DIY Obstacle Avoidance and Ranging Robot for Arduino
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DIY Obstacle Avoidance and Ranging Robot for Arduino
I.Brief introduction
II.Parameter
III.Experiment course introduction
IV.Listing
V.Install instruction
VI.Experiment in detail
1>.L298N motor driver module
2>.Tracking smart car
3>.Ultrasonic obstacle avoidance intelligent car
4>.Infrared remote control of intelligent car
5>.Mobile phone bluetooth intelligent car
6>.Multi_Function
I、Brief Introduction
Obstacle Avoidance And Ranging Robot For Arduino is a MCU learning application development system regarding The arduino microcontroller series Atmega-328 as the core. This kits include finish tracking,obstacle avoidance,infrared remote and bluetooth function as long as a large of interesting code and extensible external circuit module in order to increase more function.
II、Parameter
1.Motor parameter: Voltage:1.5V-12V.
Motor axial length:10mm. Rotate speed:100rpm/min(6V).
2.L298N driver motor ,solate form MCU;
3.Three channels tracking module,check black and white wire;
4.Infrared remote control communication module,consist of remote system of smart car;
5.Ultrasonic module is used in obstacle avoidance;
6.Bluetooth wireless module,it can remote control smart car with mobile phone;
7.It can be connect to 7V-12V power,can connect to more sensors as you can imagine.
III、Experiment Course Introduction
1.Application of L298N motor driver module;
2.Tracking smart car;
3.Ultrasonic obstacle avoidance smart car;
4.Infrared remote control smart car;
5.Arduino bluetooth programmable smart car;
6.Four functions in one code multifunction code.
IV、Listing
1.Metal gear motor x2
2.Wheel x2
3.Motor fixed part x2
4.Universal wheel x1
5.Chassis x2
6.L298N motor driver module x1
7.Arduino UNO controller x1
8.Arduino sensor shield x1
9.PTZ x1
10.Servo motor x1
11.Ultrasonic module x1
12.Three channels tracking module x1
13.Infrared receive sensor x1
14.Remote control x1
15.2000MA 18650 battery x2
16.18650 battery box x1
17.18650 battery charger x1
18.Dupont line 1P x40
19.M3*35mm copper cylinder x4
20.M3*10mm copper cylinder x2
21.M3 screw and nut severals
IV、Install Instruction
Step 1: connect gear motor and wheel.
Step 2: install motor fixed parts.
Step 3: install motor to chassis.
Step 4: fixed motor with nuts and screws.
Step 5: repeat steps above ,install another wheel and motor.
Step 6: prepare universal wheel.
Step 7: fixed universal wheel.
Step 8: repeat steps above ,install another universal wheel.
Step 9: install three channels tracking module.
Step 10: install L298N module.
Step 11:connect right wire of motor and battery box.The positive pole of battery box connect to VMS of L298N module.The negative pole of battery box connect to GND of L298N module.
Step 12:install 18650 battery box with screw.
Step 13:install four M3*35mm copper cylinders for second chassis.
Step 14:install chassis.
Step 15:install PTZ
Step 16:install arduino uno controller.
Step 17:install infrared remote control module.for new ,we have install this car.
VI、Experiment in Detail
1.L298N motor driver module
ENA(yellow in picture):
1(5V/PWM):enable motor A
0(GND/PWM):disenable motor A
IN1 to 5V,IN2 to GND,motor A
corotation IN1 to GND,IN2 to 5V,motor A
rollback ENB(yellow in picture):
1(5V/PWM):enable motor B
0(GND/PWM):disenable motor B
IN3 to 5V,IN4 to GND,motor A corotation
IN3 to GND,IN4 to 5V,motor A rollback
5V_EN(green in picture):
If use the jumper, chip 78 m05 provide power supply for modules
If do not use jumper, need to use 5v-pin & GND-pin provides power supply module for modules
CSA/CSB(green in picture):
Current test pins for motor A/B,can series connection resistance
If do not use jumper, detection of the current
If use the jumper,not detect current
UR1-UR4(green in picture)
Choose whether to use pull-up resistor For I/O port driver ability of microcontroller, can short circuit, using pull-up resistor If use the jumper, Do not use the pull-up resistor.
