void readSonars(ArRobot& robot, int numSonar){
char angle[64], value[64];
G_id += 1;
ArSensorReading* sonarReading;
string res;
sprintf(value,"id=%d;",G_id);
res += value;
for (int i=0; i < numSonar; i++){
sonarReading = robot.getSonarReading(i);
sprintf(value,"v%d=%05d;", i, sonarReading->getRange());
res += value;
//cout << "Sonar reading " << i << " = " << sonarReading->getRange() << " Angle " << i << " = " << sonarReading->getSensorTh() << "\n";
}
res += "\n";
fseek(G_SONAR_FD, SEEK_SET, 0);
fwrite(res.c_str(), sizeof(char), res.size(), G_SONAR_FD);
}
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);
}
}
void Joydrive::drive(void)
{
int trans, rot;
ArPose pose;
ArPose rpose;
ArTransform transform;
ArRangeDevice *dev;
ArSensorReading *son;
if (!myRobot->isConnected())
{
printf("Lost connection to the robot, exiting\n");
exit(0);
}
printf("\rx %6.1f y %6.1f th %6.1f",
myRobot->getX(), myRobot->getY(), myRobot->getTh());
fflush(stdout);
if (myJoyHandler.haveJoystick() && myJoyHandler.getButton(1))
{
if (ArMath::fabs(myRobot->getVel()) < 10.0)
myRobot->comInt(ArCommands::ENABLE, 1);
myJoyHandler.getAdjusted(&rot, &trans);
myRobot->setVel(trans);
myRobot->setRotVel(-rot);
}
else
{
myRobot->setVel(0);
myRobot->setRotVel(0);
}
if (myJoyHandler.haveJoystick() && myJoyHandler.getButton(2) &&
time(NULL) - myLastPress > 1)
{
myLastPress = time(NULL);
printf("\n");
switch (myTest)
{
case 1:
printf("Moving back to the origin.\n");
pose.setPose(0, 0, 0);
myRobot->moveTo(pose);
break;
case 2:
printf("Moving over a meter.\n");
pose.setPose(myRobot->getX() + 1000, myRobot->getY(), 0);
myRobot->moveTo(pose);
break;
case 3:
printf("Doing a transform test....\n");
printf("\nOrigin should be transformed to the robots coords.\n");
transform = myRobot->getToGlobalTransform();
pose.setPose(0, 0, 0);
pose = transform.doTransform(pose);
rpose = myRobot->getPose();
printf("Pos: ");
pose.log();
printf("Robot: ");
rpose.log();
if (pose.findDistanceTo(rpose) < .1)
printf("Success\n");
else
printf("#### FAILURE\n");
printf("\nRobot coords should be transformed to the origin.\n");
transform = myRobot->getToLocalTransform();
pose = myRobot->getPose();
pose = transform.doTransform(pose);
rpose.setPose(0, 0, 0);
printf("Pos: ");
pose.log();
printf("Robot: ");
rpose.log();
if (pose.findDistanceTo(rpose) < .1)
printf("Success\n");
else
printf("#### FAILURE\n");
break;
case 4:
printf("Doing a tranform test...\n");
printf("A point 1 meter to the -x from the robot (in local coords) should be transformed into global coordinates.\n");
transform = myRobot->getToGlobalTransform();
pose.setPose(-1000, 0, 0);
pose = transform.doTransform(pose);
rpose = myRobot->getPose();
printf("Pos: ");
pose.log();
printf("Robot: ");
rpose.log();
if (ArMath::fabs(pose.findDistanceTo(rpose) - 1000.0) < .1)
printf("Probable Success\n");
else
printf("#### FAILURE\n");
break;
case 5:
printf("Doing a transform test on range devices..\n");
printf("Moving the robot +4 meters x and +4 meters y and seeing if the moveTo will move the sonar readings along with it.\n");
dev = myRobot->findRangeDevice("sonar");
if (dev == NULL)
{
printf("No sonar on the robot, can't do the test.\n");
break;
}
printf("Closest sonar reading to the robot is %.0f away\n", dev->currentReadingPolar(1, 0));
printf("Sonar 0 reading is at ");
son = myRobot->getSonarReading(0);
if (son != NULL)
{
pose = son->getPose();
pose.log();
}
pose = myRobot->getPose();
pose.setX(pose.getX() + 4000);
pose.setY(pose.getY() + 4000);
myRobot->moveTo(pose);
printf("Moved robot.\n");
printf("Closest sonar reading to the robot is %.0f away\n", dev->currentReadingPolar(1, 0));
printf("Sonar 0 reading is at ");
son = myRobot->getSonarReading(0);
if (son != NULL)
{
pose = son->getPose();
pose.log();
}
break;
case 6:
printf("Robot position now is:\n");
pose = myRobot->getPose();
pose.log();
printf("Disconnecting from the robot, then reconnecting.\n");
myRobot->disconnect();
myRobot->blockingConnect();
printf("Robot position now is:\n");
pose = myRobot->getPose();
pose.log();
break;
default:
printf("No test for second button.\n");
break;
}
}
}
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);
}
}
int RosAriaNode::Setup()
{
// Note, various objects are allocated here which are never deleted (freed), since Setup() is only supposed to be
// called once per instance, and these objects need to persist until the process terminates.
