Luka Danilovic
Q
Dependencies: SRF05 ros_lib_kinetic TinyGPSPlus
PROJ515.cpp
- Committer:
- Luka_Danilovic
- Date:
- 2019-05-09
- Revision:
- 12:1a3272d67500
- Parent:
- 11:955c2ed70de2
- Child:
- 14:b972d0d0f63d
File content as of revision 12:1a3272d67500:
#include "PROJ515.hpp" // Contains Libraries, Definitions & Function Prototypes
float cfDist1 = 0; // Distance returned by cliff u_sensor1 (m)
float cfDist2 = 0; // Distance returned by cliff u_sensor2 (m)
float cfDist3 = 0; // Distance returned by cliff u_sensor3 (m)
float cfDist4 = 0; // Distance returned by cliff u_sensor4 (m)
float cbDist1 = 0; // Distance returned by curb u_sensor1 (m)
float cbDist2 = 0; // Distance returned by curb u_sensor2 (m)
float cbDist3 = 0; // Distance returned by curb u_sensor3 (m)
float cbDist4 = 0; // Distance returned by curb u_sensor4 (m)
float wPeriod = 10; // Wait period(ms) for ROS publisher to finish publishing
char gps_c = 0; // GPS serial character
int sats_n = 0; // GPS Satelite count
int main()
{
nh.getHardware()->setBaud(ROS_Baud); // Set Baud Rate for ROS Serial
nh.initNode(); // Initialise ROS Node Handler
advRosPub(); // Adverstise Ultrasound Topic
nh.advertise(gps_odom_pub); // Adverstise Odometry topic
setupRosMsg(); // Setup the message constant values
gps_odom_msg.header.frame_id = frameID_g; // Pack ROS frame ID
gps_odom_msg.status.status = UNAGUMENTED; // Location fix method
gps_odom_msg.status.service = GPS_CONSTELL; // Satelite constellation used
gps_odom_msg.altitude = 0; // Altitude (Always fixed)
gps_odom_msg.position_covariance[ 0] = CVX; // X pos covariance
gps_odom_msg.position_covariance[ 1] = CVO; // Zero
gps_odom_msg.position_covariance[ 2] = CVO; // Zero
gps_odom_msg.position_covariance[ 3] = CVO; // Zero
gps_odom_msg.position_covariance[ 4] = CVY; // Y pos covariance
gps_odom_msg.position_covariance[ 5] = CVO; // Zero
gps_odom_msg.position_covariance[ 6] = CVO; // Zero
gps_odom_msg.position_covariance[ 7] = CVO; // Zero
gps_odom_msg.position_covariance[ 8] = CVZ; // Z pos covariance
gps_odom_msg.position_covariance_type = UNNWN; // Covariance type
gpsSer.baud(GPS_Baud); // Set Baud rate for GPS Serial
while(!nh.connected()) { // While node handler is !connected
nh.spinOnce(); // Attempt to connect & synchronise
}
while(true) {
startSensors(); // Start the Sensors
recordDist(); // Record the Distances (meters)
checkCliff(); // Check the Cliff Sensors Readings
setRosDist(); // Put distance in ROS messages
setRosStamp(); // Put time into ROS messages
publishRosMsg(); // Publish ROS messages
if(gpsSer.readable()) { // If serial buffer has character
gps_c = gpsSer.getc(); // Read serial buffer and store character
gpsModule.encode(gps_c); // Encode character from GPS
} else {
leds = leds & 0b100; // Flash LED[0,1] bus OFF. Leave LED[2] on if its on to indicate that the signal was present
}
if (gpsModule.location.isValid()) { // If GPS location is Valid
gps_odom_msg.latitude = gpsModule.location.lng(); // Get Longtitude
gps_odom_msg.longitude = gpsModule.location.lat(); // Get Latitude
nh.spinOnce(); // Reccuring connect and synchronise
gps_odom_msg.header.stamp = nh.now(); // Get current time
gps_odom_pub.publish(&gps_odom_msg); // Publish the Odometry message
}
sats_n = gpsModule.satellites.value(); // Aquire satelite number
if (sats_n > 0){
leds = LEDS_ON;
}
}
}
/*============================================================================*/
/* FUNCTIONS */
/*============================================================================*/
void advRosPub()
{
// Adverstise Ultrasound topic
nh.advertise(ultrasound_pub_cf1);
nh.advertise(ultrasound_pub_cf2);
nh.advertise(ultrasound_pub_cf3);
nh.advertise(ultrasound_pub_cf4);
nh.advertise(ultrasound_pub_cb1);
nh.advertise(ultrasound_pub_cb2);
nh.advertise(ultrasound_pub_cb3);
nh.advertise(ultrasound_pub_cb4);
}
void setupRosMsg()
{
// Setup the message constant values
// Frame ID
ultrasound_msg_cf1.header.frame_id = "uss_cf1";
ultrasound_msg_cf2.header.frame_id = "uss_cf2";
ultrasound_msg_cf3.header.frame_id = "uss_cf3";
ultrasound_msg_cf4.header.frame_id = "uss_cf4";