If do not use jumper ,use the pull-up resistor
Test Code:
int pinI1=8;//define IN1 pin
int pinI2=9;//define IN2 pin
int speedpin=11;//define EA(PWM) pin
int pinI3=6;//define IN3 pin
int pinI4=7;//define IN4 pin
int speedpin1=10;//define EB(PWM) pin
void setup()
{
pinMode(pinI1,OUTPUT);
pinMode(pinI2,OUTPUT);
pinMode(speedpin,OUTPUT);
pinMode(pinI3,OUTPUT);
pinMode(pinI4,OUTPUT);
pinMode(speedpin1,OUTPUT);
}
void loop()
{
//go straight
analogWrite(speedpin,100);// define speed
analogWrite(speedpin1,100);
digitalWrite(pinI4,LOW);// right motor move in anticlockwise
digitalWrite(pinI3,HIGH);
digitalWrite(pinI1,LOW);// left motor move in clockwise
digitalWrite(pinI2,HIGH);
delay(2000);
//go back
analogWrite(speedpin,100);// define speed
analogWrite(speedpin1,100);
digitalWrite(pinI4,HIGH);// right motor move in clockwise
digitalWrite(pinI3,LOW);
digitalWrite(pinI1,HIGH);// left motor move in anticlockwise
digitalWrite(pinI2,LOW);
delay(2000);
//turn left
analogWrite(speedpin,60);//
analogWrite(speedpin1,60);
digitalWrite(pinI4,LOW);//
digitalWrite(pinI3,HIGH);
digitalWrite(pinI1,HIGH);//
digitalWrite(pinI2,LOW);
delay(2000);
//turn right
analogWrite(speedpin,60);//
analogWrite(speedpin1,60);
digitalWrite(pinI4,HIGH);//
digitalWrite(pinI3,LOW);
digitalWrite(pinI1,LOW);//
digitalWrite(pinI2,HIGH);
delay(2000);
//stop
digitalWrite(pinI4,HIGH);//
digitalWrite(pinI3,HIGH);
digitalWrite(pinI1,HIGH);//
digitalWrite(pinI2,HIGH);
delay(2000);
}
NOTE:You can use other code to driver motor.
2>.Tracking Smart Car
Tracking module principle:TCRT5000 Using infrared reflectivity of color is different, the strength of the reflected signal is converted into electrical signals. Black and white tracing module in high level effectively detect black, white is detected for the low level, effectively detect 0-3 cm in height.
Method of application:
1>>.There are 3 row needle sensor interfaces, is GND, VCC, OUT. VCC &gnd for power supply side, the OUT signal is output.
2>>.An object is detected, the output signal low level; Not detected objects, the output signal of high level.
3>>.Major judgment signal output is 0 or 1, will be able to determine whether an object exists.
Performance Parameter:
1>>.detect distance:Test white paper is about 2cm..Depending on the color of different distance is different.white is farthest
2>>.supply voltage:2.5V~12V,Not more than 12V(It is best to low voltage power supply, power supply voltage is too high will shorten the life of a sensor.5V power supply is preferred)
3>>.operating current:18-20mA when 5V.By a large number of tests, sensor hardware Settings for 18~20mA best performance when working current, main performance on anti-jamming capability
4>>.Detection principle of the white line and black line, the principle of the detection of the white line, white line around the color is close to black, then adjust the adjustable resistance of infrared sensor above, will lower sensitivity, has been transferred to the surrounding color just detect, it can detect the white line.