robot = new ArRobot();
ArArgumentBuilder *args = new ArArgumentBuilder(); // never freed
ArArgumentParser *argparser = new ArArgumentParser(args); // Warning never freed
argparser->loadDefaultArguments(); // adds any arguments given in /etc/Aria.args. Useful on robots with unusual serial port or baud rate (e.g. pioneer lx)
// Now add any parameters given via ros params (see RosAriaNode constructor):
// if serial port parameter contains a ':' character, then interpret it as hostname:tcpport
// for wireless serial connection. Otherwise, interpret it as a serial port name.
size_t colon_pos = serial_port.find(":");
if (colon_pos != std::string::npos)
{
args->add("-remoteHost"); // pass robot's hostname/IP address to Aria
args->add(serial_port.substr(0, colon_pos).c_str());
args->add("-remoteRobotTcpPort"); // pass robot's TCP port to Aria
args->add(serial_port.substr(colon_pos+1).c_str());
}
else
{
args->add("-robotPort"); // pass robot's serial port to Aria
args->add(serial_port.c_str());
}
// if a baud rate was specified in baud parameter
if(serial_baud != 0)
{
args->add("-robotBaud");
char tmp[100];
snprintf(tmp, 100, "%d", serial_baud);
args->add(tmp);
}
if( debug_aria )
{
// turn on all ARIA debugging
args->add("-robotLogPacketsReceived"); // log received packets
args->add("-robotLogPacketsSent"); // log sent packets
args->add("-robotLogVelocitiesReceived"); // log received velocities
args->add("-robotLogMovementSent");
args->add("-robotLogMovementReceived");
ArLog::init(ArLog::File, ArLog::Verbose, aria_log_filename.c_str(), true);
}
// Connect to the robot
conn = new ArRobotConnector(argparser, robot); // warning never freed
if (!conn->connectRobot()) {
ROS_ERROR("RosAria: ARIA could not connect to robot! (Check ~port parameter is correct, and permissions on port device.)");
return 1;
}
// causes ARIA to load various robot-specific hardware parameters from the robot parameter file in /usr/local/Aria/params
if(!Aria::parseArgs())
{
ROS_ERROR("RosAria: ARIA error parsing ARIA startup parameters!");
return 1;
}
// Start dynamic_reconfigure server
dynamic_reconfigure_server = new dynamic_reconfigure::Server<rosaria::RosAriaConfig>;
robot->lock();
// Setup Parameter Minimums
rosaria::RosAriaConfig dynConf_min;
//arbitrary non-zero values so dynamic reconfigure isn't STUPID
dynConf_min.trans_vel_max = 0.1;
dynConf_min.rot_vel_max = 0.1;
dynConf_min.trans_accel = 0.1;
dynConf_min.trans_decel = 0.1;
dynConf_min.rot_accel = 0.1;
dynConf_min.rot_decel = 0.1;
// I'm setting these upper bounds relitivly arbitrarily, feel free to increase them.
dynConf_min.TicksMM = 10;
dynConf_min.DriftFactor = -200;
dynConf_min.RevCount = -32760;
dynamic_reconfigure_server->setConfigMin(dynConf_min);
rosaria::RosAriaConfig dynConf_max;
dynConf_max.trans_vel_max = robot->getAbsoluteMaxTransVel() / 1000.0;
dynConf_max.rot_vel_max = robot->getAbsoluteMaxRotVel() *M_PI/180.0;
dynConf_max.trans_accel = robot->getAbsoluteMaxTransAccel() / 1000.0;
dynConf_max.trans_decel = robot->getAbsoluteMaxTransDecel() / 1000.0;
dynConf_max.rot_accel = robot->getAbsoluteMaxRotAccel() * M_PI/180.0;
dynConf_max.rot_decel = robot->getAbsoluteMaxRotDecel() * M_PI/180.0;
// I'm setting these upper bounds relitivly arbitrarily, feel free to increase them.
