Skema Arduino Sensor Shield V5.0

 

Arduino sensor shield v5.0 merupakan salah satu shield arduino yang berfungsi untuk menghubungkan board arduino dengan modul elektronik maupun sensor yang akan digunakan.

interface yang didukung:

• IIC interface
• Servo controller
• Bluetooth module
• SD card module
• APC220 radio frequency
• RB URF v1.1 ultrasonic sensor
• 12864 LCD serial dan parallel

Untuk dapat menggunakan sensor shield tersebut, kita perlu memahami skema bagaimana interface-interface tersebut terhubung dengan port-port pada board arduino.

berikut ini adalah gambar skema dari arduino sensor shield v5.0

Membuat Robot Rover Self avoiding

Tutorial kali ini akan dijelaskan tentang bagaimana cara membuat robot jenis rover yang dapat menghindari penghalang secara otomatis.
Bahan-bahan:

• baterai x8
• motor gearbox + roda X4
• 4xAA baterai holder x2
• saklar
• kabel
• arduino uno
• dual l293d motor shield
• microservo
• hc-sr04 ultrasonic sensor

cara merakit:

• hubungkan servo dengan konektor servo di serv0.
• rakit 2 motor secara pararel kemudian hubungkan masing_masing pasangan motor dengan M1 dan M3.
• hubungkan baterai holder dengan saklar, kemudian hubungkan dengan konektor eksternal power pada motor shield. 
• hubungkan ultrasonic sensor pada motor shield (trig ke a5, echo ke a4, vcc ke 5v, grnd ke ground).
• download program robot pada arduino uno.
• satukan motor shield dengan arduino.

