = new QHBoxLayout();
-
- leftMotorSlider = new QSlider(Qt::Vertical);
- rightMotorSlider = new QSlider(Qt::Vertical);
- bothMotorsCheckBox = new QCheckBox(tr("Lock both"));
- stopMotorsPushButton = new QPushButton(tr("Stop Motors"));
-
- leftMotorSlider->setMinimum(-100);
- leftMotorSlider->setMaximum(100);
- leftMotorSlider->setTracking(false);
- leftMotorSlider->setTickPosition(QSlider::TicksLeft);
-
- rightMotorSlider->setMinimum(-100);
- rightMotorSlider->setMaximum(100);
- rightMotorSlider->setTracking(false);
- rightMotorSlider->setTickPosition(QSlider::TicksRight);
-
- stopMotorsPushButton->setMaximumWidth(90);
-
- layout1->addWidget(leftMotorSlider);
- layout1->addWidget(MiscGui::createLabel("0"));
- layout1->addWidget(rightMotorSlider);
-
- layout2->addWidget(bothMotorsCheckBox);
-
- layout->addWidget(MiscGui::createLabel("100"));
- layout->addLayout(layout1);
- layout->addWidget(MiscGui::createLabel("-100"));
- layout->addLayout(layout2);
- layout->addWidget(stopMotorsPushButton);
- enginesGroupBox->setLayout(layout);
-}
-#endif
-
void RobomonAtlantis::createRobots()
{
robotRefPos = new Robot("Ref", QPen(Qt::darkBlue), QBrush(Qt::NoBrush));
robotRefPos->setZValue(11);
trailRefPos = new Trail(QPen(Qt::darkBlue));
trailRefPos->setZValue(11);
-
+
robotEstPosBest = new Robot("Est", QPen(), QBrush(Qt::darkGray));
robotEstPosBest->setZValue(10);
trailEstPosBest = new Trail(QPen());
playgroundScene->addItem(robotEstPosBest);
playgroundScene->addItem(robotEstPosIndepOdo);
playgroundScene->addItem(robotEstPosOdo);
-
+
showTrails(false);
-
+
playgroundScene->addItem(trailRefPos);
playgroundScene->addItem(trailPosIndepOdo);
playgroundScene->addItem(trailOdoPos);
hokuyoScan = new HokuyoScan();
hokuyoScan->setZValue(10);
playgroundScene->addItem(hokuyoScan);
-
+
+}
+
+void RobomonAtlantis::createMap()
+{
+ mapImage = new Map();
+ mapImage->setZValue(5);
+ mapImage->setTransform(QTransform().scale(MAP_CELL_SIZE_MM, MAP_CELL_SIZE_MM), true);
+
+
+ playgroundScene->addItem(mapImage);
}
/**********************************************************************
void RobomonAtlantis::createActions()
{
/* power management */
- connect(voltage33CheckBox, SIGNAL(stateChanged(int)),
+ connect(voltage33CheckBox, SIGNAL(stateChanged(int)),
this, SLOT(setVoltage33(int)));
- connect(voltage50CheckBox, SIGNAL(stateChanged(int)),
+ connect(voltage50CheckBox, SIGNAL(stateChanged(int)),
this, SLOT(setVoltage50(int)));
- connect(voltage80CheckBox, SIGNAL(stateChanged(int)),
+ connect(voltage80CheckBox, SIGNAL(stateChanged(int)),
this, SLOT(setVoltage80(int)));
/* motors */
-// connect(leftMotorSlider, SIGNAL(valueChanged(int)),
+// connect(leftMotorSlider, SIGNAL(valueChanged(int)),
// this, SLOT(setLeftMotor(int)));
-// connect(rightMotorSlider, SIGNAL(valueChanged(int)),
+// connect(rightMotorSlider, SIGNAL(valueChanged(int)),
// this, SLOT(setRightMotor(int)));
-// connect(stopMotorsPushButton, SIGNAL(clicked()),
+// connect(stopMotorsPushButton, SIGNAL(clicked()),
