MacroRat
Mouse code for the MacroRat
main.cpp
- Committer:
- christine222
- Date:
- 2017-05-21
- Revision:
- 25:f827a8b7880e
- Parent:
- 24:e7063765d6f0
- Child:
- 26:d20f1adac2d3
File content as of revision 25:f827a8b7880e:
#include "mbed.h"
#include "irpair.h"
#include "main.h"
#include "motor.h"
#include <stdlib.h>
#include "ITG3200.h"
#include "stm32f4xx.h"
#include "QEI.h"
/* Constants for when HIGH_PWM_VOLTAGE = 0.2
#define IP_CONSTANT 6
#define II_CONSTANT 0
#define ID_CONSTANT 1
*/
// Constants for when HIGH_PWM_VOLTAGE = 0.1
// #define IP_CONSTANT 8.85
// #define II_CONSTANT 0.005
// #define ID_CONSTANT 3.15
#define IP_CONSTANT 8.5
#define II_CONSTANT 0.095
#define ID_CONSTANT 6.85
const int desiredCount180 = 2850;
const int desiredCountR = 1575;
const int desiredCountL = 1650;
const int oneCellCount = 5400;
const int oneCellCountMomentum = 4700; // one cell count is actually approximately 5400, but this value is considering momentum!
float receiverOneReading = 0.0;
float receiverTwoReading = 0.0;
float receiverThreeReading = 0.0;
float receiverFourReading = 0.0;
float initAverageL = 8.28;
float averageDivL = 29.5; //blue
float initAverageR = 8.75; //4.5
float averageDivR = 29.5; //red
float averageDivUpper = 0.9;
void pidOnEncoders();
void turnLeft()
{
double speed0 = 0.11;
double speed1 = -0.13;
int counter = 0;
int initial0 = encoder0.getPulses();
int initial1 = encoder1.getPulses();
int desiredCount0 = initial0 - desiredCountL;
int desiredCount1 = initial1 + desiredCountL;
int count0 = initial0;
int count1 = initial1;
double error0 = count0 - desiredCount0;
double error1 = count1 - desiredCount1;
while(1) {
if(!(abs(error0) < 1) && !(abs(error1) < 1)) {
count0 = encoder0.getPulses();
count1 = encoder1.getPulses();
error0 = count0 - desiredCount0;
error1 = count1 - desiredCount1;
right_motor.move(speed0);
left_motor.move(speed1);
counter = 0;
} else {
counter++;
right_motor.brake();
left_motor.brake();
}
if (counter > 60) {
break;
}
}
right_motor.brake();
left_motor.brake();
turnFlag = 0; // zeroing out the flags!
currDir -= 1;
}
void turnRight()
{
double speed0 = -0.11;
double speed1 = 0.13;
int counter = 0;
int initial0 = encoder0.getPulses();
int initial1 = encoder1.getPulses();
int desiredCount0 = initial0 + desiredCountR;
int desiredCount1 = initial1 - desiredCountR;
int count0 = initial0;
int count1 = initial1;
double error0 = count0 - desiredCount0;
double error1 = count1 - desiredCount1;
while(1) {
if(!(abs(error0) < 1) && !(abs(error1) < 1)) {
count0 = encoder0.getPulses();
count1 = encoder1.getPulses();
error0 = count0 - desiredCount0;
error1 = count1 - desiredCount1;
right_motor.move(speed0);
left_motor.move(speed1);
counter = 0;
} else {
counter++;
right_motor.brake();
left_motor.brake();
}
if (counter > 60) {
break;
}
}
right_motor.brake();
left_motor.brake();
turnFlag = 0;
currDir += 1;
}
void turnLeft180()
{
double speed0 = 0.15;
