void laserRequest_and_odom(ArServerClient *client, ArNetPacket *packet)
{
robot.lock();
ArNetPacket sending;
sending.empty();
ArLaser* laser = robot.findLaser(1);
if(!laser){
printf("Could not connect to Laser... exiting\n");
Aria::exit(1);}
laser->lockDevice();
const std::list<ArSensorReading*> *sensorReadings = laser->getRawReadings(); // see ArRangeDevice interface doc
sending.byte4ToBuf((ArTypes::Byte4)(sensorReadings->size()));
for (std::list<ArSensorReading*>::const_iterator it2= sensorReadings->begin(); it2 != sensorReadings->end(); ++it2){
ArSensorReading* laserRead =*it2;
sending.byte4ToBuf((ArTypes::Byte4)(laserRead->getRange()));
//printf("%i,%i:",laserRead->getRange(),laserRead->getIgnoreThisReading());
}
sending.byte4ToBuf((ArTypes::Byte4)(robot.getX()));
sending.byte4ToBuf((ArTypes::Byte4)(robot.getY()));
sending.byte4ToBuf((ArTypes::Byte4)(robot.getTh()));
sending.byte4ToBuf((ArTypes::Byte4)(robot.getVel()));
sending.byte4ToBuf((ArTypes::Byte4)(robot.getRotVel()));
//printf("%1f,%1f,%1f\n",robot.getX(),robot.getY(),robot.getTh());
laser->unlockDevice();
robot.unlock();
sending.finalizePacket();
//sending.printHex();
client->sendPacketTcp(&sending);
}
void manualControlHandler(){
if(firstCall){
firstCall=false;
showMenu();
}
if(keyPressedBefore && !driver->estaEjecutando()){
keyPressedBefore=false;
showMenu();
}
if(mrpt::system::os::kbhit() ){
char c = mrpt::system::os::getch();
keyPressedBefore=true;
switch(c){
case '\033':
c=mrpt::system::os::getch(); // skip the [
cout << "Siguiente caracter" << (int)c << endl;
double v;
switch(mrpt::system::os::getch()) { // the real value
case 'A':
// code for arrow up
v=robot->getVel();
robot->setVel(v+50);
break;
case 'B':
// code for arrow down
v=robot->getVel();
robot->setVel(v-50);
break;
case 'C':
// code for arrow right
v=robot->getRotVel();
robot->setRotVel(v-5);
break;
case 'D':
// code for arrow left
v=robot->getRotVel();
robot->setRotVel(v+5);
break;
}
break;
case ' ':
robot->stop();
break;
case 'x':
//Aria::shutdown();
driver->stopRunning();
robot->stopRunning();
break;
case 'c':
guardarContinuo();
break;
case 'p':
start();
break;
case 'g':
guardar();
break;
case 'w':
guardarTrayectoria();
break;
case 't':
testParado();
break;
case 's':
stop();
break;
}
}
}
int main(int argc, char **argv)
{
Aria::init();
ArRobot robot;
ArArgumentParser parser(&argc, argv);
parser.loadDefaultArguments();
ArLog::log(ArLog::Terse, "WARNING: this program does no sensing or avoiding of obstacles, the robot WILL collide with any objects in the way! Make sure the robot has approximately 3 meters of free space on all sides.");
// ArRobotConnector connects to the robot, get some initial data from it such as type and name,
// and then loads parameter files for this robot.
ArRobotConnector robotConnector(&parser, &robot);
if(!robotConnector.connectRobot())
{
ArLog::log(ArLog::Terse, "simpleMotionCommands: Could not connect to the robot.");
if(parser.checkHelpAndWarnUnparsed())
{
Aria::logOptions();
Aria::exit(1);
return 1;
}
}
if (!Aria::parseArgs())
{
Aria::logOptions();
Aria::exit(1);
return 1;
}
ArLog::log(ArLog::Normal, "simpleMotionCommands: Connected.");
// Start the robot processing cycle running in the background.
// True parameter means that if the connection is lost, then the
// run loop ends.
robot.runAsync(true);
// Print out some data from the SIP.
// We must "lock" the ArRobot object
// before calling its methods, and "unlock" when done, to prevent conflicts
// with the background thread started by the call to robot.runAsync() above.