// this, SLOT(stopMotors()));
connect(startPlug, SIGNAL(stateChanged(int)), this, SLOT(sendStart(int)));
-
+ connect(colorChoser, SIGNAL(stateChanged(int)), this, SLOT(setTeamColor(int)));
+ connect(strategyButton, SIGNAL(pressed()), this, SLOT(changeStrategy_1()));
+ connect(strategyButton, SIGNAL(released()), this, SLOT(changeStrategy_0()));
+
/* obstacle simulation */
simulationEnabled = 0;
connect(obstacleSimulationCheckBox, SIGNAL(stateChanged(int)),
this, SLOT(setObstacleSimulation(int)));
connect(obstacleSimulationCheckBox, SIGNAL(stateChanged(int)),
playgroundScene, SLOT(showObstacle(int)));
- connect(playgroundScene, SIGNAL(obstacleChanged(QPointF)),
+ connect(playgroundScene, SIGNAL(obstacleChanged(QPointF)),
this, SLOT(changeObstacle(QPointF)));
}
+void RobomonAtlantis::changeStrategy_1()
+{
+ orte.robot_switches.strategy = true;
+ ORTEPublicationSend(orte.publication_robot_switches);
+}
+
+void RobomonAtlantis::changeStrategy_0()
+{
+ orte.robot_switches.strategy = false;
+ ORTEPublicationSend(orte.publication_robot_switches);
+}
+
void RobomonAtlantis::setVoltage33(int state)
{
if (state)
// {
// short int leftMotor;
// short int rightMotor;
-
+
// if(bothMotorsCheckBox->isChecked())
// rightMotorSlider->setValue(value);
// leftMotor = (short int)(MOTOR_LIMIT * (leftMotorSlider->value()/100.0));
// rightMotor = (short int)(MOTOR_LIMIT * (rightMotorSlider->value()/100.0));
-
+
// orte.motion_speed.left = leftMotor;
// orte.motion_speed.right = rightMotor;
-
+
// }
// void RobomonAtlantis::setRightMotor(int value)
// {
// short int leftMotor;
// short int rightMotor;
-
+
// if(bothMotorsCheckBox->isChecked())
// leftMotorSlider->setValue(value);
// leftMotor = (short int)(MOTOR_LIMIT * (leftMotorSlider->value()/100.0));
// rightMotor = (short int)(MOTOR_LIMIT * (rightMotorSlider->value()/100.0));
-
+
// orte.motion_speed.left = leftMotor;
// orte.motion_speed.right = rightMotor;
-
+
// }
// void RobomonAtlantis::stopMotors()
if (sharedMemoryOpened == false)
return;
-
+
if (show) {
mapTimer = new QTimer(this);
connect(mapTimer, SIGNAL(timeout()), this, SLOT(paintMap()));
disconnect(mapTimer, SIGNAL(timeout()), this, SLOT(paintMap()));
}
}
- playgroundScene->showMap(show);
+ mapImage->setVisible(show);
}
void RobomonAtlantis::paintMap()
struct map *map = ShmapIsMapInit();
if (!map) return;
-
- for(int i=0; i < MAP_WIDTH; i++) {
- for(int j=0; j<MAP_HEIGHT; j++) {
+
+ for(int i = 0; i < MAP_WIDTH; i++) {
+ for(int j = 0; j < MAP_HEIGHT; j++) {
QColor color;
-
+
struct map_cell *cell = &map->cells[j][i];
color = lightGray;
}
if (cell->flags & MAP_FLAG_DET_OBST)
color = cyan;
-
- playgroundScene->setMapColor(i, j, color);
+
+ color.setAlpha(200);
+ mapImage->setPixelColor(i, MAP_HEIGHT - j - 1, color);
}
}
}
void RobomonAtlantis::setSimulation(int state)
{
- if(state) {
+ if(state) {
robottype_publisher_hokuyo_scan_create(&orte, NULL, this);
} else {
if (!simulationEnabled)
simulationEnabled = state;
}
-/*!
+/*!
