int main(int argc, char *argv[])
{
// Initialize location of Aria, Arnl and their args.
Aria::init();
Arnl::init();
// The robot object
ArRobot robot;
// Parse the command line arguments.
ArArgumentParser parser(&argc, argv);
// Read data_index if exists
int data_index;
bool exist_data_index;
parser.checkParameterArgumentInteger("dataIndex",&data_index,&exist_data_index);
// Load default arguments for this computer (from /etc/Aria.args, environment
// variables, and other places)
parser.loadDefaultArguments();
// Object that connects to the robot or simulator using program options
ArRobotConnector robotConnector(&parser, &robot);
// set up a gyro
ArAnalogGyro gyro(&robot);
ArLog::init(ArLog::File,ArLog::Normal,"run.log",false,true,true);
// Parse arguments for the simple connector.
if (!Aria::parseArgs() || !parser.checkHelpAndWarnUnparsed())
{
ArLog::log(ArLog::Normal, "\nUsage: %s -map mapfilename\n", argv[0]);
Aria::logOptions();
Aria::exit(1);
}
// Collision avoidance actions at higher priority
ArActionAvoidFront avoidAction("avoid",200);
ArActionLimiterForwards limiterAction("speed limiter near", 150, 500, 150);
ArActionLimiterForwards limiterFarAction("speed limiter far", 300, 1100, 400);
ArActionLimiterTableSensor tableLimiterAction;
//robot.addAction(&tableLimiterAction, 100);
//robot.addAction(&avoidAction,100);
//robot.addAction(&limiterAction, 95);
//robot.addAction(&limiterFarAction, 90);
// Goto action at lower priority
ArActionGoto gotoPoseAction("goto");
//robot.addAction(&gotoPoseAction, 50);
gotoPoseAction.setCloseDist(750);
// Stop action at lower priority, so the robot stops if it has no goal
ArActionStop stopAction("stop");
//robot.addAction(&stopAction, 40);
// Connect the robot
if (!robotConnector.connectRobot())
{
ArLog::log(ArLog::Normal, "Could not connect to robot... exiting");
Aria::exit(3);
}
if(!robot.isConnected())
{
ArLog::log(ArLog::Terse, "Internal error: robot connector succeeded but ArRobot::isConnected() is false!");
}
// Connector for laser rangefinders
ArLaserConnector laserConnector(&parser, &robot, &robotConnector);
// Sonar, must be added to the robot, used by teleoperation and wander to
// detect obstacles, and for localization if SONARNL
ArSonarDevice sonarDev;
// Add the sonar to the robot
robot.addRangeDevice(&sonarDev);
// Start the robot thread.
robot.runAsync(true);
// Connect to the laser(s) if lasers were configured in this robot's parameter
// file or on the command line, and run laser processing thread if applicable
// for that laser class. For the purposes of this demo, add all
// possible lasers to ArRobot's list rather than just the ones that were
// connected by this call so when you enter laser mode, you
// can then interactively choose which laser to use from that list of all
// lasers mentioned in robot parameters and on command line. Normally,
// only connected lasers are put in ArRobot's list.
if (!laserConnector.connectLasers(
false, // continue after connection failures
true, // add only connected lasers to ArRobot
true // add all lasers to ArRobot
))
{
ArLog::log(ArLog::Normal ,"Could not connect to lasers... exiting\n");
Aria::exit(2);
}
// Puntero a laser
ArSick* sick=(ArSick*)robot.findLaser(1);
// Conectamos el laser
sick->asyncConnect();
//Esperamos a que esté encendido
while(!sick->isConnected())
{
ArUtil::sleep(100);
}
ArLog::log(ArLog::Normal ,"Laser conectado\n");
// Set up things so data can be logged (only do it with the laser
// since it can overrun a 9600 serial connection which the sonar is
// more likely to have)
ArDataLogger dataLogger(&robot);
dataLogger.addToConfig(Aria::getConfig());
// add our logging to the config
//ArLog::addToConfig(Aria::getConfig());
// Set up a class that'll put the movement and gyro parameters into ArConfig
ArRobotConfig robotConfig(&robot);
robotConfig.addAnalogGyro(&gyro);
// Add additional range devices to the robot and path planning task.
// IRs if the robot has them.
robot.lock();
ArIRs irs;
robot.addRangeDevice(&irs);
// Bumpers.
ArBumpers bumpers;
robot.addRangeDevice(&bumpers);
// cause the sonar to turn off automatically
// when the robot is stopped, and turn it back on when commands to move
// are sent. (Note, this should not be done if you need the sonar
// data to localize, or for other purposes while stopped)
ArSonarAutoDisabler sonarAutoDisabler(&robot);
// Read in parameter files.
