Bryan Purba
convert_KeilToMbed
Dependencies: DigitDisplay Motor PID mbed millis
Fork of
DagonFly__RoadToJapan_15Mei_Ultimate
by 
KRAI 2017
main.cpp
- Committer:
- Sufa
- Date:
- 2017-02-12
- Revision:
- 29:7b372b0aaa61
- Parent:
- 28:2d0746dc2d7d
- Child:
- 30:d69cc27ac644
File content as of revision 29:7b372b0aaa61:
/****************************************************************************/
/* PROGRAM UNTUK PID CLOSED LOOP */
/* */
/* - Digunakan encoder autonics */
/* - Konfigurasi Motor dan Encoder sbb : */
/* ______________________ */
/* / \ Rode Depan Belakang: */
/* / 2 (Belakang) \ Omniwheel */
/* | | */
/* | 3 (Encoder) 4 | Roda Kiri Kanan: */
/* | | Fixed Wheel */
/* \ 1 (Depan) / */
/* \______________________/ Putaran berlawanan arah */
/* jarum jam positif */
/* SETTINGS (WAJIB!) : */
/* 1. Settings Pin Encoder, Resolusi, dan Tipe encoding di omniPos.h */
/* 2. Deklarasi penggunaan library omniPos pada bagian deklarasi encoder */
/* */
/****************************************************************************/
/* */
/* Joystick */
/* Kanan => Posisi target x ditambah 'perpindahan' */
/* Kiri => Posisi target x dikurang 'perpindahan' */
/* */
/* Tombol silang => Kembali keposisi Awal */
/* Tombol segitiga => Aktif motor Launcher */
/* Tombol lingkaran=> Aktif servo Launcher */
/* Tombol L1 => Pivot Kiri */
/* Tombol R1 => Pivot Kanan */
/* Tombol L3 => PWM Motor Belakang Dikurangi */
/* Tombol R3 => PWM Motor Belakang Ditambah */
/* Tombol L2 => PWM Motor Depan Dikurangi */
/* Tombol R2 => PWM Motor Depan Ditambah */
/* */
/* Bismillahirahmanirrahim */
/* Jagalah Kebersihan Kodingan */
/****************************************************************************/
#include "mbed.h"
#include "JoystickPS3.h"
#include "Motor.h"
#include "Servo.h"
#include "encoderKRAI.h"
#include "millis.h"
/***********************************************/
/* Konstanta dan Variabel */
/***********************************************/
#define PI 3.14159265
#define D_ENCODER 10 // Diameter Roda Encoder
#define D_ROBOT 80 // Diameter Roda Robot
#define VMAX 0.3 // Kiri Kanan
#define PIVOT 0.4 // Pivka, Pivki
#define PERPINDAHAN 1 // Perpindahan ke kanan dan kiri
// Variable Atas
double speed,speed2, maxSpeed = 0.8, minSpeed = 0;
double kpA=0.6757, kdA=0.6757, kiA=0.00006757;
double p,i,d;
double p2,i2,d2;
double last_error = 0, current_error, sum_error = 0;
double last_error2 = 0, current_error2, sum_error2 = 0;
float rpm, target_rpm = 2.0;
float rpm2, target_rpm2 = 4.0;
// Variable Bawah
float Vt;
float k_enc = PI*D_ENCODER;
float k_robot = PI*D_ROBOT;
float speedT = 0.2;
float vpid = 0;
float pwmP = 0.5;
float pwmT = -0.95;
/* Deklarasi Encoder Base */
encoderKRAI encoderKiri(PC_4, PB_15, 2000, encoderKRAI::X2_ENCODING); //inA, inB, pin Indeks (NC = tak ada), resolusi, pembacaan
/* Deklarasi Encoder Launcher */
encoderKRAI encoderAtas( PC_10, PC_11, 28, encoderKRAI::X2_ENCODING);
encoderKRAI encoderAtas2( PD_2, PC_12, 28, encoderKRAI::X2_ENCODING);
/* Deklarasi Motor Base */
Motor motor1(PB_9, PA_12, PC_5); // pwm, fwd, rev, Motor Depan
Motor motor2(PB_6, PB_1, PB_12); // pwm, fwd, rev, Motor Belakang