// See the section on threading in the manual for more about this.
// Make sure you unlock before any sleep() call or any other code that will
// take some time; if the robot remains locked during that time, then
// ArRobot's background thread will be blocked and unable to communicate with
// the robot, call tasks, etc.
robot.lock();
ArLog::log(ArLog::Normal, "simpleMotionCommands: Pose=(%.2f,%.2f,%.2f), Trans. Vel=%.2f, Rot. Vel=%.2f, Battery=%.2fV",
robot.getX(), robot.getY(), robot.getTh(), robot.getVel(), robot.getRotVel(), robot.getBatteryVoltage());
robot.unlock();
// Sleep for 3 seconds.
ArLog::log(ArLog::Normal, "simpleMotionCommands: Will start driving in 3 seconds...");
ArUtil::sleep(3000);
// Set forward velocity to 50 mm/s
ArLog::log(ArLog::Normal, "simpleMotionCommands: Driving forward at 250 mm/s for 5 sec...");
robot.lock();
robot.enableMotors();
robot.setVel(250);
robot.unlock();
ArUtil::sleep(5000);
ArLog::log(ArLog::Normal, "simpleMotionCommands: Stopping.");
robot.lock();
robot.stop();
robot.unlock();
ArUtil::sleep(1000);
ArLog::log(ArLog::Normal, "simpleMotionCommands: Rotating at 10 deg/s for 5 sec...");
robot.lock();
robot.setRotVel(10);
robot.unlock();
ArUtil::sleep(5000);
ArLog::log(ArLog::Normal, "simpleMotionCommands: Rotating at -10 deg/s for 10 sec...");
robot.lock();
robot.setRotVel(-10);
robot.unlock();
ArUtil::sleep(10000);
ArLog::log(ArLog::Normal, "simpleMotionCommands: Driving forward at 150 mm/s for 5 sec...");
robot.lock();
robot.setRotVel(0);
robot.setVel(150);
robot.unlock();
ArUtil::sleep(5000);
ArLog::log(ArLog::Normal, "simpleMotionCommands: Stopping.");
robot.lock();
robot.stop();
robot.unlock();
ArUtil::sleep(1000);
// Other motion command functions include move(), setHeading(),
// setDeltaHeading(). You can also adjust acceleration and deceleration
// values used by the robot with setAccel(), setDecel(), setRotAccel(),
// setRotDecel(). See the ArRobot class documentation for more.
robot.lock();
ArLog::log(ArLog::Normal, "simpleMotionCommands: Pose=(%.2f,%.2f,%.2f), Trans. Vel=%.2f, Rot. Vel=%.2f, Battery=%.2fV",
robot.getX(), robot.getY(), robot.getTh(), robot.getVel(), robot.getRotVel(), robot.getBatteryVoltage());
robot.unlock();
ArLog::log(ArLog::Normal, "simpleMotionCommands: Ending robot thread...");
robot.stopRunning();
// wait for the thread to stop
robot.waitForRunExit();
// exit
ArLog::log(ArLog::Normal, "simpleMotionCommands: Exiting.");
Aria::exit(0);
return 0;
}
void RosAriaNode::publish()
{
// Note, this is called via SensorInterpTask callback (myPublishCB, named "ROSPublishingTask"). ArRobot object 'robot' sholud not be locked or unlocked.
pos = robot->getPose();
tf::poseTFToMsg(tf::Transform(tf::createQuaternionFromYaw(pos.getTh()*M_PI/180), tf::Vector3(pos.getX()/1000,
pos.getY()/1000, 0)), position.pose.pose); //Aria returns pose in mm.
position.twist.twist.linear.x = robot->getVel()/1000; //Aria returns velocity in mm/s.
