Micromouse 18
Scaled IR readings by 10^5 so also changed thresholds. Implemented and tested LED multiplexing Working on a new turning scheme involving IR readings
Dependencies: QEI RemoteIR mbed
Fork of
encoder_v2
by 
Micromouse 18
PID_control.cpp
- Committer:
- mbshark
- Date:
- 2017-12-01
- Revision:
- 11:e647b14ff4ef
- Parent:
- 10:707e542688dc
- Child:
- 12:e44dd0d4f1ee
File content as of revision 11:e647b14ff4ef:
//added routines to main for easier testing of movement functions
//wrote testStop();
//Kevin Lee Nov 30, 2017
//edited testStop();
//started a testTurns();
//testTurns not working as thought
//Myles Byrne Nov 30, 2017
//TODO: test quarterTurnLeft(); , quarterTurnRight(); for delay constants
//TODO: finetune PID , Multiplexing for IR LEDS ,
//SUGGESTIONS: implement turn functions using encoders. i.e. each pulse represents 1 degree, need difference of 90 pulses for right turn
#include "mbed.h"
#include "QEI.h"
QEI encoder_Right(PB_3, PA_15, NC, 360, QEI::X4_ENCODING);
QEI encoder_Left(PA_1, PC_4, NC, 360, QEI::X4_ENCODING);
double Kp = 0.27;//.005;
double Ki = 0.001;//0.0000001;
double Kd = 0.001;
PwmOut m_Right_F(PB_10);
PwmOut m_Right_B(PC_7);
PwmOut m_Left_F(PA_7);
PwmOut m_Left_B(PB_6);
double i_speed = 0.15;
double C_speed(0);
int integrator = 0;
int decayFactor = 1;
double Error = 0;
double IRError = 0; //added
double prevError = 0;
Serial pc (PA_2, PA_3); //serial comm enabled on pins pa_2 and pa_3
Timer timer;
int counter = 0;
float threshold = 0.00085;
float turnThreshold = 0.0004;
//IRR = IR Reciver
AnalogIn RS_IRR(PA_0); //Right Side
AnalogIn RF_IRR(PA_4); //Right Front
AnalogIn LF_IRR(PC_1); //Left Front
AnalogIn LS_IRR(PC_0); //Left Side
//IRE = IR Emitter
DigitalOut RS_IRE(PC_10); //Right Side
DigitalOut RF_IRE(PC_11); //Right Front
DigitalOut LF_IRE(PB_0); //Left Front
DigitalOut LS_IRE(PB_7); //Left Side
double P_controller(int error)
{
double correction = (Kp*error);
return correction;
}
double I_controller(int error)
{
integrator += error;
double correction = Ki*integrator;
integrator /= decayFactor;
return correction;
}
double D_controller(int error)
{
int dError = error - prevError;
int dt = timer.read_us();
timer.reset();
prevError = error;
double correction;
if (dt==0)
correction=0;
else
correction = Kd*dError/dt;
return correction;
}
Ticker systicker;
//speed = speed + P_Controller(error) + I_Controller(error) + D_Controller(error);
void systick()
{
double R_en_count = encoder_Right.getPulses()/100;
double L_en_count = encoder_Left.getPulses()/100;
Error = R_en_count - L_en_count;
double ex = D_controller(Error);
C_speed = P_controller(Error) + I_controller(Error) + ex;
if (C_speed < 0)
C_speed = C_speed*-1;
float Front_IRError = RF_IRR.read() + LF_IRR.read(); //rev1
float Side_IRError = RS_IRR.read() - LS_IRR.read(); //rev1,define side_error as positive if closer to right
}
void forward()
{
double f1_speed = i_speed + C_speed;
double f2_speed = i_speed - C_speed;
/*pc.printf("C: %f", C_speed);
if (C_speed < 0)
pc.printf("-");
if (C_speed > 0)
pc.printf("+");
*/
if(f1_speed >= 0.7) { //upper bound, can not go faster
f1_speed = 0.7;
}
if (f1_speed <= 0.05)
f1_speed = 0.05;
if(f2_speed <= 0.05) { //lower bound, should not be slower than this
f2_speed = 0.05;
}
pc.printf(" f1: %f", f1_speed);
pc.printf(" f2: %f", f2_speed);
//problems when left wheel is held for the + case
if (Error > 0) { //right wheel is turning more
m_Left_F.write(f1_speed);
m_Right_F.write(f2_speed); //f2_speed
}
if (Error < 0) { //left wheel is turning more
m_Right_F.write(f1_speed);
m_Left_F.write(f2_speed); //f2_speed
}
if (Error == 0) {
m_Right_F.write(i_speed);
m_Left_F.write(i_speed);
}
}
void forwardSlow()
{
float iS_speed = 0.05;
double f1_speed = iS_speed + C_speed;
double f2_speed = iS_speed - C_speed;
/*pc.printf("C: %f", C_speed);
if (C_speed < 0)
pc.printf("-");
if (C_speed > 0)
pc.printf("+");
*/
if(f1_speed >= 0.15) { //upper bound, can not go faster
f1_speed = 0.15;
}
if (f1_speed <= 0.05)
f1_speed = 0.05;
if(f2_speed <= 0.05) { //lower bound, should not be slower than this
f2_speed = 0.05;
}
pc.printf(" f1: %f", f1_speed);
pc.printf(" f2: %f", f2_speed);
//problems when left wheel is held for the + case
if (Error > 0) { //right wheel is turning more
m_Left_F.write(f1_speed);
m_Right_F.write(f2_speed); //f2_speed
}
if (Error < 0) { //left wheel is turning more
m_Right_F.write(f1_speed);
m_Left_F.write(f2_speed); //f2_speed
}
if (Error == 0) {
m_Right_F.write(iS_speed);
m_Left_F.write(iS_speed);
}
}
void backUp()
{
m_Left_F.write(0);
m_Right_F.write(0);
m_Left_B.write(i_speed);
m_Right_B.write(i_speed);
wait(.15);
}
void turnRight()
{
m_Left_B.write(0);
m_Right_F.write(0);
m_Left_F.write(i_speed);
m_Right_B.write(i_speed);
wait(.2);
}
void quarterTurnRight() //rev1, for ladders
{
m_Left_B.write(0);
m_Right_F.write(0);
m_Left_F.write(i_speed);
m_Right_B.write(i_speed);
wait(.1); //delay needs testing
}
void turnLeft()
{
m_Left_F.write(0);
m_Right_B.write(0);
m_Right_F.write(i_speed);
m_Left_B.write(i_speed);
wait(.2); //this is dependent on i_speed, can we write a function that varies with i_speed?