dynConf_max.TicksMM = 200;
dynConf_max.DriftFactor = 200;
dynConf_max.RevCount = 32760;
dynamic_reconfigure_server->setConfigMax(dynConf_max);
dynConf_default.trans_vel_max = robot->getTransVelMax() / 1000.0;
dynConf_default.rot_vel_max = robot->getRotVelMax() *M_PI/180.0;
dynConf_default.trans_accel = robot->getTransAccel() / 1000.0;
dynConf_default.trans_decel = robot->getTransDecel() / 1000.0;
dynConf_default.rot_accel = robot->getRotAccel() * M_PI/180.0;
dynConf_default.rot_decel = robot->getRotDecel() * M_PI/180.0;
/* ROS_ERROR("ON ROBOT NOW\n\
Trans vel max: %f\n\
Rot vel max: %f\n\
\n\
trans accel: %f\n\
trans decel: %f\n\
rot accel: %f\n\
rot decel: %f", robot->getTransVelMax(), robot->getRotVelMax(), robot->getTransAccel(), robot->getTransDecel(), robot->getRotAccel(), robot->getRotDecel());
ROS_ERROR("IN DEFAULT CONFIG\n\
Trans vel max: %f\n\
Rot vel max: %f\n\
\n\
trans accel: %f\n\
trans decel: %f\n\
rot accel: %f\n\
rot decel: %f\n", dynConf_default.trans_vel_max, dynConf_default.rot_vel_max, dynConf_default.trans_accel, dynConf_default.trans_decel, dynConf_default.rot_accel, dynConf_default.rot_decel);*/
TicksMM = robot->getOrigRobotConfig()->getTicksMM();
DriftFactor = robot->getOrigRobotConfig()->getDriftFactor();
RevCount = robot->getOrigRobotConfig()->getRevCount();
dynConf_default.TicksMM = TicksMM;
dynConf_default.DriftFactor = DriftFactor;
dynConf_default.RevCount = RevCount;
dynamic_reconfigure_server->setConfigDefault(dynConf_default);
for(int i = 0; i < 16; i++)
{
sonar_tf_array[i].header.frame_id = frame_id_base_link;
std::stringstream _frame_id;
_frame_id << "sonar" << i;
sonar_tf_array[i].child_frame_id = _frame_id.str();
ArSensorReading* _reading = NULL;
_reading = robot->getSonarReading(i);
sonar_tf_array[i].transform.translation.x = _reading->getSensorX() / 1000.0;
sonar_tf_array[i].transform.translation.y = _reading->getSensorY() / 1000.0;
sonar_tf_array[i].transform.translation.z = 0.19;
sonar_tf_array[i].transform.rotation = tf::createQuaternionMsgFromYaw(_reading->getSensorTh() * M_PI / 180.0);
}
for (int i=0;i<16;i++) {
sensor_msgs::Range r;
ranges.data.push_back(r);
}
int i=0,j=0;
if (sonars__crossed_the_streams) {
i=8;
j=8;
}
for(; i<16; i++) {
//populate the RangeArray msg
std::stringstream _frame_id;
_frame_id << "sonar" << i;
ranges.data[i].header.frame_id = _frame_id.str();
ranges.data[i].radiation_type = 0;
ranges.data[i].field_of_view = 0.2618f;
ranges.data[i].min_range = 0.03f;
ranges.data[i].max_range = 5.0f;
}
// Enable the motors
robot->enableMotors();
robot->disableSonar();
// Initialize bumpers with robot number of bumpers
bumpers.front_bumpers.resize(robot->getNumFrontBumpers());
bumpers.rear_bumpers.resize(robot->getNumRearBumpers());
robot->unlock();
pose_pub = n.advertise<nav_msgs::Odometry>("pose",1000);
bumpers_pub = n.advertise<rosaria::BumperState>("bumper_state",1000);
voltage_pub = n.advertise<std_msgs::Float64>("battery_voltage", 1000);
combined_range_pub = n.advertise<rosaria::RangeArray>("ranges", 1000,
boost::bind(&RosAriaNode::sonarConnectCb,this),
boost::bind(&RosAriaNode::sonarDisconnectCb, this));
for(int i =0; i < 16; i++) {
std::stringstream topic_name;
topic_name << "range" << i;
range_pub[i] = n.advertise<sensor_msgs::Range>(topic_name.str().c_str(), 1000,
boost::bind(&RosAriaNode::sonarConnectCb,this),
boost::bind(&RosAriaNode::sonarDisconnectCb, this));
}
recharge_state_pub = n.advertise<std_msgs::Int8>("battery_recharge_state", 5, true /*latch*/ );
recharge_state.data = -2;
state_of_charge_pub = n.advertise<std_msgs::Float32>("battery_state_of_charge", 100);
motors_state_pub = n.advertise<std_msgs::Bool>("motors_state", 5, true /*latch*/ );
motors_state.data = false;
published_motors_state = false;
// subscribe to services
cmdvel_sub = n.subscribe( "cmd_vel", 1, (boost::function <void(const geometry_msgs::TwistConstPtr&)>)
boost::bind(&RosAriaNode::cmdvel_cb, this, _1 ));
// advertise enable/disable services
enable_srv = n.advertiseService("enable_motors", &RosAriaNode::enable_motors_cb, this);
disable_srv = n.advertiseService("disable_motors", &RosAriaNode::disable_motors_cb, this);
veltime = ros::Time::now();
sonar_tf_timer = n.createTimer(ros::Duration(0.033), &RosAriaNode::sonarCallback, this);
sonar_tf_timer.stop();
dynamic_reconfigure_server->setCallback(boost::bind(&RosAriaNode::dynamic_reconfigureCB, this, _1, _2));
// callback will be called by ArRobot background processing thread for every SIP data packet received from robot
robot->addSensorInterpTask("ROSPublishingTask", 100, &myPublishCB);
// Run ArRobot background processing thread
robot->runAsync(true);
return 0;
}