\fn RobomonAtlantis::setObstacleSimulation(int state)
*/
void RobomonAtlantis::setObstacleSimulation(int state)
/* TODO Maybe it is possible to attach only once to Shmap */
ShmapInit(0);
obstacleSimulationTimer = new QTimer(this);
- connect(obstacleSimulationTimer, SIGNAL(timeout()),
+ connect(obstacleSimulationTimer, SIGNAL(timeout()),
this, SLOT(simulateObstaclesHokuyo()));
obstacleSimulationTimer->start(100);
setMouseTracking(true);
} else {
- if (obstacleSimulationTimer)
+ if (obstacleSimulationTimer)
delete obstacleSimulationTimer;
//double distance = 0.8;
}
double distance, wall_distance;
unsigned int i;
uint16_t *hokuyo = orte.hokuyo_scan.data;
-
+
for (i=0; i<HOKUYO_ARRAY_SIZE; i++) {
wall_distance = distanceToWallHokuyo(i);
- distance = distanceToObstacleHokuyo(i, simulatedObstacle, SIM_OBST_SIZE_M/*meters*/);
- if (wall_distance < distance)
+
+ distance = distanceToCircularObstacleHokuyo(i, simulatedObstacle, SIM_OBST_SIZE_M);
+ if (wall_distance < distance)
distance = wall_distance;
hokuyo[i] = distance*1000;
}
ORTEPublicationSend(orte.publication_hokuyo_scan);
-
+
}
void RobomonAtlantis::changeObstacle(QPointF position)
simulatedObstacle.x = position.x();
simulatedObstacle.y = position.y();
simulateObstaclesHokuyo();
-}
+}
/**********************************************************************
* EVENTS
case QEVENT(QEV_HOKUYO_SCAN):
hokuyoScan->newScan(&orte.hokuyo_scan);
break;
+ case QEVENT(QEV_JAWS_CMD):
+ robotEstPosBest->setJaws(orte.jaws_cmd.req_pos.left);
+ robotRefPos->setJaws(orte.jaws_cmd.req_pos.left);
+ robotEstPosIndepOdo->setJaws(orte.jaws_cmd.req_pos.left);
+ robotEstPosOdo->setJaws(orte.jaws_cmd.req_pos.left);
+ break;
case QEVENT(QEV_REFERENCE_POSITION):
emit actualPositionReceivedSignal();
break;
estPosPhi->setText(QString("%1(%2)")
.arg(DEGREES(orte.est_pos_indep_odo.phi), 0, 'f', 0)
.arg(orte.est_pos_indep_odo.phi, 0, 'f', 1));
- robotEstPosIndepOdo->moveRobot(orte.est_pos_indep_odo.x,
+ robotEstPosIndepOdo->moveRobot(orte.est_pos_indep_odo.x,
orte.est_pos_indep_odo.y, orte.est_pos_indep_odo.phi);
- trailPosIndepOdo->addPoint(QPointF(orte.est_pos_indep_odo.x,
+ trailPosIndepOdo->addPoint(QPointF(orte.est_pos_indep_odo.x,
orte.est_pos_indep_odo.y));
break;
case QEVENT(QEV_ESTIMATED_POSITION_ODO):
- robotEstPosOdo->moveRobot(orte.est_pos_odo.x,
+ robotEstPosOdo->moveRobot(orte.est_pos_odo.x,
orte.est_pos_odo.y, orte.est_pos_odo.phi);
- trailOdoPos->addPoint(QPointF(orte.est_pos_odo.x,
+ trailOdoPos->addPoint(QPointF(orte.est_pos_odo.x,
orte.est_pos_odo.y));
break;
case QEVENT(QEV_ESTIMATED_POSITION_BEST):
- robotEstPosBest->moveRobot(orte.est_pos_best.x,
+ robotEstPosBest->moveRobot(orte.est_pos_best.x,
orte.est_pos_best.y, orte.est_pos_best.phi);
- trailEstPosBest->addPoint(QPointF(orte.est_pos_best.x,
+ trailEstPosBest->addPoint(QPointF(orte.est_pos_best.x,
orte.est_pos_best.y));
- hokuyoScan->setPosition(orte.est_pos_best.x,
+ hokuyoScan->setPosition(orte.est_pos_best.x,
orte.est_pos_best.y,
- orte.est_pos_best.phi);
+ orte.est_pos_best.phi);
break;
case QEVENT(QEV_POWER_VOLTAGE):
emit powerVoltageReceivedSignal();
{
int rv;
- orte.strength = 11;
-
+ memset(&orte, 0, sizeof(orte));
rv = robottype_roboorte_init(&orte);
if (rv) {
printf("RobomonAtlantis: Unable to initialize ORTE\n");
robottype_publisher_pwr_ctrl_create(&orte, dummy_publisher_callback, NULL);
robottype_publisher_robot_cmd_create(&orte, NULL, &orte);