}
void quarterTurnLeft() { //rev1, for ladders
m_Left_F.write(0);
m_Right_B.write(0);
m_Right_F.write(i_speed);
m_Left_B.write(i_speed);
wait(.1); //time needs testing
}
void turnAround()
{
m_Left_B.write(0);
m_Right_F.write(0);
m_Left_F.write(i_speed);
m_Right_B.write(i_speed);
wait(.4);
}
void stop()
{
m_Right_F.write(0);
m_Right_B.write(0);
m_Left_F.write(0);
m_Left_B.write(0);
}
void debugEncoder()
{
while(1) {
wait(1);
pc.printf("Right: %i", encoder_Right.getPulses());
pc.printf(" Left: %i", encoder_Left.getPulses(), "\n");
pc.printf("\n");
}
}
void debugError()
{
while(1) {
pc.printf("Error: %i\n", Error);
}
}
/*void main1() {
printf("\nAnalogIn example\n");
LF_IRE.write(1);
RF_IRE.write(1);
while (1){
while (LF_IRR.read() < threshold && RF_IRR.read() < threshold){
forward();
float value1 = LF_IRR.read();
float value2 = RF_IRR.read();
printf("LF Led: %f\n", value1);
wait(0.5);
printf("RF Led: %f\n", value2);
}
backUp();
LS_IRE.write(1);
RS_IRE.write(1);
if (LS_IRR.read() > turnThreshold) {
if (RS_IRR.read() < turnThreshold)
turnRight();
else
turnAround();
}
else if (RS_IRR.read() > turnThreshold) {
if (LS_IRR.read() < turnThreshold)
turnRight();
else
turnAround();
}
else
turnAround();
LS_IRE.write(0);
RS_IRE.write(0);
}
stop();
}
*/
void testStop() //rev1
{
//printf("\nAnalogIn example\n");
LF_IRE.write(1);
RF_IRE.write(1);
forward();
while(1) {
if (RF_IRR.read() > turnThreshold && LF_IRR.read() > turnThreshold)
{
stop();
forwardSlow();
if (RF_IRR.read() > threshold && LF_IRR.read() > threshold)
{
stop();
break;
}
}
float value1 = LF_IRR.read();
float value2 = RF_IRR.read();
printf("LF Led: %f\n", value1);
wait(0.25);
printf("RF Led: %f\n\r", value2);
}
}
void testTurnAround() //rev1
{
}
void testTurns()
{
LF_IRE.write(1);
RF_IRE.write(1);
forward();
while(1)
{
if (RF_IRR.read() > turnThreshold && LF_IRR.read() > turnThreshold)
{
stop();
forwardSlow();
if (RF_IRR.read() > threshold && LF_IRR.read() > threshold)
{
stop();
if (LS_IRR.read() > turnThreshold) {
if (RS_IRR.read() < turnThreshold)
turnRight();
else
turnAround();
}
else if (RS_IRR.read() > turnThreshold) {
if (LS_IRR.read() < turnThreshold)
turnLeft();
else
turnAround();
}
else
turnAround();
LS_IRE.write(0);
RS_IRE.write(0);
}
//stop();
break;
}
}
float value1 = LF_IRR.read();
float value2 = RF_IRR.read();
printf("LF Led: %f\n", value1);
wait(0.25);
printf("RF Led: %f\n\r", value2);
}
int main()
{
systicker.attach_us(&systick, 1000); //rev1
testStop();
}
/*while(RF_IRR.read() * 100000 < 175 && LF_IRR.read() * 100000 < 175) {
/*meas = LS_IRR.read(); // Converts and read the analog input value (value from 0.0 to 1.0)
meas = meas * 100000; // Change the value to be in the 0 to 3300 range
printf("measure = %.0f mV\n", meas);
*/
/*if (meas > 2000) { // If the value is greater than 2V then switch the LED on
LS_IRE = 1;
}
else {
LS_IRE = 0;
}
*/
/*
forward();
//wait(0.2); // 200 ms
}
stop();
*/
/*int main() //only runs once
{
systicker.attach_us(&systick, 1000); //enable interrupt
while (1) {
forward();
}
//
//debugEncoder();
}
*/