Test code:
int pin=7;//
int val;//
void setup()
{
pinMode(ledPin,OUTPUT);//
Serial.begin(9600);//
}
void loop()
{ val=digitalRead(pin);/
/ Serial.println(val);//
}
Tracking smart test code:
int MotorRight1=5;
int MotorRight2=6;
int MotorLeft1=10;
int MotorLeft2=11;
const int SensorLeft = 7; //left sensor input
const int SensorMiddle= 4 ; //middle sensor input
const int SensorRight = 3; //right sensor input
int SL; //left sensor state
int SM; //
int SR; //
void setup()
{
Serial.begin(9600);
pinMode(MotorRight1, OUTPUT); // pin 8 (PWM)
pinMode(MotorRight2, OUTPUT); // 9 (PWM)
pinMode(MotorLeft1, OUTPUT); // 10 (PWM)
pinMode(MotorLeft2, OUTPUT); // 11 (PWM)
pinMode(SensorLeft, INPUT); //
pinMode(SensorMiddle, INPUT);//
pinMode(SensorRight, INPUT); //
}
void loop()
{
SL = digitalRead(SensorLeft);
SM = digitalRead(SensorMiddle);
SR = digitalRead(SensorRight);
if (SM == HIGH)//middle sensor in black area
{
if (SL == LOW & SR == HIGH) // left sensor in black area,right sensor in white area,so turn left
{
digitalWrite(MotorRight1,LOW);
digitalWrite(MotorRight2,HIGH);
analogWrite(MotorLeft1,0);
analogWrite(MotorLeft2,80);
}
else if (SR == LOW & SL == HIGH) //
{
analogWrite(MotorRight1,0);//
analogWrite(MotorRight2,80);
digitalWrite(MotorLeft1,LOW);
digitalWrite(MotorLeft2,HIGH);
}
else //
{
digitalWrite(MotorRight1,LOW);
digitalWrite(MotorRight2,HIGH);
digitalWrite(MotorLeft1,LOW);
digitalWrite(MotorLeft2,HIGH);
analogWrite(MotorLeft1,200);
analogWrite(MotorLeft2,200);
analogWrite(MotorRight1,200);
analogWrite(MotorRight2,200);
}
}
else //
{
if (SL == LOW & SR == HIGH)//
{
digitalWrite(MotorRight1,LOW);
digitalWrite(MotorRight2,HIGH);
digitalWrite(MotorLeft1,LOW);
digitalWrite(MotorLeft2,LOW);
}
else if (SR == LOW & SL == HIGH) //
{
digitalWrite(MotorRight1,LOW);
digitalWrite(MotorRight2,LOW);
digitalWrite(MotorLeft1,LOW);
digitalWrite(MotorLeft2,HIGH);
}
else //
{
digitalWrite(MotorRight1,HIGH);
digitalWrite(MotorRight2,LOW);
digitalWrite(MotorLeft1,HIGH);
digitalWrite(MotorLeft2,LOW);;
}}}
3>.Ultrasonic Obstacle Avoidance Intelligent Car
Obstacle avoidance intelligent ultrasonic is convenient, simple and easy to do real-time control, and can meet the practical requirements in terms of accuracy of measurement, thus become a commonly used method of obstacle avoidance. Ultrasonic method using reference (Arduino ultrasonic ranging).