double speed1 = -0.15;
int counter = 0;
int initial0 = encoder0.getPulses();
int initial1 = encoder1.getPulses();
int desiredCount0 = initial0 - desiredCountL*2;
int desiredCount1 = initial1 + desiredCountL*2;
int count0 = initial0;
int count1 = initial1;
double error0 = count0 - desiredCount0;
double error1 = count1 - desiredCount1;
while(1) {
if(!(abs(error0) < 1) && !(abs(error1) < 1)) {
count0 = encoder0.getPulses();
count1 = encoder1.getPulses();
error0 = count0 - desiredCount0;
error1 = count1 - desiredCount1;
right_motor.move(speed0);
left_motor.move(speed1);
counter = 0;
} else {
counter++;
right_motor.brake();
left_motor.brake();
}
if (counter > 60) {
break;
}
}
right_motor.brake();
left_motor.brake();
currDir -= 2;
}
void turnRight180()
{
double speed0 = -0.16;
double speed1 = 0.16;
int counter = 0;
int initial0 = encoder0.getPulses();
int initial1 = encoder1.getPulses();
int desiredCount0 = initial0 + desiredCount180;
int desiredCount1 = initial1 - desiredCount180;
int count0 = initial0;
int count1 = initial1;
double error0 = count0 - desiredCount0;
double error1 = count1 - desiredCount1;
while(1) {
if(!(abs(error0) < 1) && !(abs(error1) < 1)) {
count0 = encoder0.getPulses();
count1 = encoder1.getPulses();
error0 = count0 - desiredCount0;
error1 = count1 - desiredCount1;
right_motor.move(speed0);
left_motor.move(speed1);
counter = 0;
} else {
counter++;
right_motor.brake();
left_motor.brake();
}
if (counter > 60) {
break;
}
}
right_motor.brake();
left_motor.brake();
currDir += 2;
}
void moveForwardCellEncoder(double cellNum){
int desiredCount0 = encoder0.getPulses() + oneCellCountMomentum*cellNum;
int desiredCount1 = encoder1.getPulses() + oneCellCountMomentum*cellNum;
left_motor.forward(0.125);
right_motor.forward(0.095);
wait_ms(1);
while (encoder0.getPulses() <= desiredCount0 && encoder1.getPulses() <= desiredCount1){
receiverTwoReading = IRP_2.getSamples(100);
receiverThreeReading = IRP_3.getSamples(100);
// serial.printf("Average 2: %f Average 3: %f Sensor 2: %f Sensor 3: %f\n", IRP_2.sensorAvg, IRP_3.sensorAvg, receiverTwoReading, receiverThreeReading);
if (receiverThreeReading < IRP_3.sensorAvg/averageDivR){
// redLed.write(1);
// blueLed.write(0);
turnFlag |= RIGHT_FLAG;
}
else if (receiverTwoReading < IRP_2.sensorAvg/averageDivL){
// redLed.write(0);
// blueLed.write(1);
turnFlag |= LEFT_FLAG;
}
pidOnEncoders();
}
left_motor.brake();
right_motor.brake();
}
void handleTurns(){
if (turnFlag == 0x1){
// moveForwardCellEncoder(0.3);
turnLeft();
}
else if (turnFlag == 0x2){
// moveForwardCellEncoder(0.3);
turnRight();
}
else if (turnFlag == 0x3){
// moveForwardCellEncoder(0.3);
turnLeft();
turnRight();
}
}
void pidBrake(){
int count0;
int count1;
count0 = encoder0.getPulses();
count1 = encoder1.getPulses();
int initial0 = count0;
int initial1 = count1;
double kp = 0.00011;
int error = count0 - count1;
int counter = 0;
right_motor.move(0.7);
left_motor.move(0.7);