+ robottype_publisher_robot_switches_create(&orte, dummy_publisher_callback, &orte);
/* subscribers */
- robottype_subscriber_pwr_voltage_create(&orte,
+ robottype_subscriber_pwr_voltage_create(&orte,
receivePowerVoltageCallBack, this);
- robottype_subscriber_motion_status_create(&orte,
+ robottype_subscriber_motion_status_create(&orte,
receiveMotionStatusCallBack, this);
- robottype_subscriber_ref_pos_create(&orte,
+ robottype_subscriber_ref_pos_create(&orte,
receiveActualPositionCallBack, this);
- robottype_subscriber_est_pos_odo_create(&orte,
+ robottype_subscriber_est_pos_odo_create(&orte,
generic_rcv_cb, new OrteCallbackInfo(this, QEV_ESTIMATED_POSITION_ODO));
- robottype_subscriber_est_pos_indep_odo_create(&orte,
+ robottype_subscriber_est_pos_indep_odo_create(&orte,
generic_rcv_cb, new OrteCallbackInfo(this, QEV_ESTIMATED_POSITION_INDEP_ODO));
- robottype_subscriber_est_pos_best_create(&orte,
+ robottype_subscriber_est_pos_best_create(&orte,
generic_rcv_cb, new OrteCallbackInfo(this, QEV_ESTIMATED_POSITION_BEST));
- robottype_subscriber_hokuyo_scan_create(&orte,
+ robottype_subscriber_hokuyo_scan_create(&orte,
generic_rcv_cb, new OrteCallbackInfo(this, QEV_HOKUYO_SCAN));
- robottype_subscriber_fsm_main_create(&orte,
+ robottype_subscriber_jaws_cmd_create(&orte,
+ generic_rcv_cb, new OrteCallbackInfo(this, QEV_JAWS_CMD));
+ robottype_subscriber_fsm_main_create(&orte,
rcv_fsm_main_cb, this);
- robottype_subscriber_fsm_motion_create(&orte,
+ robottype_subscriber_fsm_motion_create(&orte,
rcv_fsm_motion_cb, this);
- robottype_subscriber_fsm_act_create(&orte,
+ robottype_subscriber_fsm_act_create(&orte,
rcv_fsm_act_cb, this);
/* motors */
act_init(&orte);
/* set actions to do when we receive data from orte */
- connect(this, SIGNAL(motionStatusReceivedSignal()),
+ connect(this, SIGNAL(motionStatusReceivedSignal()),
this, SLOT(motionStatusReceived()));
- connect(this, SIGNAL(actualPositionReceivedSignal()),
+ connect(this, SIGNAL(actualPositionReceivedSignal()),
this, SLOT(actualPositionReceived()));
- connect(this, SIGNAL(powerVoltageReceivedSignal()),
+ connect(this, SIGNAL(powerVoltageReceivedSignal()),
this, SLOT(powerVoltageReceived()));
}
actPosPhi->setText(QString("%1(%2)")
.arg(DEGREES(orte.ref_pos.phi), 0, 'f', 0)
.arg(orte.ref_pos.phi, 0, 'f', 1));
- robotRefPos->moveRobot(orte.ref_pos.x,
+ robotRefPos->moveRobot(orte.ref_pos.x,
orte.ref_pos.y, orte.ref_pos.phi);
trailRefPos->addPoint(QPointF(orte.ref_pos.x, orte.ref_pos.y));
}
return;
sharedSegmentSize = sizeof(unsigned int) * MAP_WIDTH * MAP_HEIGHT;
-
+
/* Get segment identificator in a read only mode */
segmentId = shmget(SHM_MAP_KEY, sharedSegmentSize, S_IRUSR);
if(segmentId == -1) {
"Unable to open shared memory segment!");
return;
}
-
+
/* Init Shmap */
ShmapInit(0);
-
+
/* Attach the shared memory segment */
//map = (_Map*)shmat (segmentId, (void*) 0, 0);
struct map *map = ShmapIsMapInit();
if (!map) return min_distance;
-
+
// Simulate obstacles
for(j=0;j<MAP_HEIGHT;j++) {
for (i=0;i<MAP_WIDTH;i++) {
if( cell->flags & MAP_FLAG_SIMULATED_WALL) {
// WALL
ShmapCell2Point(i, j, &wall.x, &wall.y);
-
+
distance = distanceToObstacleHokuyo(beamnum, wall, MAP_CELL_SIZE_M);
if (distance<min_distance) min_distance = distance;
}
return min_distance;
}
-/**
+double RobomonAtlantis::distanceToCircularObstacleHokuyo(int beamnum, Point center, double diameter)