Ultrasonic smart wiring diagram;
Test code:
#include
int pinLB=6; // left back
int pinLF=9; // left front
int pinRB=10; // right back
int pinRF=11; // left front
int inputPin = A0; // ultrasonic echo
int outputPin =A1; // ultrasonic trig
int Fspeedd = 0; // front distance
int Rspeedd = 0; // right distance
int Lspeedd = 0; // left distance
int directionn = 0; // Determine the direction of car turns
Servo myservo; // myservo
int delay_time = 250; // Stable steering servo motor
int Fgo = 8; // advance
int Rgo = 6; // turn right
int Lgo = 4; // turn left
int Bgo = 2; // back
void setup()
{
pinMode(pinLB,OUTPUT); // pin 6 (PWM)
pinMode(pinLF,OUTPUT); // pin 9 (PWM)
pinMode(pinRB,OUTPUT); // pin 10 (PWM)
pinMode(pinRF,OUTPUT); // pin 11 (PWM)
pinMode(inputPin, INPUT); // Define ultrasound input pin
pinMode(outputPin, OUTPUT); // Define ultrasound output pin
myservo.attach(5); // Define the servo motor output pin5 (PWM)
}
void advance(int a) // advance
{ //In the mid-point of the two wheels as a reference
digitalWrite(pinRB,LOW); //right wheel advance
digitalWrite(pinRF,HIGH);
digitalWrite(pinLB,HIGH); //left wheel advance
digitalWrite(pinLF,LOW);
delay(a);
}
void right(int b) //turn right (single wheel)
{
digitalWrite(pinRB,HIGH); //right stop
digitalWrite(pinRF,HIGH);
digitalWrite(pinLB,HIGH); //left advance
digitalWrite(pinLF,LOW);
delay(b);
}
void left(int c) //turn left(single wheel)
{
digitalWrite(pinRB,LOW); //righ wheel advance
digitalWrite(pinRF,HIGH);
digitalWrite(pinLB,HIGH); //left stop
digitalWrite(pinLF,HIGH);
delay(c);
}
void left(int c) //turn left(single wheel)
{
digitalWrite(pinRB,LOW); //righ wheel advance
digitalWrite(pinRF,HIGH);
digitalWrite(pinLB,HIGH); //left stop
digitalWrite(pinLF,HIGH);
delay(c);
}
void turnR(int d) //turn right(double wheels)
{
digitalWrite(pinRB,HIGH); //right wheel back
digitalWrite(pinRF,LOW);
digitalWrite(pinLB,HIGH); //left wheel advance
digitalWrite(pinLF,LOW);
delay(d);
}
void turnL(int e) //turn left (double wheels)
{
void turnL(int e) //turn left (double wheels)
{
digitalWrite(pinRB,LOW); //right wheel advance
digitalWrite(pinRF,HIGH);
digitalWrite(pinLB,LOW); //left wheel back
digitalWrite(pinLF,HIGH);
delay(e);
}
void stopp(int f) //stop
{
digitalWrite(pinRB,HIGH);
digitalWrite(pinRF,HIGH);
digitalWrite(pinLB,HIGH);
digitalWrite(pinLF,HIGH);
delay(f);
}
void back(int g) //back
{
digitalWrite(pinRB,HIGH); //right wheel back
digitalWrite(pinRF,LOW);
digitalWrite(pinLB,LOW); //left wheel back
digitalWrite(pinLF,HIGH);
delay(g);
}
void detection() //Measuring three angles(2.90.178)
{
myservo.write(90); //measure distance in the front
delay(delay_time); // Waiting for servo motor stable
ask_pin_F(); // Read the distance of front
if(Fspeedd < 20) // If the distance is less than 20cm in front
{
stopp(1); // clear output ,motor stop
myservo.write(178); //measure left distance
delay(delay_time);
ask_pin_L();
myservo.write(2); //measure right distance
delay(delay_time);
ask_pin_R();
if(Lspeedd > Rspeedd) //compare distance of right and left
{
directionn = Lgo; //turn left
}
right
if(Lspeedd <= Rspeedd) //if the distance is less than or equal to the distance at the right
{
directionn = Rgo; //turn right
}
}
else
else
directionn = Fgo;
}
myservo.write(90);