double speed0 = 0.7;
double speed1 = 0.7;
while(1)
{
if(abs(error) < 3){
right_motor.brake();
left_motor.brake();
counter++;
}else{
count0 = encoder0.getPulses() - initial0;
count1 = encoder1.getPulses() - initial1;
error = count0 - count1;
speed0 = -error*kp + speed0;
speed1 = error*kp + speed1;
right_motor.move(speed0);
left_motor.move(speed1);
counter = 0;
}
if (counter > 10){
break;
}
}
return;
}
void moveForwardEncoder(){
int count0;
int count1;
count0 = encoder0.getPulses();
count1 = encoder1.getPulses();
int initial1 = count1;
int initial0 = count0;
int diff = count0 - count1;
double kp = 0.00015;
double kd = 0.00019;
int prev = 0;
double speed0 = 0.10;
double speed1 = 0.12;
right_motor.move(speed0);
left_motor.move(speed1);
while((encoder0.getPulses() - initial0) <= (oneCellCountMomentum-200) && (encoder1.getPulses() - initial1) <= (oneCellCountMomentum-200)) {
//while( (IRP_1.getSamples(50) + IRP_4.getSamples(50))/2 < ((IRP_1.sensorAvg+IRP_2.sensorAvg)/2)*0.4 ){
//serial.printf("IRS= >: %f, %f \r\n", IRP_2.getSamples( 100 ), IRP_3.getSamples( 100 ));
count0 = encoder0.getPulses() - initial0;
count1 = encoder1.getPulses() - initial1;
int x = count0 - count1;
//double d = kp * x + kd * ( x - prev );
double kppart = kp * x;
double kdpart = kd * (x-prev);
double d = kppart + kdpart;
//serial.printf( "x: %d,\t prev: %d,\t d: %f,\t kppart: %f,\t kdpart: %f\n", x, prev, d, kppart, kdpart );
if( x < diff - 40 ) // count1 is bigger, right wheel pushed forward
{
left_motor.move( speed1-0.8*d );
right_motor.move( speed0+d );
}
else if( x > diff + 40 )
{
left_motor.move( speed1-0.8*d );
right_motor.move( speed0+d );
}
// else
// {
// left_motor.brake();
// right_motor.brake();
// }
prev = x;
}
//pidOnEncoders();
//pidBrake();
right_motor.brake();
left_motor.brake();
return;
}
void moveForwardWallEncoder(){
int count0;
int count1;
count0 = encoder0.getPulses();
count1 = encoder1.getPulses();
int initial1 = count1;
int initial0 = count0;
int diff = count0 - count1;
double kp = 0.00015;
double kd = 0.00019;
int prev = 0;
double speed0 = 0.11;
double speed1 = 0.13;
right_motor.move(speed0);
left_motor.move(speed1);
float ir1 = IRP_1.getSamples(50);
float ir4 = IRP_4.getSamples(50);
if((ir1 + ir4)/2 > ((IRP_1.sensorAvg+IRP_4.sensorAvg)/2)*0.4){
return;
}
//while((encoder0.getPulses() - initial0) <= (oneCellCountMomentum-200) && (encoder1.getPulses() - initial1) <= (oneCellCountMomentum-200)) {
//while( (ir1 + ir4)/2 < ((IRP_1.sensorAvg+IRP_4.sensorAvg)/2)*0.4 ){
while( ir1 < IRP_1.sensorAvg*0.7 || ir4 < IRP_4.sensorAvg*0.7 ){
//serial.printf("IRS= >: %f, %f \r\n", IRP_2.getSamples( 100 ), IRP_3.getSamples( 100 ));
count0 = encoder0.getPulses() - initial0;
count1 = encoder1.getPulses() - initial1;
int x = count0 - count1;
//double d = kp * x + kd * ( x - prev );
double kppart = kp * x;
double kdpart = kd * (x-prev);
double d = kppart + kdpart;
