MEGACARAZ
PIDs and fun
Dependencies: btbee m3pi_ng mbed FatFileSystemCpp
main.cpp
- Committer:
- crmackey
- Date:
- 2015-05-22
- Revision:
- 1:936e329e840a
- Parent:
- 0:4d1ae7eb0070
- Child:
- 2:1e947dcc40cb
File content as of revision 1:936e329e840a:
#include "mbed.h"
#include "m3pi_ng.h"
#include "time.h"
#include "btbee.h"
m3pi m3pi;
btbee btbee;
DigitalIn m3pi_pb(p21);
DigitalIn m3pi_IN[] = {(p12)};
DigitalOut mbed_led[] = {(LED1), (LED2),(LED3), (LED4)};
DigitalOut m3pi_led[] = {(p13), (p14), (p15), (p16), (p17), (p18), (p19), (p20)};
// Minimum and maximum motor speeds
#define MAX 1.0
#define MIN 0
// PID terms
#define P_TERM 1.5
#define I_TERM 0
#define D_TERM 25
int main() {
double IR;
while(1) {
btbee.reset();
m3pi_pb.mode(PullUp);
m3pi.printf("Wait 4");
m3pi.locate(0,1);
m3pi.printf("PC");
while(m3pi_pb) {
m3pi_led[0]=!m3pi_led[0];
wait(3);
btbee.printf("\n");
btbee.printf("PC connected. Press the button \n");
}
m3pi.cls();
Timer LapTimer;
char Bat[] = {'V','o','l','t',' ','i','s'};
m3pi.print(Bat,7);
wait(0.75);
m3pi.cls();
float batteryvoltage = m3pi.battery();
char* str = new char[30];
sprintf(str, "%.4g", batteryvoltage);
m3pi.print(str,6);
btbee.printf("Battery voltage is %f \n", batteryvoltage);
wait(0.75);
m3pi.cls();
if (batteryvoltage < 4.2)
{
char low[] = {'L','o','w',' ','b','a','t'};
m3pi.print(low,7);
char ExitSound[]={'V','1','5','O','6','E','4','O','5','E','4'};
m3pi.playtune(ExitSound,11);
btbee.printf("Battery voltage is too low. Stopping program");
exit(1);
}
m3pi.locate(0,1);
m3pi.printf("Line PID");
wait(2.0);
btbee.printf("Now calibrating \n");
m3pi.sensor_auto_calibrate();
btbee.printf("Finished calibrating \n");
while (m3pi_IN [0] == 0) {
btbee.printf("Obstacle detected. Please remove to continue");
m3pi.stop();
wait(3.0);
}
float right;
float left;
float current_pos_of_line = 0.0;
float previous_pos_of_line = 0.0;
float derivative,proportional,integral = 0;
float power;
float speed = MAX;
int LapTest[5];
int s1, s2, s3, s4, s5;
int counter = -1;
int checkvar = 0;
double Time1, Time2, Time3, Time4, Time5, TimeAve;
btbee.printf("\n");
btbee.printf("Now starting \n");
while (1) {
// Get the position of the line.
current_pos_of_line = m3pi.line_position();
proportional = current_pos_of_line;
// Compute the derivative
derivative = current_pos_of_line - previous_pos_of_line;
// Compute the integral
integral += proportional;
// Remember the last position.
previous_pos_of_line = current_pos_of_line;
// Compute the power
power = (proportional * (P_TERM) ) + (integral*(I_TERM)) + (derivative*(D_TERM)) ;
// Compute new speeds
right = speed+power;
left = speed-power;
// limit checks
if (right < MIN)
right = MIN;
else if (right > MAX)
right = MAX;
if (left < MIN)
left = MIN;
else if (left > MAX)
left = MAX;
// set speed
m3pi.left_motor(left);
m3pi.right_motor(right);
m3pi.calibrated_sensor(LapTest);
s1 = LapTest[0];
s2 = LapTest[1];
s3 = LapTest[2];
s4 = LapTest[3];
s5 = LapTest[4];
if (s1 > 500 and s5 > 500) {
checkvar = 1;
}
if (s1 < 500 and s5 < 500 and checkvar == 1 and counter == -1) {
LapTimer.start();
}
if (s1 < 500 and s5 < 500 and checkvar == 1) {
counter = counter + 1;
m3pi.cls();
m3pi.printf("%d", counter);
checkvar = 0;
switch (counter) {
case 1: {
Time1 = LapTimer.read();
LapTimer.reset();
LapTimer.start();
btbee.printf("Lap 1: %f \n", Time1);
break;
}
case 2: {
Time2 = LapTimer.read();
LapTimer.reset();
LapTimer.start();
btbee.printf("Lap 2: %f \n", Time2);
break;
}
case 3: {
Time3 = LapTimer.read();
LapTimer.reset();
LapTimer.start();
btbee.printf("Lap 3: %f \n", Time3);
break;
}
case 4: {
Time4 = LapTimer.read();
LapTimer.reset();
LapTimer.start();
btbee.printf("Lap 4: %f \n", Time4);
break;
}
case 5: {
Time5 = LapTimer.read();
LapTimer.reset();
LapTimer.start();
btbee.printf("Lap 5: %f \n", Time5);
break;
}
}
}
if (counter == 5) {
m3pi.stop();
m3pi.cls();
m3pi.locate(0,0);
m3pi.printf("Ave time");
TimeAve = (Time1 + Time2 + Time3 + Time4 + Time5)/5.0;
m3pi.locate(0,1);
m3pi.printf("%f", TimeAve);
btbee.printf("Average time per lap: %f ", TimeAve);
exit(1);
}
}
}
}