delay(delay_time);
}
void ask_pin_F() // Measure the distance in front
{
digitalWrite(outputPin, LOW); //Ultrasonic launch 2us low level
delayMicroseconds(2);
digitalWrite(outputPin, HIGH); // ultrasound transmitting high voltage 10us, there is at least 10us
delayMicroseconds(11);
digitalWrite(outputPin, LOW); // Ultrasonic launch low level
float Fdistance = pulseIn(inputPin, HIGH); //measure time
Fdistance= Fdistance/5.8/10; // time to distance (cm)
Fspeedd = Fdistance;
}
void ask_pin_L() //
{
delay(delay_time);
digitalWrite(outputPin, LOW); //
delayMicroseconds(2);
digitalWrite(outputPin, HIGH); //
delayMicroseconds(11);
digitalWrite(outputPin, LOW); //
float Ldistance = pulseIn(inputPin, HIGH); //
Ldistance= Ldistance/5.8/10; //
Lspeedd = Ldistance; //
}
void ask_pin_R() //
{
delay(delay_time);
digitalWrite(outputPin, LOW); //
delayMicroseconds(2);
digitalWrite(outputPin, HIGH; //
delayMicroseconds(11);
digitalWrite(outputPin, LOW); //
float Rdistance = pulseIn(inputPin, HIGH); //
Rdistance= Rdistance/5.8/10; //
Rspeedd = Rdistance; //
}
void loop()
{
detection(); //Measure the Angle and determine which direction to go to
if(directionn == 2)
{
back(600);
}
if(directionn == 6)
{
turnR(350);
stopp(1); }
if(directionn == 4)
{
turnL(350);
stopp(1);
}
if(directionn == 8)
{
advance(10);
ask_pin_F();
if(Fspeedd < 20) stopp(1);
}
}
4>.Infrared Remote Control of Intelligent Car
Test code:
#include //
const int irReceiverPin = 2; //
IRrecv irrecv(irReceiverPin); //
decode_results results; //
void setup()
{
Serial.begin(9600); //
irrecv.enableIRIn(); //
}
//
void showIRProtocol(decode_results *results)
{
Serial.print("Protocol: ");
//
switch(results->decode_type) {
case NEC:
Serial.print("NEC");
break;
case SONY:
Serial.print("SONY");
break;
case RC5:
Serial.print("RC5");
break;
case RC6:
Serial.print("RC6");
break;
default:
Serial.print("Unknown encoding");
}
//
Serial.print(", irCode: ");
Serial.print(results->value, HEX); //
Serial.print(", bits: ");
Serial.println(results->bits); //
}
void loop()
{
if (irrecv.decode(&results)) { //
showIRProtocol(&results); //
irrecv.resume(); //
}
}
Test code:
//******Infrared remote smart car code*******
#include
int RECV_PIN = A0;
int pinLB=6;//
int pinLF=9;//
int pinRB=3;//
int pinRF=5;//
//******
long advence = 0x00EF807F;
long back = 0x00EFA05F;
long stop = 0x00EF906F;
long left = 0x00EF00FF;
long right = 0x00EF40BF;
IRrecv irrecv(RECV_PIN);
decode_results results;
void dump(decode_results *results) {
int count = results->rawlen;
if (results->decode_type == UNKNOWN)
{
Serial.println("Could not decode message");
}
else
{
if (results->decode_type == NEC)
{
Serial.print("Decoded NEC: ");
}
else if (results->decode_type == SONY)
{
Serial.print("Decoded SONY: ");
}
else if (results->decode_type == RC5)
{
Serial.print("Decoded RC5: ");
}
else if (results->decode_type == RC6)
{
Serial.print("Decoded RC6: ");
}
Serial.print(results->value, HEX);
Serial.print(" (");
Serial.print(results->bits, DEC);
Serial.println(" bits)");
}
Serial.print("Raw (");
Serial.print(count, DEC);
Serial.print("): ");
for (int i = 0; i < count; i++)
{
if ((i % 2) == 1) {
Serial.print(results->rawbuf[i]*USECPERTICK, DEC);
}
else
{
Serial.print(-(int)results->rawbuf[i]*USECPERTICK, DEC);
}
