Robot's source code

Dependencies:   mbed

main.cpp

Committer:
sype
Date:
2015-04-16
Revision:
84:24d727006218
Parent:
82:3581a768f2db
Child:
85:8e95432d99d3

File content as of revision 84:24d727006218:

#include "mbed.h"

#define PLAN_B

//#define OUT_USB
#include "defines.h"

#include "QEI.h"
#include "Map.h"
#include "AX12.h"

#ifdef PLAN_A
    #include "Odometry.h"
    #include "Asserv.h"
#else
    #include "Odometry2.h"
    #include "planB.h"
#endif

#include "Motor.h"
/*----------------------------------------------------------------------------------------------*/
/*Serial*/    

//Serial logger(OUT_TX, OUT_RX); // tx, rx
Serial logger(USBTX,USBRX);
//logger.baud((int)115200);
/*----------------------------------------------------------------------------------------------*/

/* --- Initialisation de la liste des obstable --- */
int Obstacle::lastId = 0;

int main()
{
    logger.printf("Initialisation...\r\n");
    
    AX12 test(AX12_TX,AX12_RX,5,250000);
    test.setMode(0);
    
    /*while(1)
    {
        test.setMaxTorque(0x1FF);
        test.setGoal(0);
        logger.printf("0\r\n");
        wait(2);
        test.setMaxTorque(0x1FF);
        test.setGoal(90);
        logger.printf("180\r\n");
        wait(4);
    }*/
    
    PwmOut pw1(PWM_MOT1);
    DigitalOut dir1(DIR_MOT1);
    PwmOut pw2(PWM_MOT2);
    DigitalOut dir2(DIR_MOT2);
    
        
    Motor motorL(PWM_MOT1,DIR_MOT1);
    Motor motorR(PWM_MOT2,DIR_MOT2);    
    
    Timer t;
    
    //AX12 test(PA_9,NC,0x03,250000);
    
    AnalogIn ain0(PA_0);
    AnalogIn ain1(PA_1);
    AnalogIn ain2(PA_4);
    AnalogIn ain3(PB_0);
    AnalogIn ain4(PC_1);
    
    /*----------------------------------------------------------------------------------------------*/
    /*Odometry*/
    #ifdef PLAN_A
        QEI qei_right(PB_3,PA_10,NC,1024*4,QEI::X4_ENCODING);
        QEI qei_left(PB_4,PB_5,NC,1024*4,QEI::X4_ENCODING);
        
        Odometry odometry(&qei_left,&qei_right,63/2.,63/2.,255);
        odometry.setTheta(0);
        odometry.setX(0);
        odometry.setY(0);
    #else
        QEI qei_left(ODO_G_A,ODO_G_B,NC,1024*4,QEI::X4_ENCODING);
        QEI qei_right(ODO_D_A,ODO_D_B,NC,1024*4,QEI::X4_ENCODING);
        
        Odometry2 odometry(&qei_left,&qei_right,63/2.,63/2.,255);
        
        odometry.setTheta(PI/2);
        odometry.setX(0);
        odometry.setY(0);
    #endif
    
    DigitalOut led1(LED1);
    DigitalOut led2(LED2);
    DigitalOut led3(LED3);
    
    bool testOdo = false;
    
    #ifdef PLAN_A
        Asserv<float> instanceAsserv(&odometry);
        instanceAsserv.setGoal((float)0.0,(float)0.0,(float)PI/2);
        
        char state = 0;
        
        t.start();
        t.reset();
        
        while(!testOdo)
        {
            float dt = t.read();
            t.reset();
            
            odometry.update(dt);
            instanceAsserv.update(dt);
            float phi_r = (float)instanceAsserv.getPhiR();
            float phi_l = (float)instanceAsserv.getPhiL();
            float phi_max = (float)instanceAsserv.getPhiMax();
            
            motorR.setSpeed(0.08+(phi_r/phi_max));
            motorL.setSpeed(0.06+(phi_l/phi_max));
#ifdef test            
            if(state == 0 && instanceAsserv.isArrivedRho())
            {
                state = 1;
                logger.printf("Arrive en 0,0 !!!!!");
                wait(5);
                instanceAsserv.setGoal(200.0,200.0,0);
            }
            else if(state == 1 && instanceAsserv.isArrivedRho())
            {
                state = 2;
                logger.printf("Arrive en 200,200 !!!!!");
                wait(5);
                instanceAsserv.setGoal(0.0,200.0,0);
            }
            else if(state == 2 && instanceAsserv.isArrivedRho())
            {
                state = 0;
                logger.printf("Arrive en 0,200 !!!!!");
                wait(5);
                instanceAsserv.setGoal(0.0,0.0,0);
            }
#endif
        }
    #else
        aserv_planB asserv(odometry,motorL,motorR);
        asserv.setGoal(-1,0,0);
        
        t.start();
        t.reset();
        
        while(!testOdo)
        {
            //Parametrage des coef par bluetooth
            /*while(logger.readable())
            {
                char c = logger.getc();
                if(c=='a') asserv.Kd += 0.001;
                else if(c=='z') asserv.Kd -= 0.001;
                logger.printf("%f\n\r",asserv.Kd);
            }*/
            
            //Asservissement :
            float dt = t.read();
            t.reset();
            odometry.update(dt);
            asserv.update(dt);
            wait_ms(10);            
        }
    #endif
}