position.twist.twist.linear.y = robot->getLatVel()/1000.0;
position.twist.twist.angular.z = robot->getRotVel()*M_PI/180;
position.header.frame_id = frame_id_odom;
position.child_frame_id = frame_id_base_link;
position.header.stamp = ros::Time::now();
pose_pub.publish(position);
ROS_DEBUG("RosAria: publish: (time %f) pose x: %f, y: %f, angle: %f; linear vel x: %f, y: %f; angular vel z: %f",
position.header.stamp.toSec(),
(double)position.pose.pose.position.x,
(double)position.pose.pose.position.y,
(double)position.pose.pose.orientation.w,
(double) position.twist.twist.linear.x,
(double) position.twist.twist.linear.y,
(double) position.twist.twist.angular.z
);
// publishing transform odom->base_link
odom_trans.header.stamp = ros::Time::now();
odom_trans.header.frame_id = frame_id_odom;
odom_trans.child_frame_id = frame_id_base_link;
odom_trans.transform.translation.x = pos.getX()/1000;
odom_trans.transform.translation.y = pos.getY()/1000;
odom_trans.transform.translation.z = 0.0;
odom_trans.transform.rotation = tf::createQuaternionMsgFromYaw(pos.getTh()*M_PI/180);
odom_broadcaster.sendTransform(odom_trans);
// getStallValue returns 2 bytes with stall bit and bumper bits, packed as (00 00 FrontBumpers RearBumpers)
int stall = robot->getStallValue();
unsigned char front_bumpers = (unsigned char)(stall >> 8);
unsigned char rear_bumpers = (unsigned char)(stall);
bumpers.header.frame_id = frame_id_bumper;
bumpers.header.stamp = ros::Time::now();
std::stringstream bumper_info(std::stringstream::out);
// Bit 0 is for stall, next bits are for bumpers (leftmost is LSB)
for (unsigned int i=0; i<robot->getNumFrontBumpers(); i++)
{
bumpers.front_bumpers[i] = (front_bumpers & (1 << (i+1))) == 0 ? 0 : 1;
bumper_info << " " << (front_bumpers & (1 << (i+1)));
}
ROS_DEBUG("RosAria: Front bumpers:%s", bumper_info.str().c_str());
bumper_info.str("");
// Rear bumpers have reverse order (rightmost is LSB)
unsigned int numRearBumpers = robot->getNumRearBumpers();
for (unsigned int i=0; i<numRearBumpers; i++)
{
bumpers.rear_bumpers[i] = (rear_bumpers & (1 << (numRearBumpers-i))) == 0 ? 0 : 1;
bumper_info << " " << (rear_bumpers & (1 << (numRearBumpers-i)));
}
ROS_DEBUG("RosAria: Rear bumpers:%s", bumper_info.str().c_str());
bumpers_pub.publish(bumpers);
//Publish battery information
// TODO: Decide if BatteryVoltageNow (normalized to (0,12)V) is a better option
std_msgs::Float64 batteryVoltage;
batteryVoltage.data = robot->getRealBatteryVoltageNow();
voltage_pub.publish(batteryVoltage);
if(robot->haveStateOfCharge())
{
std_msgs::Float32 soc;
soc.data = robot->getStateOfCharge()/100.0;
state_of_charge_pub.publish(soc);
}
// publish recharge state if changed
char s = robot->getChargeState();
if(s != recharge_state.data)
{
ROS_INFO("RosAria: publishing new recharge state %d.", s);
recharge_state.data = s;
recharge_state_pub.publish(recharge_state);
}
// publish motors state if changed
bool e = robot->areMotorsEnabled();
if(e != motors_state.data || !published_motors_state)
{
ROS_INFO("RosAria: publishing new motors state %d.", e);
motors_state.data = e;
motors_state_pub.publish(motors_state);
published_motors_state = true;
}
// Publish sonar information, if enabled.
if (use_sonar) {
sensor_msgs::PointCloud cloud; //sonar readings.
cloud.header.stamp = position.header.stamp; //copy time.
// sonar sensors relative to base_link
cloud.header.frame_id = frame_id_sonar;
// Log debugging info
std::stringstream sonar_debug_info;
sonar_debug_info << "Sonar readings: ";
for (int i = 0; i < robot->getNumSonar(); i++) {
ArSensorReading* reading = NULL;
reading = robot->getSonarReading(i);
if(!reading) {
ROS_WARN("RosAria: Did not receive a sonar reading.");
continue;
}
// getRange() will return an integer between 0 and 5000 (5m)
sonar_debug_info << reading->getRange() << " ";
// local (x,y). Appears to be from the centre of the robot, since values may
// exceed 5000. This is good, since it means we only need 1 transform.