//serial.printf( "x: %d,\t prev: %d,\t d: %f,\t kppart: %f,\t kdpart: %f\n", x, prev, d, kppart, kdpart );
if( x < diff - 40 ) // count1 is bigger, right wheel pushed forward
{
left_motor.move( speed1-0.8*d );
right_motor.move( speed0+d );
}
else if( x > diff + 40 )
{
left_motor.move( speed1-0.8*d );
right_motor.move( speed0+d );
}
// else
// {
// left_motor.brake();
// right_motor.brake();
// }
prev = x;
ir1 = IRP_1.getSamples(50);
ir4 = IRP_4.getSamples(50);
}
//pidOnEncoders();
//pidBrake();
right_motor.brake();
left_motor.brake();
return;
}
void moveForwardUntilWallIr()
{
double currentError = 0;
double previousError = 0;
double derivError = 0;
double sumError = 0;
double HIGH_PWM_VOLTAGE = 0.1;
double rightSpeed = 0.25;
double leftSpeed = 0.23;
float ir2 = IRP_2.getSamples( SAMPLE_NUM );
float ir3 = IRP_3.getSamples( SAMPLE_NUM );
int count = encoder0.getPulses();
while ((IRP_1.getSamples( SAMPLE_NUM ) + IRP_4.getSamples( SAMPLE_NUM ) )/2 < 0.05f) { // while the front facing IR's arent covered
if((IRP_2.getSamples(SAMPLE_NUM) < 0.005 || IRP_3.getSamples(SAMPLE_NUM) < 0.005)) {
//moveForwardWallEncoder();
}else if(IRP_2.getSamples(SAMPLE_NUM) < 0.005){ // left wall gone
//moveForwardRightWall();
}else if(IRP_3.getSamples(SAMPLE_NUM) < 0.005){ // right wall gone
//moveForwardLeftWall();
}else{
// will move forward using encoders only
// if cell ahead doesn't have a wall on either one side or both sides
int pulseCount = (encoder0.getPulses()-count) % 5600;
if (pulseCount > 5400 && pulseCount < 5800) {
blueLed.write(0);
} else {
blueLed.write(1);
}
sumError += currentError;
currentError = ( (IRP_2.getSamples( SAMPLE_NUM ) - IRP_2.sensorAvg/initAverageL) ) - ( (IRP_3.getSamples( SAMPLE_NUM ) - IRP_3.sensorAvg/initAverageR) ) ;
derivError = currentError - previousError;
double PIDSum = IP_CONSTANT*currentError + II_CONSTANT*sumError + ID_CONSTANT*derivError;
if (PIDSum > 0) { // this means the leftWheel is faster than the right. So right speeds up, left slows down
rightSpeed = HIGH_PWM_VOLTAGE - abs(PIDSum*HIGH_PWM_VOLTAGE);
leftSpeed = HIGH_PWM_VOLTAGE + abs(PIDSum*HIGH_PWM_VOLTAGE);
} else { // r is faster than L. speed up l, slow down r
rightSpeed = HIGH_PWM_VOLTAGE + abs(PIDSum*HIGH_PWM_VOLTAGE);
leftSpeed = HIGH_PWM_VOLTAGE - abs(PIDSum*HIGH_PWM_VOLTAGE);
}
if (leftSpeed > 0.30) leftSpeed = 0.30;
if (leftSpeed < 0) leftSpeed = 0;
if (rightSpeed > 0.30) rightSpeed = 0.30;
if (rightSpeed < 0) rightSpeed = 0;
right_motor.forward(rightSpeed);
left_motor.forward(leftSpeed);
previousError = currentError;
ir2 = IRP_2.getSamples( SAMPLE_NUM );
ir3 = IRP_3.getSamples( SAMPLE_NUM );
}
//backward();
//wait_ms(40);
//brake();
left_motor.brake();
right_motor.brake();
}
}
void printDipFlag()
{
if (DEBUGGING) serial.printf("Flag value is %d", dipFlags);
}
void enableButton1()
{
dipFlags |= BUTTON1_FLAG;
printDipFlag();
}
void enableButton2()
{
dipFlags |= BUTTON2_FLAG;
printDipFlag();
}
void enableButton3()
{
