No.9 Robotics / Mbed 2 deprecated Robotics_DCMotor

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Dependencies:   mbed

Fork of Robotics_Lab_DCMotor by LDSC_Robotics

main.cpp

Committer:
ChangYuHsuan
Date:
2016-04-14
Revision:
6:da43b63ffb24
Parent:
5:ff3b5f31a9ce
Child:
9:85cbef9febe7
Child:
10:7954ec17021d

File content as of revision 6:da43b63ffb24:

/*DCMotor*/
#include "mbed.h"

//The number will be compiled as type "double" in default
//Add a "f" after the number can make it compiled as type "float"
#define Ts 0.01f    //period of timer1 (s)
#define Kp 0.05f
#define Ki 0.001f

Serial bluetooth(D10,D2); //宣告藍牙腳位

PwmOut pwm1(D7);
PwmOut pwm1n(D11);
PwmOut pwm2(D8);
PwmOut pwm2n(A3);

DigitalOut led1(A4);
DigitalOut led2(A5);

//Motor1 sensor
InterruptIn HallA_1(A1);
InterruptIn HallB_1(A2);
//Motor2 sensor
InterruptIn HallA_2(D13);
InterruptIn HallB_2(D12);


Ticker timer1;
void timer1_interrupt(void);
int  timer1_counter;

void CN_interrupt(void);

void init_TIMER(void);
void init_PWM(void);
void init_CN(void);
void init_BLUETOOTH(void);

char speedCmd;

int8_t stateA_1=0, stateB_1=0, stateA_2=0, stateB_2=0;
int8_t state_1 = 0, state_1_old = 0, state_2 = 0, state_2_old = 0;

int v1Count = 0;
int v2Count = 0;

float v1 = 0.0, v1_ref = 0.0;
float v1_err = 0.0, v1_ierr = 0.0, PIout_1 = 0.0, PIout_1_old = 0.0;
float v2 = 0.0, v2_ref = 0.0;
float v2_err = 0.0, v2_ierr = 0.0, PIout_2 = 0.0, PIout_2_old = 0.0;

int main() {
    
    init_BLUETOOTH();
    init_TIMER();
    init_PWM();
    init_CN();
    
    v1_ref = 0.0;
    v2_ref = 0.0;
    
    while(1) 
    {
        if(bluetooth.readable())
        {
           speedCmd = bluetooth.getc();
            
            if (speedCmd == 'a')
            { 
                v1_ref = v1_ref + 10;
                v2_ref = v2_ref + 10;
            }
            else if (speedCmd == 's')
            {
                v1_ref = v1_ref - 10;
                v2_ref = v2_ref - 10;
            }
            else if (speedCmd == 'q')
            {
                v1_ref = v1_ref + 20;
                v2_ref = v2_ref + 20;
            }
            else if (speedCmd == 'w')
            {
                v1_ref = v1_ref - 20;
                v2_ref = v2_ref - 20;
            }
            
            if (v1_ref < -100)
                v1_ref = -100;
            else if (v1_ref > 100)
                v1_ref = 100;
                
            if (v2_ref < -100)
                v2_ref = -100;
            else if (v2_ref > 100)
                v2_ref = 100;
        }
    }
}

void timer1_interrupt(void)
{
    //Motor 1
    v1 = (float)v1Count * 100.0f / 12.0f * 60.0f / 29.0f;   //unit: rpm
    v1Count = 0;
    
    ///code for PI control///
    v1_err = v1_ref - v1;
    v1_ierr += v1_err;
    PIout_1 = Kp * v1_err + Ki * Ts * (v1_ierr - v1_err);
    
    // saturation
    if(PIout_1 >= 0.5f)PIout_1 = 0.5f;
    else if(PIout_1 <= -0.5f)PIout_1 = -0.5f;
    pwm1.write(PIout_1 + 0.5f);
    TIM1->CCER |= 0x4;
    
    PIout_1_old = PIout_1;
    
    //Motor 2
    v2 = (float)v2Count * 100.0f / 12.0f * 60.0f / 29.0f;   //unit: rpm
    v2Count = 0;
    
    ///code for PI control///
    v2_err = v2_ref - v2;
    v2_ierr += v2_err;
    PIout_2 = Kp * v2_err + Ki * Ts * (v2_ierr - v2_err);
    
    //saturation
    if(PIout_2 >= 0.5f)PIout_2 = 0.5f;
    else if(PIout_2 <= -0.5f)PIout_2 = -0.5f;
    pwm2.write(PIout_2 + 0.5f);
    TIM1->CCER |= 0x40;
    
    PIout_2_old = PIout_2;
    
    timer1_counter ++;
    if (timer1_counter == 5)
    {
       timer1_counter = 0;
       if(bluetooth.writeable())
       {
           bluetooth.printf("V1: %f  V2: %f\n",v1,v2);
       }
    }
}

void CN_interrupt(void)
{
    //Motor 1
    stateA_1 = HallA_1.read();
    stateB_1 = HallB_1.read();
    
    ///code for state determination///
    if (stateA_1 == 0)
    {
        if (stateB_1 == 0)
            state_1 = 0;
        else
            state_1 = 1;
    }
    else
    {
        if (stateB_1 == 1)
            state_1 = 2;
        else
            state_1 = 3;
    }
    
    //Forward: v1Count +1
    //Inverse: v1Count -1
    if ( (state_1 == (state_1_old + 1)) || (state_1 == (state_1_old - 3)) )
        v1Count++;
    else if ( (state_1 == (state_1_old - 1)) || (state_1  == (state_1_old + 3)))
        v1Count--;
            
    state_1_old = state_1;
    
    //Motor 2
    stateA_2 = HallA_2.read();
    stateB_2 = HallB_2.read();
    
    ///code for state determination///
    if (stateA_2 == 0)
    {
        if (stateB_2 == 0)
            state_2 = 0;
        else
            state_2 = 1;
    }
    else
    {
        if (stateB_2 == 1)
            state_2 = 2;
        else
            state_2 = 3;
    }
    
    //Forward: v2Count +1
    //Inverse: v2Count -1
    if ( (state_2 == (state_2_old + 1)) || (state_2 == (state_2_old - 3)) )
        v2Count++;
    else if ( (state_2 == (state_2_old - 1)) || (state_2  == (state_2_old + 3)))
        v2Count--;
}

void init_TIMER(void)
{
    timer1.attach_us(&timer1_interrupt, 10000);//10ms interrupt period (100 Hz)
    timer1_counter = 0;
}         
   
void init_PWM(void)
{
    pwm1.period_us(50);
    pwm1.write(0.5);
    TIM1->CCER |= 0x4;
    
    pwm2.period_us(50);
    pwm2.write(0.5);
    TIM1->CCER |= 0x40;
}

void init_CN(void)
{
    HallA_1.rise(&CN_interrupt);
    HallA_1.fall(&CN_interrupt);
    HallB_1.rise(&CN_interrupt);
    HallB_1.fall(&CN_interrupt);
    
    HallA_2.rise(&CN_interrupt);
    HallA_2.fall(&CN_interrupt);
    HallB_2.rise(&CN_interrupt);
    HallB_2.fall(&CN_interrupt);
    
    stateA_1 = HallA_1.read();
    stateB_1 = HallB_1.read();
    stateA_2 = HallA_2.read();
    stateB_2 = HallB_2.read();
}

void init_BLUETOOTH(void)
{
    bluetooth.baud(115200);
}