// x & y seem to be swapped though, i.e. if the robot is driving north
// x is north/south and y is east/west.
//
//ArPose sensor = reading->getSensorPosition(); //position of sensor.
// sonar_debug_info << "(" << reading->getLocalX()
// << ", " << reading->getLocalY()
// << ") from (" << sensor.getX() << ", "
// << sensor.getY() << ") ;; " ;
//add sonar readings (robot-local coordinate frame) to cloud
geometry_msgs::Point32 p;
p.x = reading->getLocalX() / 1000.0;
p.y = reading->getLocalY() / 1000.0;
p.z = 0.0;
cloud.points.push_back(p);
}
ROS_DEBUG_STREAM(sonar_debug_info.str());
sonar_pub.publish(cloud);
}
}
int main(int argc, char **argv)
{
std::string str;
int ret;
ArTime start;
// connection to the robot
ArSerialConnection con;
// the robot
ArRobot robot;
// the connection handler from above
ConnHandler ch(&robot);
// init area with a dedicated signal handling thread
Aria::init(Aria::SIGHANDLE_THREAD);
// open the connection with the defaults, exit if failed
if ((ret = con.open()) != 0)
{
str = con.getOpenMessage(ret);
printf("Open failed: %s\n", str.c_str());
Aria::shutdown();
return 1;
}
// set the robots connection
robot.setDeviceConnection(&con);
// try to connect, if we fail, the connection handler should bail
if (!robot.blockingConnect())
{
// this should have been taken care of by the connection handler
// but just in case
printf(
"asyncConnect failed because robot is not running in its own thread.\n");
Aria::shutdown();
return 1;
}
// run the robot in its own thread, so it gets and processes packets and such
robot.runAsync(false);
// just a big long set of printfs, direct motion commands and sleeps,
// it should be self-explanatory
printf("Telling the robot to go 300 mm for 5 seconds\n");
robot.lock();
robot.setVel(500);
robot.unlock();
start.setToNow();
while (1)
{
robot.lock();
if (start.mSecSince() > 5000)
{
robot.unlock();
break;
}
printf("Trans: %10g Rot: %10g\n", robot.getVel(), robot.getRotVel());
robot.unlock();
ArUtil::sleep(100);
}
printf("Telling the robot to turn at 50 deg/sec for 10 seconds\n");
robot.lock();
robot.setVel(0);
robot.setRotVel(50);
robot.unlock();
start.setToNow();
while (1)
{
robot.lock();
if (start.mSecSince() > 10000)
{
robot.unlock();
break;
}
printf("Trans: %10g Rot: %10g\n", robot.getVel(), robot.getRotVel());
robot.unlock();
ArUtil::sleep(100);
}
printf("Telling the robot to turn at 100 deg/sec for 10 seconds\n");
robot.lock();
robot.setVel(0);
robot.setRotVel(100);
robot.unlock();
start.setToNow();
while (1)
{
robot.lock();
if (start.mSecSince() > 10000)
{
robot.unlock();
break;
}
printf("Trans: %10g Rot: %10g\n", robot.getVel(), robot.getRotVel());
robot.unlock();
ArUtil::sleep(100);
}
printf("Done with tests, exiting\n");
robot.disconnect();
// shutdown and ge tout
Aria::shutdown();
return 0;
}
void RosAriaNode::publish()
{
// Note, this is called via SensorInterpTask callback (myPublishCB, named "ROSPublishingTask"). ArRobot object 'robot' sholud not be locked or unlocked.
pos = robot->getPose();
tf::poseTFToMsg(tf::Transform(tf::createQuaternionFromYaw(pos.getTh()*M_PI/180), tf::Vector3(pos.getX()/1000,
pos.getY()/1000, 0)), position.pose.pose); //Aria returns pose in mm.
position.twist.twist.linear.x = robot->getVel()/1000; //Aria returns velocity in mm/s.