/* Deklarasi Motor Launcher */
Motor motorL1(PA_8,PC_2,PC_1); // pwm ,fwd, rev, Motor Launcher1
Motor motorL3(PA_10, PC_3, PC_0); // pwm, fwd, rev, Motor Launcher2
Motor motorP(PB_7, PA_14, PA_15); // pwm, fwd, rev, Motor Powerscrew
/* Deklarasi Penumatik Launcher */
DigitalOut pneumatik(PB_3, PullUp);
/*Dekalrasi Limit Switch */
DigitalIn limitA (PC_9, PullUp);
DigitalIn limitT(PB_10, PullUp);
DigitalIn limitB (PC_8, PullUp);
/**
* posX dan posY berdasarkan arah robot
* encoder Depan & Belakang sejajar sumbu Y
* encoder Kanan & Kirim sejajar sumbu X
**/
/* Variabel Encoder */
float errT, Tetha; // Variabel yang didapatkan encoder
/* Fungsi dan Procedur Encoder */
void setCenter(); // Fungsi reset agar robot di tengah
float getTetha(); // Fungsi mendapatkan jarak Tetha
/* Inisialisasi Pin TX-RX Joystik dan PC */
joysticknucleo joystick(PA_0,PA_1);
Serial pc(USBTX,USBRX);
/* Deklarasi Variable Milis */
unsigned long int previousMillis = 0;
unsigned long int currentMillis;
unsigned long int previousMillis2 = 0;
unsigned long int currentMillis2;
/* Variabel Stick */
char case_ger;
bool launcher = false;
bool reload = false;
/****************************************************/
/* Deklarasi Fungsi dan Procedure */
/****************************************************/
void init_speed();
void speedKalibrasiMotor();
float pidBase(float Kp, float Ki, float Kd)
{
int errorP;
errorP = getTetha();
return (float)Kp*errorP;
}
int case_gerak(){
/****************************************************
** Gerak Motor Base
** Case 1 : Pivot kanan
** Case 2 : Pivot Kiri
** Case 3 : Kanan
** Case 4 : Kiri
** Case 5 : Break
****************************************************/
int casegerak;
if (!joystick.L1 && joystick.R1) {
// Pivot Kanan
casegerak = 1;
}
else if (!joystick.R1 && joystick.L1) {
// Pivot Kiri
casegerak = 2;
}
else if ((!joystick.R1)&&(!joystick.L1)&&(!joystick.atas)&&(!joystick.bawah)&&(joystick.kanan)&&(!joystick.kiri)) {
// Kanan
casegerak = 3;
// pc.printf("kanan");
}
else if ((!joystick.R1)&&(!joystick.L1)&&(!joystick.atas)&&(!joystick.bawah)&&(!joystick.kanan)&&(joystick.kiri)) {
// Kiri
casegerak = 4;
// pc.printf("kiri");
}
else if ((!joystick.R1)&&(!joystick.L1)&&(!joystick.atas)&&(!joystick.bawah)&&(!joystick.kanan)&&(!joystick.kiri)) {
// Break
casegerak = 5;
}
return(casegerak);
}
void aktuator(){
/* Fungsi untuk menggerakkan Motor PowerScrew */
// PowerScrew
if (reload){
if (!limitA){
motorP.brake (1);
wait_ms(1000);
}
else
{
motorP.speed(pwmP);
if (!limitT)
{
while (limitB)
{
motorP.speed(pwmT);
}
motorP.brake(1);
reload = !reload;
}
}
}
/*Motor Atas*/
if (launcher) {
startMillis();
currentMillis = millis();
currentMillis2 = millis();
/*PID Launcher Depan*/
if (currentMillis-previousMillis>=10)
{
rpm = (float)encoderAtas.getPulses();
current_error = target_rpm - rpm;
sum_error = sum_error + current_error;
p = current_error*kpA;
d = (current_error-last_error)*kdA/10.0;
i = sum_error*kiA*10.0;
speed = p + d + i;
init_speed();
motorL1.speed(speed);
last_error = current_error;
encoderAtas.reset();
//pc.printf("%.04lf\n",rpm);
