Soft robot team
Robot team project
Dependencies: QEI Motordriver ros_lib_melodic
main.cpp
- Committer:
- dnulty
- Date:
- 2020-01-06
- Revision:
- 23:d1dc248b4e54
- Parent:
- 20:074a3638c702
- Child:
- 24:4d6ff25fb9cc
File content as of revision 23:d1dc248b4e54:
#include "mbed.h"
#include <ros.h>
#include <std_msgs/Empty.h>
#include <std_msgs/Int32.h>
#include <std_msgs/String.h>
#include <mbed_custom_msgs/motor_msg.h>
#include <motordriver.h>
#include "QEI.h"
#include <cstdlib>
#include "Sensor.h"
// Set up serial to pc
//Serial pc(SERIAL_TX, SERIAL_RX);
//Threading for sensor readings
Thread thread1;
Thread thread2;
Mutex SerialMutex;
// Set up I²C on the STM32 NUCLEO-401RE
#define addr1 (0x29)
#define addr2 (0x2A)
#define addr3 (0x2B)
#define addr4 (0x2C)
#define S1 PC_8
#define S2 PC_9
#define S3 PC_10
#define S4 PC_11
#define S5 PC_12
#define S6 PD_2
#define S7 PG_2
#define S8 PG_3
// VL6180x sensors
Sensor sensor_back(I2C_SDA, I2C_SCL, S1);
Sensor sensor_left(I2C_SDA, I2C_SCL, S3);
Sensor sensor_forward(I2C_SDA, I2C_SCL, S5);
Sensor sensor_right(I2C_SDA, I2C_SCL, S7);
// Floats for sensor readings
float sensor_forward_reading;
float sensor_back_reading;
float sensor_left_reading;
float sensor_right_reading;
//Initialised motor speed
double speed=0.6;
//used to change control to set distances of continous movement
bool control_type = 1;;
//used for the switch cases and the distance travelled
int32_t motor_option;
int32_t pulse = 6000;
// Set motorpins for driving
Motor A(PB_13, PB_15, PC_6, 1); // pwm, fwd, rev, can brake
Motor B(PB_4, PC_7, PA_15, 1); // pwm, fwd, rev, can brake
QEI wheel_A (PB_12, PA_4, NC, 3576, QEI::X4_ENCODING); //counts per rev = 12 * 298:1, use quadrature encoding
QEI wheel_B (PB_5, PB_3, NC, 3576, QEI::X4_ENCODING); //counts per rev = 12 * 298:1, use quadrature encoding
//Thread function to update sensor readings
void flip() {
while(1) {
SerialMutex.lock();
// Sensor readings
sensor_forward_reading = sensor_forward.read();
sensor_back_reading = sensor_back.read();
sensor_left_reading = sensor_left.read();
sensor_right_reading = sensor_right.read();
SerialMutex.unlock();
thread1.wait(2);
}
}
void motor_callback(const mbed_custom_msgs::motor_msg& msg)
{
motor_option = msg.dir;
if( (msg.distance <= 0) or (msg.distance > 120) ) {
pulse = 6000;
} else {
pulse = msg.distance * 200; // Est 200 pulses per cm
}
//motor_option = motor_dir.data;
thread2.signal_set(1);
}
// Function to move robot
void move(float motorA, float motorB, int distance) {
float current_pulse_reading = 0;
// Set motors speed
A.speed(motorA);
B.speed(motorB);
while(abs(current_pulse_reading) <= distance) {
current_pulse_reading = wheel_A.getPulses();
//Stops Robot moving forward if front sensor detects
if (sensor_back_reading <255 and motorA>0 and motorB>0){
return;
}
//Stops robot reversing if back sensors detects
if (sensor_forward_reading <255 and motorA<0 and motorB<0){
return;
}
}
}
void square()
{
float current_pulse_reading = 0;
// - is forward on our robot
for(int i = 0; i<4 ; i++)
{
current_pulse_reading = 0;
while(abs(current_pulse_reading) <= 6000)
{
A.speed(-speed);
B.speed(-speed);
current_pulse_reading = wheel_A.getPulses();
//Stops Robot moving forward if front sensor detects
if (sensor_forward_reading <255)
{
return;
}
}
// need to set motor speed to 0
A.speed(0);
B.speed(0);
wait(0.05);
A.speed(-speed);
B.speed(speed);
wheel_B.reset();
wheel_A.reset();
while(abs(current_pulse_reading) <= 2782)
{
current_pulse_reading = wheel_A.getPulses();
}
wheel_B.reset();
wheel_A.reset();
}
A.speed(0);
B.speed(0);
wait(0.05);
}
void dance()
{
wait(5);// required for audacity to play music
for (int i =0; i<10; i++)
{
int distance = (rand()%7000+2000);
float A_speed = (rand()%2-1);
float B_speed = (rand()%2-1);
/* if((A_speed < 0.4) && (A_speed > -0.4)){
A_speed = 0.4;
}
if((B_speed < 0.4) && (B_speed > -0.4)){
B_speed = 0.4;
} */
move(A_speed,B_speed,distance);
wheel_B.reset();
wheel_A.reset();
}
}
// Function to set robot direction and distance according to data published on motor_control topic
void control_motor(void) {
while (1){
thread2.signal_wait(1);
switch(motor_option) {
// Do nothing - default value published on motor_contorl topic
case 0:
break;
//Forward
case 1://49
if (control_type == 1){
move(-speed, -speed, pulse);
}
else if (control_type ==0){
move(-speed, -speed, 50);
}
break;
//Left
case 2://50
if (control_type == 1 ){
move(speed, -speed, pulse/6.7); // Divide by 6.7 to convert to degrees
}
else if (control_type == 0){
move(speed, -speed, 100);
}
break;
//Right
case 3://51
if (control_type == 1 ){
move(-speed, speed, pulse/6.7);
}
else if (control_type == 0 ){
move(-speed, speed, 60);
}
break;
// Reverse
case 4://52
if (control_type ==1 ){
move(speed, speed, pulse);
}
else if (control_type ==0 ){
move(speed, speed, 50);
}
break;
// Speed up
case 5:
if (speed < 1.0){
speed += 0.2;
}
break;
// Speed down
case 6:
if (speed>0.2){
speed -= 0.2;
}
break;
// Switch control type
case 7:
control_type =! control_type;
break;
// Turn around
case 8:
if (control_type == 1 ){
move(-speed, speed, 5376);
}
break;
// Draw a square
case 9:
square();
break;
case 10:
dance();
break;
}
//Reset speed and pulse count
A.speed(0);
B.speed(0);
wheel_B.reset();
wheel_A.reset();
}
}
int main()
{
ros::NodeHandle nh;
nh.initNode();
// ROS subscriber for motors control
ros::Subscriber<mbed_custom_msgs::motor_msg> motor_sub("motor_control", &motor_callback);
nh.subscribe(motor_sub);
// load settings onto VL6180X sensors
sensor_forward.init();
// change default address of sensor 2
sensor_forward.changeAddress(addr2);
sensor_right.init();
// change default address of sensor 3
sensor_right.changeAddress(addr3);
sensor_back.init();
// change default address of sensor 4
sensor_back.changeAddress(addr4);
sensor_left.init();
thread1.start(callback(&flip));
thread2.start(callback(&control_motor));
while(1) {
nh.spinOnce();
}
}