Aria::getConfig()->useArgumentParser(&parser);
if (!Aria::getConfig()->parseFile(Arnl::getTypicalParamFileName()))
{
ArLog::log(ArLog::Normal, "Trouble loading configuration file, exiting");
Aria::exit(5);
}
//Configuracion del laser
sick->setMinDistBetweenCurrent(0);
robot.enableMotors();
robot.setAbsoluteMaxTransVel(1000);
/* Finally, get ready to run the robot: */
robot.unlock();
Controlador driver(&robot);
if(exist_data_index){
driver.setDataIndex(data_index);
}
driver.runAsync();
ControlHandler handler(&driver,&robot);
// Use manual key handler
//handler.addKeyHandlers(&robot);
robot.addSensorInterpTask("ManualKeyHandler",50,handler.getFunctor());
ArLog::log(ArLog::Normal ,"Añadido manejador teclado\n");
// double x,y,dist,angle;
// ArPose punto;
// ArPose origen=robot.getPose();
// sick->lockDevice();
// for(int i=-90;i<90;i++){
// // Obtengo la medida de distancia y angulo
// dist=sick->currentReadingPolar(i,i+1,&angle);
// // Obtengo coordenadas del punto usando el laser como referencia
// x=dist*ArMath::cos(angle);
// y=dist*ArMath::sin(angle);
// //Roto los puntos
// ArMath::pointRotate(&x,&y,-origen.getTh());
// punto.setX(x);
// punto.setY(y);
// punto=punto + origen;
// printf("Medida: %d\t Angulo:%.2f\t Angulo:%.2f\t Distancia:%0.2f\t X:%0.2f\t Y:%0.2f\n",i,angle,angle+origen.getTh(),dist,punto.getX(),punto.getY());
// }
// printf("Medidas adquiridas\n");
// sick->unlockDevice();
robot.waitForRunExit();
//ArUtil::sleep(10000);
return 0;
}
int main(void)
{
ArSerialConnection con;
ArRobot robot;
int ret;
std::string str;
ArActionLimiterForwards limiter("speed limiter near", 300, 600, 250);
ArActionLimiterForwards limiterFar("speed limiter far", 300, 1100, 400);
ArActionLimiterBackwards backwardsLimiter;
ArActionConstantVelocity stop("stop", 0);
ArActionConstantVelocity backup("backup", -200);
ArSonarDevice sonar;
ArACTS_1_2 acts;
ArGripper gripper(&robot);
ArSonyPTZ sony(&robot);
Acquire acq(&acts);
DriveTo driveTo(&acts, &gripper, &sony);
PickUp pickUp(&acts, &gripper, &sony);
TakeBlockToWall takeBlock(&robot, &gripper, &sony, &acq, &driveTo, &pickUp,
&backup);
Aria::init();
acts.openPort(&robot);
robot.addRangeDevice(&sonar);
if ((ret = con.open()) != 0)
{
str = con.getOpenMessage(ret);
printf("Open failed: %s\n", str.c_str());
Aria::shutdown();
return 1;
}
robot.setDeviceConnection(&con);
if (!robot.blockingConnect())
{
printf("Could not connect to robot... exiting\n");
Aria::shutdown();
return 1;
}
sony.init();
ArUtil::sleep(1000);
robot.setAbsoluteMaxTransVel(400);
robot.comInt(ArCommands::ENABLE, 1);
robot.comInt(ArCommands::SOUNDTOG, 0);
ArUtil::sleep(200);
robot.addAction(&limiter, 100);
robot.addAction(&limiterFar, 99);
robot.addAction(&backwardsLimiter, 98);
robot.addAction(&acq, 77);
robot.addAction(&driveTo, 76);
robot.addAction(&pickUp, 75);
robot.addAction(&backup, 50);
robot.addAction(&stop, 30);
robot.run(true);
Aria::shutdown();
return 0;
}
int main(void)
{
ArSerialConnection con;
ArRobot robot;
int ret;
std::string str;
ArActionLimiterForwards limiter("speed limiter near", 225, 600, 250);
ArActionLimiterForwards limiterFar("speed limiter far", 225, 1100, 400);
ArActionTableSensorLimiter tableLimiter;
ArActionLimiterBackwards backwardsLimiter;
ArActionConstantVelocity stop("stop", 0);
ArSonarDevice sonar;
ArACTS_1_2 acts;
ArPTZ *ptz;
ptz = new ArVCC4(&robot, true);
ArGripper gripper(&robot);
Acquire acq(&acts, &gripper);
DriveTo driveTo(&acts, &gripper, ptz);
DropOff dropOff(&acts, &gripper, ptz);
PickUp pickUp(&acts, &gripper, ptz);
TakeBlockToWall takeBlock(&robot, &gripper, ptz, &acq, &driveTo, &pickUp,