Serial.print(" ");
}
Serial.println("");
}
void setup()
{
pinMode(RECV_PIN, INPUT);
pinMode(pinLB,OUTPUT);
pinMode(pinLF,OUTPUT);
pinMode(pinRB,OUTPUT);
pinMode(pinRF,OUTPUT); S
erial.begin(9600);
irrecv.enableIRIn(); // Start the receiver
}
int on = 0;
unsigned long last = millis();
void loop()
{
if (irrecv.decode(&results))
{
// If it's been at least 1/4 second since the last
// IR received, toggle the relay
if (millis() - last > 250)
{
on = !on;
// digitalWrite(8, on ? HIGH : LOW);
digitalWrite(13, on ? HIGH : LOW);
dump(&results);
}
if (results.value == advence )
{digitalWrite(pinRB,LOW);//
digitalWrite(pinRF,HIGH);
digitalWrite(pinLB,LOW);//
digitalWrite(pinLF,HIGH);}
if (results.value == back )
{digitalWrite(pinRB,HIGH);//)BACK
digitalWrite(pinRF,LOW);}
if (results.value == left )
{ digitalWrite(pinRB,LOW);// STOP
digitalWrite(pinRF,HIGH);
digitalWrite(pinLB,HIGH);//GO
digitalWrite(pinLF,LOW);}
if (results.value == right )
{ digitalWrite(pinRB,HIGH);//)GO
digitalWrite(pinRF,LOW);
digitalWrite(pinLB,HIGH);//STOP
digitalWrite(pinLF,HIGH);}
if (results.value == stop )
{ digitalWrite(pinRB,HIGH);//ST
OP digitalWrite(pinRF,HIGH);
digitalWrite(pinLB,HIGH);//STOP
digitalWrite(pinLF,HIGH);
}
last = millis();
irrecv.resume(); // Receive the next value
}
}
5>.Mobile Phone Bluetooth Intelligent Car
Being a short-range radio technology, Bluetooth technology can effectively simplify the handheld computers, laptops and mobile phones for communication between mobile phones and other mobile communication terminal equipment. What's more, Bluetooth can also simplify the above communication between the devices and the Internet,so that the modern communication equipment and data transmission become more efficiently, and broaden the way with wireless communications.
Because today is the first time to deal with the bluetooth module, or to a profound, let the Arduino and PC communication success. Wiring, first connect bluetooth motherboard + 5 v VCC, bluetooth motherboard GND connection - GND, motherboard TX connected bluetooth RX, RX connected bluetooth TX. When the success of the bluetooth module when the power is connected to the PC, the bluetooth module power will flashing lights, connect light green light will light up.
Test code:
char val;
int ledpin=13;
void setup()
{
Serial.begin(9600);
pinMode(ledpin,OUTPUT);
}
void loop()
{
val=Serial.read();
if(val=='r')
{
digitalWrite(ledpin,HIGH);
delay((500);
digitalWrite(ledpin,LOW);
delay(500);
Serial.println("keyes");
}
}
Let's learn the Arduino bluetooth remote control programmable intelligent car. Through bluetooth control forward, backward, turn left, turn right, buttons, computers and mobile phones, two kinds of control mode. (mobile phone operating system support Android 2.3.7 above. The computer must bring their own bluetooth)
When used for the first time to mobile phone with bluetooth car matching (pairing for the first time after the later don't have in wireless location), first take a look at the following steps:
1>>.Remember to open mobile phone bluetooth oh, open the software will remind users open the bluetooth 2>>.Then the text as shown in figure tips, connect a bluetooth device, scan matching bluetooth oh, otherwise not be able to connect to the car.