position.twist.twist.angular.z = robot->getRotVel()*M_PI/180;
position.header.frame_id = frame_id_odom;
position.child_frame_id = frame_id_base_link;
position.header.stamp = ros::Time::now();
pose_pub.publish(position);
ROS_DEBUG("RosAria: publish: (time %f) pose x: %f, y: %f, angle: %f; linear vel x: %f, y: %f; angular vel z: %f",
position.header.stamp.toSec(),
(double)position.pose.pose.position.x,
(double)position.pose.pose.position.y,
(double)position.pose.pose.orientation.w,
(double) position.twist.twist.linear.x,
(double) position.twist.twist.linear.y,
(double) position.twist.twist.angular.z
);
// publishing transform odom->base_link
odom_trans.header.stamp = ros::Time::now();
odom_trans.header.frame_id = frame_id_odom;
odom_trans.child_frame_id = frame_id_base_link;
odom_trans.transform.translation.x = pos.getX()/1000;
odom_trans.transform.translation.y = pos.getY()/1000;
odom_trans.transform.translation.z = 0.0;
odom_trans.transform.rotation = tf::createQuaternionMsgFromYaw(pos.getTh()*M_PI/180);
odom_broadcaster.sendTransform(odom_trans);
// getStallValue returns 2 bytes with stall bit and bumper bits, packed as (00 00 FrontBumpers RearBumpers)
int stall = robot->getStallValue();
unsigned char front_bumpers = (unsigned char)(stall >> 8);
unsigned char rear_bumpers = (unsigned char)(stall);
bumpers.header.frame_id = frame_id_bumper;
bumpers.header.stamp = ros::Time::now();
std::stringstream bumper_info(std::stringstream::out);
// Bit 0 is for stall, next bits are for bumpers (leftmost is LSB)
for (unsigned int i=0; i<robot->getNumFrontBumpers(); i++)
{
bumpers.front_bumpers[i] = (front_bumpers & (1 << (i+1))) == 0 ? 0 : 1;
bumper_info << " " << (front_bumpers & (1 << (i+1)));
}
ROS_DEBUG("RosAria: Front bumpers:%s", bumper_info.str().c_str());
bumper_info.str("");
// Rear bumpers have reverse order (rightmost is LSB)
unsigned int numRearBumpers = robot->getNumRearBumpers();
for (unsigned int i=0; i<numRearBumpers; i++)
{
bumpers.rear_bumpers[i] = (rear_bumpers & (1 << (numRearBumpers-i))) == 0 ? 0 : 1;
bumper_info << " " << (rear_bumpers & (1 << (numRearBumpers-i)));
}
ROS_DEBUG("RosAria: Rear bumpers:%s", bumper_info.str().c_str());
bumpers_pub.publish(bumpers);
//Publish battery information
// TODO: Decide if BatteryVoltageNow (normalized to (0,12)V) is a better option
std_msgs::Float64 batteryVoltage;
batteryVoltage.data = robot->getRealBatteryVoltageNow();
voltage_pub.publish(batteryVoltage);
if(robot->haveStateOfCharge())
{
std_msgs::Float32 soc;
soc.data = robot->getStateOfCharge()/100.0;
state_of_charge_pub.publish(soc);
}
// publish recharge state if changed
char s = robot->getChargeState();
if(s != recharge_state.data)
{
ROS_INFO("RosAria: publishing new recharge state %d.", s);
recharge_state.data = s;
recharge_state_pub.publish(recharge_state);
}
// publish motors state if changed
bool e = robot->areMotorsEnabled();
if(e != motors_state.data || !published_motors_state)
{
ROS_INFO("RosAria: publishing new motors state %d.", e);
motors_state.data = e;
motors_state_pub.publish(motors_state);
published_motors_state = true;
}
if (robot->areSonarsEnabled())
{
int i = 0;
int j = 0;
ArSensorReading* reading = NULL;
if(sonars__crossed_the_streams)
{
i = 8;
j = 8;
}
for(; i < 16; i++)
{
ranges.data[i].header.stamp = ros::Time::now();
ArSensorReading* _reading = NULL;
_reading = robot->getSonarReading(i-j);
ranges.data[i].range = _reading->getRange() / 1000.0f;
range_pub[i].publish(ranges.data[i]);
}
ranges.header.stamp = ros::Time::now();
combined_range_pub.publish(ranges);
}
}