ultrasound_msg_cb1.header.frame_id = "uss_cb1";
ultrasound_msg_cb2.header.frame_id = "uss_cb2";
ultrasound_msg_cb3.header.frame_id = "uss_cb3";
ultrasound_msg_cb4.header.frame_id = "uss_cb4";
// Radiation Type
ultrasound_msg_cf1.radiation_type = ULTRASOUND;
ultrasound_msg_cf2.radiation_type = ULTRASOUND;
ultrasound_msg_cf3.radiation_type = ULTRASOUND;
ultrasound_msg_cf4.radiation_type = ULTRASOUND;
ultrasound_msg_cb1.radiation_type = ULTRASOUND;
ultrasound_msg_cb2.radiation_type = ULTRASOUND;
ultrasound_msg_cb3.radiation_type = ULTRASOUND;
ultrasound_msg_cb4.radiation_type = ULTRASOUND;
// Field of View
ultrasound_msg_cf1.field_of_view = FOV;
ultrasound_msg_cf2.field_of_view = FOV;
ultrasound_msg_cf3.field_of_view = FOV;
ultrasound_msg_cf4.field_of_view = FOV;
ultrasound_msg_cb1.field_of_view = FOV;
ultrasound_msg_cb2.field_of_view = FOV;
ultrasound_msg_cb3.field_of_view = FOV;
ultrasound_msg_cb4.field_of_view = FOV;
// Minumum Range
ultrasound_msg_cf1.min_range = MIN_RANGE;
ultrasound_msg_cf2.min_range = MIN_RANGE;
ultrasound_msg_cf3.min_range = MIN_RANGE;
ultrasound_msg_cf4.min_range = MIN_RANGE;
ultrasound_msg_cb1.min_range = MIN_RANGE;
ultrasound_msg_cb2.min_range = MIN_RANGE;
ultrasound_msg_cb3.min_range = MIN_RANGE;
ultrasound_msg_cb4.min_range = MIN_RANGE;
// Maximum Range
ultrasound_msg_cf1.max_range = MAX_RANGE;
ultrasound_msg_cf2.max_range = MAX_RANGE;
ultrasound_msg_cf3.max_range = MAX_RANGE;
ultrasound_msg_cf4.max_range = MAX_RANGE;
ultrasound_msg_cb1.max_range = MAX_RANGE;
ultrasound_msg_cb2.max_range = MAX_RANGE;
ultrasound_msg_cb3.max_range = MAX_RANGE;
ultrasound_msg_cb4.max_range = MAX_RANGE;
}
void startSensors()
{
// Start the Sensors
USS_CF1.start();
USS_CF2.start();
USS_CF3.start();
USS_CF4.start();
USS_CB1.start();
USS_CB2.start();
USS_CB3.start();
USS_CB4.start();
}
void recordDist()
{
// Record the Distances (meters)
cfDist1 = USS_CF1.get_dist();
cfDist2 = USS_CF2.get_dist();
cfDist3 = USS_CF3.get_dist();
cfDist4 = USS_CF4.get_dist();
cbDist1 = USS_CB1.get_dist();
cbDist2 = USS_CB2.get_dist();
cbDist3 = USS_CB3.get_dist();
cbDist4 = USS_CB4.get_dist();
}
void checkCliff()
{
/* Check the Cliff Sensors (If distance more than clif treshold,
hardcode the cliff value in, else no obstacle)*/
if (static_cast<double>(cfDist1) <= CLIFF_TRH) {
cfDist1 = CLIFF_ZRO;
} else {
cfDist1 = EXCL_ZONE;
}
if (static_cast<double>(cfDist2) <= CLIFF_TRH) {
cfDist2 = CLIFF_ZRO;
} else {
cfDist2 = EXCL_ZONE;
}
if (static_cast<double>(cfDist3) <= CLIFF_TRH) {
cfDist3 = CLIFF_ZRO;
} else {
cfDist3 = EXCL_ZONE;
}
if (static_cast<double>(cfDist4) <= CLIFF_TRH) {
cfDist4 = CLIFF_ZRO;
} else {
cfDist4 = EXCL_ZONE;
}
}
void setRosDist()
{
// Put distance in ROS messages
ultrasound_msg_cf1.range = cfDist1;
ultrasound_msg_cf2.range = cfDist2;
ultrasound_msg_cf3.range = cfDist3;
ultrasound_msg_cf4.range = cfDist4;
ultrasound_msg_cb1.range = cbDist1;
ultrasound_msg_cb2.range = cbDist2;
ultrasound_msg_cb3.range = cbDist3;
ultrasound_msg_cb4.range = cbDist4;
}
void setRosStamp()
{
// Get current time and put into ROS messages
nh.spinOnce(); // Reccuring connect and synchronise
ultrasound_msg_cf1.header.stamp = nh.now();
ultrasound_msg_cf2.header.stamp = nh.now();
ultrasound_msg_cf3.header.stamp = nh.now();
ultrasound_msg_cf4.header.stamp = nh.now();
ultrasound_msg_cb1.header.stamp = nh.now();
ultrasound_msg_cb2.header.stamp = nh.now();
ultrasound_msg_cb3.header.stamp = nh.now();
ultrasound_msg_cb4.header.stamp = nh.now();
}
void publishRosMsg()
{
// Publish ROS messages
ultrasound_pub_cf1.publish(&ultrasound_msg_cf1);
wait_ms(wPeriod);
ultrasound_pub_cf2.publish(&ultrasound_msg_cf2);
wait_ms(wPeriod);
ultrasound_pub_cf3.publish(&ultrasound_msg_cf3);
wait_ms(wPeriod);
ultrasound_pub_cf4.publish(&ultrasound_msg_cf4);
wait_ms(wPeriod);
ultrasound_pub_cb1.publish(&ultrasound_msg_cb1);
wait_ms(wPeriod);
ultrasound_pub_cb2.publish(&ultrasound_msg_cb2);
wait_ms(wPeriod);
ultrasound_pub_cb3.publish(&ultrasound_msg_cb3);
wait_ms(wPeriod);
ultrasound_pub_cb4.publish(&ultrasound_msg_cb4);
wait_ms(wPeriod);
}