kode program:
#include <AFMotor.h>
#include <Servo.h>
#include <Ultrasonic.h>
typedef enum {
  RADAR_LEFT = 0, RADAR_CENTER = 60, RADAR_RIGHT = 120 } RadarDirection;
Servo radarServo;  // create servo object to control a servo
int RADAR_INPUT_PIN = 9;
int RADAR_MOVEMENT_DELAY = 250;
int RADAR_DISTANCE_MINIMAL_IN_CM = 80; // centimeter
int RADAR_DISTANCE_UNKNOWN_IN_CM = 0; // centimeter
int RADAR_DISTANCE_UNDEFINED = -1;
Ultrasonic radarUltrasonic(A5,A4);
AF_DCMotor motorLeft(3, MOTOR12_64KHZ); // create motor #2, 64KHz pwm
AF_DCMotor motorRight(1, MOTOR12_64KHZ); // create motor #1, 64KHz pwm
int MOTOR_SPEED = 200;// 150;
int MOTOR_TURN_SPEED = 200; //250;
int MOTOR_DELAY = 150;
int MOTOR_TURN_DELAY = 500;
int MOTOR_BACKWARD_DELAY = 1000;
struct RobotState {
  int leftMotorDirection;
  int rightMotorDirection;
  int leftMotorSpeed;
  int rightMotorSpeed;
  int motorDelay;
  boolean isBackwardState;
};
struct RadarDistances {
  int left;
  int center;
  int right;
};
RobotState forwardState = {
  FORWARD,FORWARD,MOTOR_SPEED,MOTOR_SPEED,MOTOR_DELAY,false};
RobotState backwardState = {
  BACKWARD,BACKWARD,MOTOR_SPEED,MOTOR_SPEED,MOTOR_BACKWARD_DELAY,true};
RobotState backwardUturnState = {
  FORWARD,BACKWARD,MOTOR_SPEED,MOTOR_SPEED,MOTOR_TURN_DELAY,true};
RobotState turnLeftState = {
  RELEASE,FORWARD,MOTOR_SPEED,MOTOR_TURN_SPEED,MOTOR_TURN_DELAY,false};
RobotState turnRightState = {
  FORWARD,RELEASE,MOTOR_TURN_SPEED,MOTOR_SPEED,MOTOR_TURN_DELAY,false};
RobotState stopState = {
  RELEASE,RELEASE,MOTOR_SPEED,MOTOR_SPEED,MOTOR_BACKWARD_DELAY,false};
RobotState currentState = forwardState;
RadarDistances currentDistances = {
  RADAR_DISTANCE_UNDEFINED,RADAR_DISTANCE_UNDEFINED,RADAR_DISTANCE_UNDEFINED};
RadarDistances lastDistances = {
  RADAR_DISTANCE_UNDEFINED,RADAR_DISTANCE_UNDEFINED,RADAR_DISTANCE_UNDEFINED};
void setup() {
  initTrace();
  initRadar();
  initMotors();
}
void initTrace(){
  Serial.begin(9600);           // set up Serial library at 9600 bps
  Serial.println("My First Robot");
}
void initRadar(){
  radarServo.attach(RADAR_INPUT_PIN);  // attaches the servo on pin RADAR_INPUT_PIN to the servo object
  radarServo.write(RADAR_CENTER);
}
void initMotors(){
  motorLeft.setSpeed(MOTOR_SPEED);     // set the speed to 200/255
  motorRight.setSpeed(MOTOR_SPEED);     // set the speed to 200/255
}
void loop() {
  calculateRobotState();
  makeDistancesSnapshot();
  go();
}
void calculateRobotState(){
  measureDistanceAhead();
  if(
    isCenterDistanceUndefinded() ||
    isNoObstacleInPathAhead())
  {
//    if(isInCorner()){
//      currentState = backwardState; 
//      return;
//    }
    currentState = forwardState; 
    return;
  }
  measureDistanceLeft();
  measureDistanceRight();
  if(greater(currentDistances.left,currentDistances.right)){
    currentState = turnLeftState; 
    return;
  }
  if(greater(currentDistances.right,currentDistances.left)){
    currentState = turnRightState; 
    return;
  }
  if(eq(currentDistances.left,currentDistances.right)){
    currentState = backwardState; 
    return;
  }
  currentState = stopState;
}
void go(){
  Serial.print("Go : { ");
  Serial.print(currentState.leftMotorDirection);
  Serial.print(" , ");
  Serial.print(currentState.rightMotorDirection);
  Serial.println(" }");
  Serial.print("with : { left:");
  Serial.print(currentDistances.left);
  Serial.print(" , center:");
  Serial.print(currentDistances.center);
  Serial.print(" , right:");
  Serial.print(currentDistances.right);
  Serial.println(" }");
  motor();
}
void motor(){
  motorLeft.setSpeed(currentState.leftMotorSpeed);
  motorRight.setSpeed(currentState.rightMotorSpeed);
  motorLeft.run(currentState.leftMotorDirection);
  motorRight.run(currentState.rightMotorDirection);
  if(currentState.isBackwardState){
    delay(currentState.motorDelay);
    motorLeft.setSpeed(backwardUturnState.leftMotorSpeed);
    motorRight.setSpeed(backwardUturnState.rightMotorSpeed);
    motorLeft.run(backwardUturnState.leftMotorDirection);
    motorRight.run(backwardUturnState.rightMotorDirection);
    delay(backwardUturnState.motorDelay);
  }
}
void measureDistanceLeft(){
  moveRadarFastTo(RADAR_LEFT);
  currentDistances.left = internalMeasure();
}
void measureDistanceRight(){
  moveRadarFastTo(RADAR_RIGHT);
  currentDistances.right = internalMeasure();
}
void measureDistanceAhead(){
  moveRadarFastTo(RADAR_CENTER);
  currentDistances.center = internalMeasure();
}
int internalMeasure(){
  long microsec = radarUltrasonic.timing();
  return radarUltrasonic.convert(microsec, Ultrasonic::CM);
}
void moveRadarFastTo(int radarServoPosition){
  radarServo.write(radarServoPosition);              // tell servo to go to position in variable 'pos'
  delay(RADAR_MOVEMENT_DELAY);
}
boolean isCenterDistanceUndefinded(){
  return currentDistances.center == RADAR_DISTANCE_UNKNOWN_IN_CM;
}
boolean isNoObstacleInPathAhead(){
  return currentDistances.center >= RADAR_DISTANCE_MINIMAL_IN_CM;
}
boolean isInCorner(){
  boolean left = eq(currentDistances.left,lastDistances.left);
  boolean center = eq(currentDistances.center,lastDistances.center);
  boolean right = eq(currentDistances.right,lastDistances.right);
  return left && center && right;
}
boolean eq(int a, int b){
  int epsilon = 5;
  int diff = a - b;
  diff = diff < 0 ? (-1)*diff : diff;
  return diff <= epsilon ? true : false;
}
boolean greater(int a, int b){
  int epsilon = 5;
  int diff = a - b;
  if(diff > 0){
    diff = diff - epsilon;
  }
  return diff > 0;
}
void makeDistancesSnapshot(){
  lastDistances.left = currentDistances.left;
  lastDistances.center = currentDistances.center;
  lastDistances.right = currentDistances.right;
}
 