dipFlags |= BUTTON3_FLAG;
printDipFlag();
}
void enableButton4()
{
dipFlags |= BUTTON4_FLAG;
printDipFlag();
}
void disableButton1()
{
dipFlags &= ~BUTTON1_FLAG;
printDipFlag();
}
void disableButton2()
{
dipFlags &= ~BUTTON2_FLAG;
printDipFlag();
}
void disableButton3()
{
dipFlags &= ~BUTTON3_FLAG;
printDipFlag();
}
void disableButton4()
{
dipFlags &= ~BUTTON4_FLAG;
printDipFlag();
}
void pidOnEncoders()
{
int count0;
int count1;
count0 = encoder0.getPulses();
count1 = encoder1.getPulses();
int diff = count0 - count1;
double kp = 0.00011;
double kd = 0.00014;
int prev = 0;
int counter = 0;
while(1)
{
count0 = encoder0.getPulses();
count1 = encoder1.getPulses();
int x = count0 - count1;
//double d = kp * x + kd * ( x - prev );
double kppart = kp * x;
double kdpart = kd * (x-prev);
double d = kppart + kdpart;
//serial.printf( "x: %d,\t prev: %d,\t d: %f,\t kppart: %f,\t kdpart: %f\n", x, prev, d, kppart, kdpart );
if( x < diff - 40 ) // count1 is bigger, right wheel pushed forward
{
left_motor.move( -d );
right_motor.move( d );
}
else if( x > diff + 40 )
{
left_motor.move( -d );
right_motor.move( d );
}
// else
// {
// left_motor.brake();
// right_motor.brake();
// }
prev = x;
counter++;
if (counter == 5)
break;
}
}
void nCellEncoderAndIR(double cellCount){
double currentError = 0;
double previousError = 0;
double derivError = 0;
double sumError = 0;
double HIGH_PWM_VOLTAGE = 0.1;
double rightSpeed = 0.10;
double leftSpeed = 0.10;
int desiredCount0 = encoder0.getPulses() + oneCellCountMomentum*cellCount;
int desiredCount1 = encoder1.getPulses() + oneCellCountMomentum*cellCount;
left_motor.forward(0.28);
right_motor.forward(0.25);
float receiverTwoReading = 0.0;
float receiverThreeReading = 0.0;
float ir2 = IRP_2.getSamples( SAMPLE_NUM );
float ir3 = IRP_3.getSamples( SAMPLE_NUM );
// float previr2 = ir2;
// float previr3 = ir3;
int state = 0;
while (encoder0.getPulses() <= desiredCount0 && encoder1.getPulses() <= desiredCount1 && receiverOneReading < IRP_1.sensorAvg*0.8 && receiverFourReading < IRP_4.sensorAvg*0.8){
receiverTwoReading = IRP_2.getSamples(100);
receiverThreeReading = IRP_3.getSamples(100);
// previr2 = receiverTwoReading;
// previr3 = receiverThreeReading;
receiverOneReading = IRP_1.getSamples(100);
receiverFourReading = IRP_4.getSamples(100);
//if ((receiverOneReading+receiverFourReading)/2 > ((IRP_1.sensorAvg+IRP_4.sensorAvg)/2)*0.15 ){
if( receiverOneReading > IRP_1.sensorAvg*0.7 || receiverFourReading > IRP_4.sensorAvg*0.7 ){
// almost to the end
right_motor.move(-0.15);
left_motor.move(-0.15);
wait_ms(150);
right_motor.brake();
left_motor.brake();
redLed.write(1);
greenLed.write(1);
blueLed.write(1);
wait_ms(200);
redLed.write(1);
greenLed.write(1);
blueLed.write(0);
wait_ms(200);
redLed.write(1);
greenLed.write(0);
blueLed.write(1);
wait_ms(200);
redLed.write(0);
greenLed.write(1);
blueLed.write(1);
//moveForwardWallEncoder();
return;
