Kiyoteru Hayama
mbed robotracer for education.
Robotracer (line follower robot ) using stepper motor.
/media/uploads/hayama/mbedrobotracer-manual-english.pdf
/media/uploads/hayama/mbedrobotracer-manual-japanese.pdf
/media/uploads/hayama/eagle-design-robotracer.zip
movie -> https://www.youtube.com/watch?v=INwun8gSds4
(for competition->) https://www.youtube.com/watch?v=l_gP2pUt4w0
main.cpp
- Committer:
- hayama
- Date:
- 2013-10-02
- Revision:
- 1:200aad416161
- Parent:
- 0:da22b0b4395a
File content as of revision 1:200aad416161:
//**************************************************************************
//
// mbed Robotracer for education
// (c) Kiyoteru Hayama(Kumamoto National College of Technology)
//
//**************************************************************************
#include "mbed.h"
Serial pc(USBTX, USBRX);
// run parameters
#define STH 0.5 // threshold value for digital photo sensor
#define SGTH 10 // threshold value for start/goal marker
#define CTH 10 // threshold value for corner marker
// pattern table for stepping motor
const unsigned char RMOTOR[]={0x09, 0x0C, 0x06, 0x03, 0x00}; // magnetization pattern for left motor
const unsigned char LMOTOR[]={0x03, 0x06, 0x0C, 0x09, 0x00}; // magnetization pattern for right motor
const int sensArray[64]={0,5,3,4,1,0,2,0,-1,0,0,0,0,0,0,0,-3,0,0,0,0,0,0,0,-2,0,0,0,0,0,0,0,-5,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,-4,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0};
unsigned char pmode=0; // program mode
volatile float pt1B, pt2B, pt3B, pt4B, pt5B, pt6B, ptSGB, ptCB; // sensor values during turn-off the LED
volatile float sens1, sens2, sens3, sens4, sens5, sens6, sensSG, sensC; // sensor values
volatile int sensD,sensDout=0;
volatile int markerSG, markerC, markerX;
unsigned char frun, fmarker;
volatile int spdR,spdL;
volatile unsigned char modeR=0, modeL=0; // run forward both motor
volatile int stepR, stepL; // varilable for set step of motor
volatile unsigned char patR=0, patL=0; // index of motor pattern
volatile int cntR, cntL; // count of motor steps
volatile unsigned char timR=0, timL=0; // timer for motors
volatile unsigned char timS=0; // timer for sensors
volatile int bp=0; // couter for beep
Ticker timerS; // defince interval timer
Ticker timerM; // defince interval timer
BusOut leds( LED4, LED3, LED2, LED1 ); // for LED display
BusOut motorR(p5, p6, p7, p8 ); // output for right motor
BusOut motorL(p11, p12, p13, p14 ); // output for left motor
AnalogIn pt12(p19); // front right sensor, analog input
AnalogIn pt34(p18); // front left sensor, analog input
AnalogIn pt56(p17); // right sensor, analog input
AnalogIn ptC(p20); // left sensor, analog input
AnalogIn ptSG(p16); // left sensor, analog input
AnalogIn gyro(p15); // for Gyro, analog input, reserved
DigitalIn setSw(p21); // set-switch, digital input
DigitalIn startSw(p22); // start-switch, digital input
DigitalOut ledCout(p9); // LED output signal for corner marker
DigitalOut ledSGout(p10); // LED output signal for start/goal marker
DigitalOut buzzer(p23); // buzzer out
//--------------------------------------------------------------------------
// interrupt by us timerS
//--------------------------------------------------------------------------
void Sensor() {
// read sensors
// 1st-step:measure background during LED-off, 2nd-step: measure reflecting light during LED-on. sensor value is differnce of both.