previousMillis = currentMillis;
}
else
{
encoderAtas.getPulses();
}
if (currentMillis2-previousMillis2>=10)
{
rpm2 = (float)encoderAtas2.getPulses();
current_error2 = target_rpm2 - rpm2;
sum_error2 = sum_error2 + current_error2;
p2 = current_error2*kpA;
d2 = (current_error2-last_error2)*kdA/10.0;
i2 = sum_error2*kiA*10.0;
speed2 = p2 + d2 + i2;
init_speed();
motorL3.speed(speed2);
last_error2 = current_error2;
encoderAtas2.reset();
//pc.printf("%.04lf\n",rpm2);
previousMillis2 = currentMillis2;
}
else
{
encoderAtas2.getPulses();
}
}
else
{
motorL1.brake(1);
motorL3.brake(1);
}
// MOTOR Bawah
switch (case_ger) {
case (1): {
// Pivot Kanan
motor1.speed(PIVOT);
motor2.speed(PIVOT);
setCenter();
break;
}
case (2): {
// Pivot Kiri
motor1.speed(-PIVOT);
motor2.speed(-PIVOT);
setCenter();
break;
}
case (3) : {
// Kanan
//motor1.speed(-VMAX-vpid);
//motor2.speed(0.2+vpid);
motor1.speed(-0.365+pidBase(0.09,0,0));
motor2.speed(0.46+pidBase(0.09,0,0));
break;
}
case (4) : {
// Kiri
//motor1.speed(VMAX-vpid);
//motor2.speed(-0.2+vpid);
motor1.speed(0.365+pidBase(0.09,0,0));//belakang
motor2.speed(-0.46+pidBase(0.09,0,0));//depan
break;
}
default : {
motor1.brake(1);
motor2.brake(1);
}
} // End Switch
}
void setCenter(){
/* Fungsi untuk menentukan center dari robot */
encoderKiri.reset();
}
float getTetha(){
/* Fungsi untuk mendapatkan nilai tetha */
float busurKir, tetha;
busurKir = ((encoderKiri.getPulses())/(float)(2000.0)*k_enc);
tetha = busurKir/k_robot*360;
return -(tetha);
}
void speedKalibrasiMotor(){
/* Fungsi untuk speed launcher */
if (joystick.R3_click and target_rpm < 14){
target_rpm = target_rpm + 1; // RPM++ Motor Belakang
}
if (joystick.L3_click and target_rpm > 1){
target_rpm = target_rpm - 1; // RPM-- Motor Belakang
}
if (joystick.R2_click and target_rpm2 < 14){
target_rpm2 = target_rpm2 + 1; // RPM++ Motor Depan
}
if (joystick.L2_click and target_rpm2 > 1 ){
target_rpm2 = target_rpm2 - 1; // RPM-- Motor Depan
}
// pc.printf("Rpm depan = %.4f\t Rpm belakang = %.4f\n", target_rpm, target_rpm2);
}
void init_speed (){
if (speed>maxSpeed){
speed = maxSpeed;
}
if (speed<minSpeed){
speed = minSpeed;
}
if (speed2>maxSpeed){
speed2 = maxSpeed;
}
if (speed2<minSpeed){
speed2 = minSpeed;
}
}
/*********************************************************/
/* Main Function */
/*********************************************************/
int main (void){
/* Set baud rate - 115200 */
joystick.setup();
pc.baud(115200);
wait_ms(1000);
setCenter();
wait_ms(500);
pc.printf("ready....");
/* Untuk mendapatkan serial dari Arduino */
while(1)
{
// Interrupt Serial
joystick.idle();
//pc.printf("enco : %d \n",encoderKiri.getPulses());
if(joystick.readable()) {
// Panggil fungsi pembacaan joystik
joystick.baca_data();
// Panggil fungsi pengolahan data joystik
joystick.olah_data();
// Masuk ke case gerak
case_ger = case_gerak();
aktuator();
if (joystick.segitiga_click){
launcher = !launcher;
}
if (joystick.lingkaran_click){
pneumatik = 0;
wait_ms(1000);
pneumatik = 1;
}
speedKalibrasiMotor();
if (joystick.silang_click){
reload = !reload;
}
}
else {
joystick.idle();
motor1.brake(1);
motor2.brake(1);
}
}
}