video robot rover 4 roda:

video robot 2 roda:

Arduino L293D Motor Drive Shield

 

Dual l293d motor shield, merupakan shield arduino yang mudah penggunaannya untuk pembuatan aplikasi robot beroda. Karena shield ini dapat menjalankan 4 buah motor dan dua buah servo sekaligus. Shield ini adalah produk buatan dari adafruit. Namun dipasaran, sudah banyak beredar produk yang serupa (clone) dengan harga yang lebih murah.

Spesifikasi lengkap shield ini adalah sebagai berikut.

-2 konektor untuk 5V Servo.
- Dapat menjalankan 4 motor DC atau 2 stepper motor atau 2 Servo.
- Dapat menjalankan 4 motor bi-directional DC dengan kecepatan pemilihan 8-bit.
- Menjalankan 2 stepper motor (unipolar atau bipolar) dengan single coil atau double coil.
- 4 H-Bridges: per bridge menyediakan 0.6A (1.2A saat puncak) dengan perlindungan termal, dapat menjalankan motor  4.5V sampai 36V DC.
- Tombol reset.
- 2 konektor daya eksternal.
- Kompatibel untuk Uno, Mega Diecimila & Duemilanove.

Untuk file librarynya bisa mendownload di link di bawah ini.

arduino motor shield library

contoh program

1. Motor_shield_test_01

#include <AFMotor.h>

AF_DCMotor motor(2, MOTOR12_64KHZ); // create motor #2, 64KHz pwm

void setup() {
  Serial.begin(9600);           // set up Serial library at 9600 bps
  Serial.println("Motor test!");
  motor.setSpeed(200);     // set the speed to 200/255
}

void loop() {
  Serial.print("tick");
  motor.run(FORWARD);      // turn it on going forward
  delay(1000);

  Serial.print("tock");
  motor.run(BACKWARD);     // the other way
  delay(1000);

  Serial.print("tack");
  motor.run(RELEASE);      // stopped
  delay(1000);
}

 

2. Motor_shield_test_02

#include <AFMotor.h>

AF_DCMotor motor1(1);
AF_DCMotor motor2(2);
AF_DCMotor motor3(3);
AF_DCMotor motor4(4);

void setup()
{
  motor1.setSpeed(100); 
  motor2.setSpeed(100); 
  motor3.setSpeed(100); 
  motor4.setSpeed(100);
}
void loop()
{
  motor1.run(FORWARD); 
  motor2.run(FORWARD); 
  motor3.run(FORWARD); 
  motor4.run(FORWARD);
  ::delay(5000);
  motor1.run(RELEASE);
  motor2.run(RELEASE); 
  motor3.run(RELEASE); 
  motor4.run(RELEASE); 
  ::delay(5000);
}