}else if((receiverThreeReading < 1.3*IRP_3.sensorAvg/(averageDivR)) && (receiverTwoReading < 1.3*IRP_2.sensorAvg/(averageDivL)) ){
// both sides gone
redLed.write(1);
greenLed.write(1);
blueLed.write(1);
wait_ms(100);
redLed.write(1);
greenLed.write(1);
blueLed.write(0);
wait_ms(200);
redLed.write(1);
greenLed.write(1);
blueLed.write(0);
wait_ms(200);
redLed.write(1);
greenLed.write(1);
blueLed.write(0);
wait_ms(200);
redLed.write(1);
greenLed.write(1);
blueLed.write(0);
moveForwardEncoder();
}else if (receiverThreeReading < IRP_3.sensorAvg/averageDivR){// right wall gone
// RED RED RED RED RED
state = 1;
redLed.write(0);
greenLed.write(1);
blueLed.write(1);
}else if (receiverTwoReading < IRP_2.sensorAvg/averageDivL){// left wall gone
// BLUE BLUE BLUE BLUE
state = 2;
redLed.write(1);
greenLed.write(1);
blueLed.write(0);
}else if ((receiverTwoReading > ((IRP_2.sensorAvg/initAverageL)*averageDivUpper)) && (receiverThreeReading > ((IRP_3.sensorAvg/initAverageR)*averageDivUpper))){
// both walls there
state = 0;
redLed.write(1);
greenLed.write(0);
blueLed.write(1);
}
switch(state){
case(0):{ // both walls there
currentError = ( receiverTwoReading - IRP_2.sensorAvg/initAverageL) - ( receiverThreeReading - IRP_3.sensorAvg/initAverageR);
break;
}
case(1):{// RED RED RED RED RED
currentError = (receiverTwoReading - IRP_2.sensorAvg/initAverageL) - (IRP_2.sensorAvg/initAverageL);
break;
}
case(2):{// blue
currentError = (IRP_3.sensorAvg/initAverageR) - (receiverThreeReading - IRP_3.sensorAvg/initAverageR);
break;
}
default:{
currentError = ( receiverTwoReading - IRP_2.sensorAvg/initAverageL) - ( receiverThreeReading - IRP_3.sensorAvg/initAverageR);
//currentError = ( receiverTwoReading - IRP_2.sensorAvg/initAverageL) - ( receiverThreeReading - IRP_3.sensorAvg/initAverageR);
break;
}
}
//currentError = ( receiverTwoReading - IRP_2.sensorAvg/initAverageL) - ( receiverThreeReading - IRP_3.sensorAvg/initAverageR);
sumError += currentError;
derivError = currentError - previousError;
double PIDSum = IP_CONSTANT*currentError + II_CONSTANT*sumError + ID_CONSTANT*derivError;
if (PIDSum > 0) { // this means the leftWheel is faster than the right. So right speeds up, left slows down
rightSpeed = HIGH_PWM_VOLTAGE - abs(PIDSum*HIGH_PWM_VOLTAGE);
leftSpeed = HIGH_PWM_VOLTAGE + abs(PIDSum*HIGH_PWM_VOLTAGE);
} else { // r is faster than L. speed up l, slow down r
rightSpeed = HIGH_PWM_VOLTAGE + abs(PIDSum*HIGH_PWM_VOLTAGE);
leftSpeed = HIGH_PWM_VOLTAGE - abs(PIDSum*HIGH_PWM_VOLTAGE);
}
if (leftSpeed > 0.30) leftSpeed = 0.30;
if (leftSpeed < 0) leftSpeed = 0;
if (rightSpeed > 0.30) rightSpeed = 0.30;
if (rightSpeed < 0) rightSpeed = 0;
right_motor.forward(rightSpeed);
left_motor.forward(leftSpeed);
pidOnEncoders();
previousError = currentError;
ir2 = IRP_2.getSamples( SAMPLE_NUM );
ir3 = IRP_3.getSamples( SAMPLE_NUM );
}
left_motor.brake();
right_motor.brake();
return;
}
int main()
{
//Set highest bandwidth.