&dropOff, &tableLimiter);
if (!acts.openPort(&robot))
{
printf("Could not connect to acts, exiting\n");
exit(0);
}
Aria::init();
robot.addRangeDevice(&sonar);
//con.setBaud(38400);
if ((ret = con.open()) != 0)
{
str = con.getOpenMessage(ret);
printf("Open failed: %s\n", str.c_str());
Aria::shutdown();
return 1;
}
robot.setDeviceConnection(&con);
if (!robot.blockingConnect())
{
printf("Could not connect to robot... exiting\n");
Aria::shutdown();
return 1;
}
ptz->init();
ArUtil::sleep(8000);
printf("### 2222\n");
ptz->panTilt(0, -40);
printf("### whee\n");
ArUtil::sleep(8000);
robot.setAbsoluteMaxTransVel(400);
robot.setStateReflectionRefreshTime(250);
robot.comInt(ArCommands::ENABLE, 1);
robot.comInt(ArCommands::SOUNDTOG, 0);
ArUtil::sleep(200);
robot.addAction(&tableLimiter, 100);
robot.addAction(&limiter, 99);
robot.addAction(&limiterFar, 98);
robot.addAction(&backwardsLimiter, 97);
robot.addAction(&acq, 77);
robot.addAction(&driveTo, 76);
robot.addAction(&pickUp, 75);
robot.addAction(&dropOff, 74);
robot.addAction(&stop, 30);
robot.run(true);
Aria::shutdown();
return 0;
}
int main(int argc, char **argv)
{
Aria::init();
ArArgumentParser parser(&argc, argv);
parser.loadDefaultArguments();
ArRobot robot;
ArRobotConnector robotConnector(&parser, &robot);
if(!robotConnector.connectRobot())
{
ArLog::log(ArLog::Terse, "teleopActionsExample: Could not connect to the robot.");
if(parser.checkHelpAndWarnUnparsed())
{
Aria::logOptions();
Aria::exit(1);
}
}
if (!Aria::parseArgs() || !parser.checkHelpAndWarnUnparsed())
{
Aria::logOptions();
Aria::exit(1);
}
ArLog::log(ArLog::Normal, "teleopActionsExample: Connected.");
// limiter for close obstacles
ArActionLimiterForwards limiter("speed limiter near", 300, 600, 250);
// limiter for far away obstacles
ArActionLimiterForwards limiterFar("speed limiter far", 300, 1100, 400);
// limiter that checks IR sensors (like Peoplebot has)
ArActionLimiterTableSensor tableLimiter;
// limiter so we don't bump things backwards
ArActionLimiterBackwards backwardsLimiter;
// the joydrive action
ArActionJoydrive joydriveAct;
// the keydrive action
ArActionKeydrive keydriveAct;
// sonar device, used by the limiter actions.
ArSonarDevice sonar;
printf("This program will allow you to use a joystick or keyboard to control the robot.\nYou can use the arrow keys to drive, and the spacebar to stop.\nFor joystick control press the trigger button and then drive.\nPress escape to exit.\n");
// if we don't have a joystick, let 'em know
if (!joydriveAct.joystickInited())
printf("Do not have a joystick, only the arrow keys on the keyboard will work.\n");
// add the sonar to the robot
robot.addRangeDevice(&sonar);
// set the robots maximum velocity (sonar don't work at all well if you're
// going faster)
robot.setAbsoluteMaxTransVel(400);
// enable the motor
robot.enableMotors();
// Add the actions, with the limiters as highest priority, then the teleop.
// actions. This will keep the teleop. actions from being able to drive too
// fast and hit something
robot.addAction(&tableLimiter, 100);
robot.addAction(&limiter, 95);
robot.addAction(&limiterFar, 90);
robot.addAction(&backwardsLimiter, 85);
robot.addAction(&joydriveAct, 50);
robot.addAction(&keydriveAct, 45);
// Configure the joydrive action so it will let the lower priority actions
// (i.e. keydriveAct) request motion if the joystick button is
// not pressed.
joydriveAct.setStopIfNoButtonPressed(false);
// run the robot, true means that the run will exit if connection lost
robot.run(true);
Aria::exit(0);
}