timS = !timS;
if (timS==0){
pt1B=pt12; // measure all background values
pt3B=pt34;
pt5B=pt56;
ptSGB=ptSG;
ledSGout=1; // LED-ON
wait_us(50); // delay
sens1=abs(pt12-pt1B); //"sabunn"
sens3=abs(pt34-pt3B);
sens5=abs(pt56-pt5B);
sensSG=abs(ptSG-ptSGB);
ledSGout=0; // LED-OFF
} else{
pt2B=pt12; // measure all background values
pt4B=pt34;
pt6B=pt56;
ptCB=ptC;
ledCout=1; // LED-ON
wait_us(50); // delay
sens2=abs(pt12-pt2B);
sens4=abs(pt34-pt4B);
sens6=abs(pt56-pt6B);
sensC=abs(ptC-ptCB);
ledCout=0; // LED-OFF
}
sensD=0;
if (sens1>STH ) sensD |= 0x20; else sensD &= ~(0x20);
if (sens2>STH ) sensD |= 0x10; else sensD &= ~(0x10);
if (sens3>STH ) sensD |= 0x08; else sensD &= ~(0x08);
if (sens4>STH ) sensD |= 0x04; else sensD &= ~(0x04);
if (sens5>STH ) sensD |= 0x02; else sensD &= ~(0x02);
if (sens6>STH ) sensD |= 0x01; else sensD &= ~(0x01);
sensDout=sensArray[sensD];
// corner and start/goal marker detection
if (sensSG>STH) markerSG++; else if (markerSG>0) markerSG--;
if (sensC>STH ) markerC++; else if (markerC>0) markerC--;
// cross line detection
if (markerSG>1 && markerC>1) markerX=1; // both marker
if (markerX==1 && markerSG==0 && markerC==0) markerX=0; // ignore cross line
// buzzer
if (bp>0){ // high beep
bp--;
if (buzzer==1) buzzer=0; else buzzer=1; // alternate ON-OFF
}
}
//--------------------------------------------------------------------------
// interrupt by us timerR/L
// motor rotation, mode = 0: free,1: forward,2: reverse,3: break
// right motor rotation
//--------------------------------------------------------------------------
void stepMotor(){
if (timR>0) timR--; //count down timR,when timR=0 do next process
if (timR==0) {
timR=spdR;
if (modeR==1) {if (patR < 3) patR++; else patR = 0; }
if (modeR==2) {if (patR > 0) patR--; else patR = 3; }
cntR++; // count up right moter step
}
// left motor rotation
if (timL>0) timL--; //count down timL,when timL=0 do next process
if (timL==0) {
timL=spdL;
//modeL==1;
if (modeL==1) {if (patL < 3) patL++; else patL = 0; }
if (modeL==2) {if (patL > 0) patL--; else patL = 3; }
cntL++; // count up left moter step
}
if (modeR==0 || modeL==0) { patR=4; patL=4; } // motor free when mode=0
motorR= RMOTOR[patR]; // pattern output to right motor
motorL= LMOTOR[patL]; // pattern output to left motor
}
// -----------------------------------------------
// beep
// -----------------------------------------------
void beep(int n){
bp=n; // set beep couter
}
//--------------------------------------------------------------------------
// check sensors
//--------------------------------------------------------------------------
void check_sens(){ // serial output of sensor level
while (1){
pc.printf("sensC :"); pc.printf("%f\n",sensC); //
pc.printf("sensSG :"); pc.printf("%f\n",sensSG); //
pc.printf("sens1 :"); pc.printf("%f\n",sens1); //
pc.printf("sens2 :"); pc.printf("%f\n",sens2); //
pc.printf("sens3 :"); pc.printf("%f\n",sens3); //
pc.printf("sens4 :"); pc.printf("%f\n",sens4); //
pc.printf("sens5 :"); pc.printf("%f\n",sens5); //
pc.printf("sens6 :"); pc.printf("%f\n",sens6); //
pc.printf("sensD :"); pc.printf("%d\n",sensD);
pc.printf("sensDout :"); pc.printf("%d\n",sensDout);
wait (0.5);
}
}
void check_sens_level(){ // leds output of sensor level
int i=0;
while (1){
if (setSw==0) {
wait(0.01);
beep(50);
while (setSw==0);
wait(0.01);
i++; if (i>7) i=0;
}
if (i==0){leds=(int)(sens1*10); pc.printf("sens1 x 10="); pc.printf("%d\n",(int)(sens1*10)); }