+{
+ struct robot_pos_type e = orte.est_pos_best;
+ double sensor_a;
+ struct sharp_pos s;
+
+ s.x = HOKUYO_CENTER_OFFSET_M;
+ s.y = 0.0;
+ s.ang = HOKUYO_INDEX_TO_RAD(beamnum);
+
+ Point sensor(e.x + s.x*cos(e.phi) - s.y*sin(e.phi),
+ e.y + s.x*sin(e.phi) + s.y*cos(e.phi));
+ sensor_a = e.phi + s.ang;
+
+ const double sensorRange = 4.0; /*[meters]*/
+
+ double distance = sensorRange;
+ double angle;
+
+ angle = sensor.angleTo(center) - sensor_a;
+ angle = fmod(angle, 2.0*M_PI);
+ if (angle > +M_PI) angle -= 2.0*M_PI;
+ if (angle < -M_PI) angle += 2.0*M_PI;
+ angle = fabs(angle);
+
+ double k = tan(sensor_a);
+ double r = diameter / 2.0;
+
+ double A = 1 + k*k;
+ double B = 2 * (sensor.y*k - center.x - k*k*sensor.x - center.y*k);
+ double C = center.x*center.x + center.y*center.y +
+ k*k*sensor.x*sensor.x - 2*sensor.y*k*sensor.x +
+ sensor.y*sensor.y + 2*k*sensor.x*center.y -
+ 2*sensor.y*center.y - r*r;
+
+ double D = B*B - 4*A*C;
+
+ if (D > 0) {
+ Point ob1, ob2;
+
+ ob1.x = (-B + sqrt(D)) / (2*A);
+ ob2.x = (-B - sqrt(D)) / (2*A);
+ ob1.y = k * (ob1.x - sensor.x) + sensor.y;
+ ob2.y = k * (ob2.x - sensor.x) + sensor.y;
+
+ double distance1 = sensor.distanceTo(ob1);
+ double distance2 = sensor.distanceTo(ob2);
+ distance = (distance1 < distance2) ? distance1 : distance2;
+ } else if (D == 0) {
+ Point ob;
+ ob.x = -B / (2*A);
+ ob.y = k * (ob.x - sensor.x) + sensor.y;
+ distance = sensor.distanceTo(ob);
+ }
+ distance = distance + (drand48()-0.5)*3.0e-2;
+ if (D < 0 || angle > atan(r / distance))
+ distance = sensorRange;
+ if (distance > sensorRange)
+ distance = sensorRange;
+
+ return distance;
+}
+
+/**
* Calculation for Hokuyo simulation. Calculates distance that would
* be returned by Hokuyo sensors, if there is only one obstacle (as
* specified by parameters).
* @param beamnum Hokuyo's bean number [0..HOKUYO_CLUSTER_CNT]
* @param obstacle Position of the obstacle (x, y in meters).
* @param obstacleSize Size (diameter) of the obstacle in meters.
- *
+ *
* @return Distance measured by sensors in meters.
- */
+ */
double RobomonAtlantis::distanceToObstacleHokuyo(int beamnum, Point obstacle, double obstacleSize)
-{
+{
struct robot_pos_type e = orte.est_pos_best;
double sensor_a;
struct sharp_pos s;
Point sensor(e.x + s.x*cos(e.phi) - s.y*sin(e.phi),
e.y + s.x*sin(e.phi) + s.y*cos(e.phi));
sensor_a = e.phi + s.ang;
-
+
const double sensorRange = 4.0; /*[meters]*/
-
+
double distance, angle;
-
+
angle = sensor.angleTo(obstacle) - sensor_a;
angle = fmod(angle, 2.0*M_PI);
if (angle > +M_PI) angle -= 2.0*M_PI;
if (angle < M_PI/2.0) {
distance = distance/cos(angle);
}
- if (distance > sensorRange)
+ if (distance > sensorRange)
distance = sensorRange;
} else {
distance = sensorRange;
void RobomonAtlantis::sendStart(int plug)
{
- orte.robot_cmd.start = plug ? 0 : 1;
+ orte.robot_cmd.start_condition = plug ? 0 : 1;
ORTEPublicationSend(orte.publication_robot_cmd);
}
+void RobomonAtlantis::setTeamColor(int plug)
+{
+ orte.robot_switches.team_color = plug ? 1 : 0;
+ ORTEPublicationSend(orte.publication_robot_switches);
+}
+
void RobomonAtlantis::resetTrails()
{
trailRefPos->reset();
trailPosIndepOdo->setVisible(show && robotEstPosIndepOdo->isVisible());
trailOdoPos->setVisible(show && robotEstPosOdo->isVisible());
}
+
+void RobomonAtlantis::showShapeDetect(bool show)
+{
+ hokuyoScan->showShapeDetect = show;
+}