//gyro.setLpBandwidth(LPFBW_42HZ);
serial.baud(9600);
//serial.printf("The gyro's address is %s", gyro.getWhoAmI());
wait (0.1);
redLed.write(1);
greenLed.write(0);
blueLed.write(1);
//left_motor.forward(0.1);
//right_motor.forward(0.1);
// PA_1 is A of right
// PA_0 is B of right
// PA_5 is A of left
// PB_3 is B of left
//QEI encoder0( PA_5, PB_3, NC, PULSES, QEI::X4_ENCODING );
// QEI encoder1( PA_1, PA_0, NC, PULSES, QEI::X4_ENCODING );
// TODO: Setting all the registers and what not for Quadrature Encoders
/* RCC->APB1ENR |= 0x1001; // Enable clock for Tim2 (Bit 0) and Tim5 (Bit 3)
RCC->AHB1ENR |= 0x11; // Enable GPIO port clock enables for Tim2(A) and Tim5(B)
GPIOA->AFR[0] |= 0x10; // Set GPIO alternate function modes for Tim2
GPIOB->AFR[0] |= 0x100; // Set GPIO alternate function modes for Tim5
*/
// set GPIO pins to alternate for the pins corresponding to A/B for eacah encoder, and 2 alternate function registers need to be selected for each type
// of alternate function specified
// 4 modes sets AHB1ENR
// Now TMR: enable clock with timer, APB1ENR
// set period, autoreload value, ARR value 2^32-1, CR1 - TMR resets itself, ARPE and EN
//
// Encoder mode: disable timer before changing timer to encoder
// CCMR1/2 1/2 depends on channel 1/2 or 3/4, depends on upper bits, depending which channels you use
// CCMR sets sample rate and set the channel to input
// CCER, which edge to trigger on, cannot be 11(not allowed for encoder mode), CCER for both channels
// SMCR - encoder mode
// CR1 reenabales
// then read CNT reg of timer
dipButton1.rise(&enableButton1);
dipButton2.rise(&enableButton2);
dipButton3.rise(&enableButton3);
dipButton4.rise(&enableButton4);
dipButton1.fall(&disableButton1);
dipButton2.fall(&disableButton2);
dipButton3.fall(&disableButton3);
dipButton4.fall(&disableButton4);
//right_motor.forward( 0.2 );
//left_motor.forward( 0.2 );
turnRight180();
wait_ms(1500);
while (1) {
//wait_ms(1500);
//turnRight();
//wait_ms(1500);
//turnLeft();
// float ir2 = IRP_2.getSamples(100);
// float ir3 = IRP_3.getSamples(100);
// float ir1 = IRP_1.getSamples(100);
// float ir4 = IRP_4.getSamples(100);
// if( ir1 > IRP_1.sensorAvg*0.3 || ir4 > IRP_4.sensorAvg*0.3 ){
// // almost to the end
// redLed.write(1);
// greenLed.write(1);
// blueLed.write(1);
// wait_ms(200);
// redLed.write(1);
// greenLed.write(1);
// blueLed.write(0);
// wait_ms(200);
// redLed.write(1);
// greenLed.write(0);
// blueLed.write(1);
// wait_ms(200);
// redLed.write(0);
// greenLed.write(1);
// blueLed.write(1);
// }else if((ir3 < IRP_3.sensorAvg/(averageDivR)) && (ir2 < IRP_2.sensorAvg/(averageDivL)) ){
// // both sides gone
// redLed.write(1);
// greenLed.write(1);
// blueLed.write(1);
// wait_ms(100);
// redLed.write(1);
// greenLed.write(1);
// blueLed.write(0);
// wait_ms(200);
// redLed.write(1);
// greenLed.write(1);
// blueLed.write(0);
// wait_ms(200);
// redLed.write(1);
// greenLed.write(1);
// blueLed.write(0);
// wait_ms(200);
// redLed.write(1);
// greenLed.write(1);
// blueLed.write(0);
// }else if (ir3 < IRP_3.sensorAvg/averageDivR){// right wall gone
// // RED RED RED RED RED
// redLed.write(0);
// greenLed.write(1);
// blueLed.write(1);
// }else if (ir2 < IRP_2.sensorAvg/averageDivL){// left wall gone