if (i==1){leds=(int)(sens2*10); pc.printf("sens2 x 10="); pc.printf("%d\n",(int)(sens2*10)); }
if (i==2){leds=(int)(sens3*10); pc.printf("sens3 x 10="); pc.printf("%d\n",(int)(sens3*10)); }
if (i==3){leds=(int)(sens4*10); pc.printf("sens4 x 10="); pc.printf("%d\n",(int)(sens4*10)); }
if (i==4){leds=(int)(sens5*10); pc.printf("sens5 x 10="); pc.printf("%d\n",(int)(sens5*10)); }
if (i==5){leds=(int)(sens6*10); pc.printf("sens6 x 10="); pc.printf("%d\n",(int)(sens6*10)); }
if (i==6){leds=(int)(sensC*10); pc.printf("sensC x 10="); pc.printf("%d\n",(int)(sensC*10)); }
if (i==7){leds=(int)(sensSG*10); pc.printf("sensSG x 10="); pc.printf("%d\n",(int)(sensSG*10)); }
wait (0.1);
}
}
void check_pos(){ // leds output of line position
while (1){
leds=sensDout;
wait (0.1);
}
}
//--------------------------------------------------------------------------
// break and release motors
//--------------------------------------------------------------------------
void run_release(){
modeR=0; modeL=0; // motor release
}
void run_break(){
modeR=3; modeL=3; // mode 0 means break the motor
wait(0.5);
run_release();
}
//--------------------------------------------------------------------------
// run and turn
// (mR,mL)=(1,1):forward, (2,1): turn right, (1,2): turn left, (2,2): Reverse
// spd: speed,
// nstep: number of step
//--------------------------------------------------------------------------
void runTurn(int mR,int mL, int spd, int nstep ){
modeR=mR;modeL=mL;
spdR=spdL=spd;
cntR=0; stepR=nstep;
while (cntR<stepR);
}
//-----------------------
// run
// n: run speed, m: factor of reduce speed
//----------------------
void run(int n, int m){
int cntGoal=0; // couter for run after goal
markerSG=0; markerC=0; markerX=0; fmarker=0;
frun=0;
runTurn(1,1,n*2,50); // slow start
while(startSw==1 ){
spdR=spdL=n;
if (sensDout>0){
spdR+=sensDout*m;
} else {
spdL-=sensDout*m;
}
// corner marker check
if (markerX==1) fmarker=0;
if (markerX==0 && fmarker==0 && markerC>5) fmarker=1;
if (markerX==0 && fmarker==1 && markerC==0){
fmarker=0; beep(50);
}
// start/goal marker check
if (frun==0 && markerSG>SGTH) frun=1; // start marker detect
if (frun==1 && markerSG==0){ // start marker fix
frun=2; beep(100);
}
if (frun==2 && markerSG>SGTH) frun=3; // goal marker detect
if (frun==3 && markerX==1) frun=2; // ignor cross line
if (frun==3 && markerSG==0){ // goal marker fix
frun=4; beep(100);
cntGoal=cntR;
}
if (frun==4 && cntR>(cntGoal+500)) break;
wait(0.005); // wait 5ms for control loop
}
run_break();
}
//--------------------------------------------------------------------------
// main
//--------------------------------------------------------------------------
int main(){
timerS.attach_us(&Sensor, 2000); // set timer for sensor
timerM.attach_us(&stepMotor, 400); // set timer for motor
while (1) {
// initialize motor
run_release();
while (startSw==1) { // program mode selection
if (setSw==0) {
wait(0.01);
beep(50);
while (setSw==0);
wait(0.01);
pmode++;
if (pmode>7) pmode=0;
}
leds=pmode;
}
leds=0; beep(50);
wait(0.5);
// go selected program
switch(pmode){
case 0: check_sens_level(); break; // check sensors by leds
//case 0: check_sens(); break; // check sensors by serial output
//case 0: check_pos(); break; // check line position
case 1: runTurn(1,1,15,500); break; // run forward
case 2: runTurn(2,1,15,500); break; // turn right
case 3: run(10,30); break; // trace run
case 4: run(8,24); break;
case 5: run(6,18); break;
case 6: run(5,15); break;
case 7: run(4,12); break;
}
}
}