// // BLUE BLUE BLUE BLUE
// redLed.write(1);
// greenLed.write(1);
// blueLed.write(0);
// }else if ((ir2 > ((IRP_2.sensorAvg/initAverageL)*averageDivUpper)) && (ir3 > ((IRP_3.sensorAvg/initAverageR)*averageDivUpper))){
// // both walls there
// redLed.write(1);
// greenLed.write(0);
// blueLed.write(1);
// }
nCellEncoderAndIR(1);
wait_ms(1000);
// turnRight();
// wait_ms(500);
// nCellEncoderAndIR(1);
// wait_ms(500);
// turnRight();
// wait_ms(500);
// nCellEncoderAndIR(1);
// wait_ms(500);
// turnLeft();
// wait_ms(500);
// nCellEncoderAndIR(2);
// wait_ms(500);
// turnRight();
// wait_ms(500);
// nCellEncoderAndIR(1);
// wait_ms(500);
// turnRight();
// wait_ms(500);
// nCellEncoderAndIR(5);
// break;
// turnRight180();
// int number = rand() % 4 + 1;
// switch(number){
// case(1):{//turn right
// turnRight();
// break;
// }
// case(2):{ // turn left
// turnLeft();
// break;
// }
// case(3):{// keep going
// break;
// }
// case(4):{// turnaround
// turnRight180();
// break;
// }
// default:{// keep going
// break;
// }
// }
// float irbase2 = IRP_2.sensorAvg/initAverageL/averageDivL;
// float irbase3 = IRP_3.sensorAvg/initAverageR/averageDivR;
// float ir3 = IRP_2.getSamples(100)/initAverageL;
// float ir2 = IRP_3.getSamples(100)/initAverageR;
//serial.printf("%f, %f \n", IRP_1.sensorAvg, IRP_4.sensorAvg);
//serial.printf("%f, %f \n", IRP_2.sensorAvg, IRP_3.sensorAvg);
//break;
//serial.printf("IRS= >: %f, %f \r\n", IRP_2.getSamples(100), IRP_3.getSamples(100));
//serial.printf("IRS= >: %f, %f \r\n", IRP_1.getSamples(100), IRP_4.getSamples(100));
/*
counter2++;
counter3++;
ir2tot += IRP_2.getSamples(100);
ir3tot += IRP_3.getSamples(100);
ir2 = ir2tot/counter2;
ir3 = ir3tot/counter3;
serial.printf("IRS= >: %f, %f \r\n", ir2, ir3);
*/
//serial.printf("%f, %f \n", IRP_2.sensorAvg/initAverageL/averageDivL, IRP_3.sensorAvg/initAverageR/averageDivR);
//serial.printf("IRBASEnowall= >: %f, %f \r\n", irbase2, irbase3);
//break;
//serial.printf("IRS= >: %f, %f \r\n", IRP_2.getSamples(100), IRP_3.getSamples(100));
//serial.printf("IRSAvg= >: %f, %f \r\n", ir2, ir3);
//serial.printf("IRSAvg= >: %f, %f \r\n", IRP_2.sensorAvg, IRP_3.sensorAvg);
////////////////////////////////////////////////////////////////
//nCellEncoderAndIR(3);
//break;
//serial.printf("IRS= >: %f, %f, %f, %f \r\n", IRP_1.getSamples( 100 ), IRP_2.getSamples( 100 ), IRP_3.getSamples( 100 ), IRP_4.getSamples(100));
//serial.printf("IRS= >: %f, %f \r\n", IRP_2.getSamples( 100 ), IRP_3.getSamples( 100 ));
//break;
// moveForwardCellEncoder(1);
// wait(0.5);
// handleTurns();
// wait(0.5);
// moveForwardCellEncoder(1);
// wait(0.5);
// handleTurns();
//break;
//pidOnEncoders();
// moveForwardUntilWallIr();
//serial.printf("%i, %i, %i\n", gyro.getGyroX(), gyro.getGyroY(), gyro.getGyroZ());
//serial.printf("Pulse Count=> e0:%d, e1:%d \r\n", encoder0.getPulses(),encoder1.getPulses());
// double currentError = ( (IRP_2.getSamples( SAMPLE_NUM ) - IRP_2.sensorAvg) ) - ( (IRP_3.getSamples( SAMPLE_NUM ) - IRP_3.sensorAvg) ) ;
//serial.printf("IRS= >: %f, %f, %f, %f, %f \r\n", IRP_1.getSamples( 100 ), IRP_2.getSamples( 100 ), IRP_3.getSamples( 100 ), IRP_4.getSamples(100), currentError );
//reading = Rec_4.read();
// serial.printf("reading: %f\n", reading);
}
}