3>>.Match the car, the password is "1234" try it
Test code:
int MotorRight1=5;
int MotorRight2=6;
int MotorLeft1=10;
int MotorLeft2=11;
void setup()
{
Serial.begin(9600);
pinMode(MotorRight1, OUTPUT); // pin 8 (PWM)
pinMode(MotorRight2, OUTPUT); //9 (PWM)
pinMode(MotorLeft1, OUTPUT); //10 (PWM)
pinMode(MotorLeft2, OUTPUT); //11 (PWM)
}
void go()//
{
digitalWrite(MotorRight1,LOW);
digitalWrite(MotorRight2,HIGH);
digitalWrite(MotorLeft1,LOW);
digitalWrite(MotorLeft2,HIGH);
}
void left() //
{
digitalWrite(MotorRight1,LOW);
digitalWrite(MotorRight2,HIGH);
digitalWrite(MotorLeft1,LOW);
digitalWrite(MotorLeft2,HIGH);
}
void left() //
{
digitalWrite(MotorRight1,HIGH);
digitalWrite(MotorRight2,LOW);
digitalWrite(MotorLeft1,LOW);
digitalWrite(MotorLeft2,HIGH);
}
void right() //
{
digitalWrite(MotorRight1,LOW);
digitalWrite(MotorRight2,HIGH);
digitalWrite(MotorLeft1,HIGH);
digitalWrite(MotorLeft2,LOW);
}
void stop() //
{
digitalWrite(MotorRight1,LOW);
digitalWrite(MotorRight2,LOW);
digitalWrite(MotorLeft1,LOW);
digitalWrite(MotorLeft2,LOW);
}
void back() //
{
digitalWrite(MotorRight1,HIGH);
digitalWrite(MotorRight2,LOW);
digitalWrite(MotorLeft1,HIGH);
digitalWrite(MotorLeft2,LOW);;
}
void loop()
{
char val = Serial.read();
Serial.write(val);
if (-1 != val) {
if ('W' == val)
go();
else if ('A' ==val)
left();
else if ('D' == val)
right();
else if ('S' == val)
back();
else if ('Q' == val)
stop();
delay(500);
}
else
{
//stop();
delay(500);
}
}
6>.Multi_Function
Test code:
//******************************
#include
#include
//***********************define motor pin*************************
int MotorRight1=5;
int MotorRight2=6;
int MotorLeft1=10;
int MotorLeft2=11;
int counter=0;
const int irReceiverPin = 2; //Infrared receive sensor
char val;
//***********************set detection IRcode*************************
long IRfront= 0x00FFA25D; //go straight
long IRback=0x00FF629D; //go back
long IRturnright=0x00FFC23D; //turn right
long IRturnleft= 0x00FF02FD; //turn left
long IRstop=0x00FFE21D; //stop
long IRcny70=0x00FFA857; //CNY70 automatic mode
long IRAutorun=0x00FF906F; //Ultrasonic automatic mode
long IRturnsmallleft= 0x00FF22DD;
//*************************define CNY70 pin***************************
const int SensorLeft = 7; //left sensor input
const int SensorMiddle= 4 ; //middle sensor input
const int SensorRight = 3; //right sensor input
int SL; //left sensor state
int SM; //middle sensor state
int SR; //right sensor state
IRrecv irrecv(irReceiverPin); // define IRrecv receive signal
decode_results results; // decoderesults
//*************************define ultrasonic pin****************
int inputPin =13 ; // ultrasonic receive pin
int outputPin =12; //ultrasonic echo pin
int Fspeedd = 0; // front distance
int Rspeedd = 0; // right distance
int Lspeedd = 0; // left distance
int directionn = 0; // front=8; back=2; left=4; right=6
Servo myservo; // define myservo
int delay_time = 250; // servo motor go back state time
int Fgo = 8; // go straight
int Rgo = 6; // turn right
int Lgo = 4; // turn left
int Bgo = 2; // go back
//*********************************(SETUP)
void setup()
{
Serial.begin(9600);
pinMode(MotorRight1, OUTPUT); // pin 8 (PWM)
pinMode(MotorRight2, OUTPUT); //pin 9 (PWM)
pinMode(MotorLeft1, OUTPUT); // pin 10 (PWM)
pinMode(MotorLeft2, OUTPUT); // pin 11 (PWM)
irrecv.enableIRIn(); // start infrared decode
pinMode(SensorLeft, INPUT); //
pinMode(SensorMiddle, INPUT);//
pinMode(SensorRight, INPUT); //
digitalWrite(2,HIGH);
pinMode(inputPin, INPUT); //
pinMode(outputPin, OUTPUT); //
myservo.attach(9); //
}
//*************************************************(Void)
void advance(int a) // go straight
{
digitalWrite(MotorRight1,LOW);
digitalWrite(MotorRight2,HIGH);
digitalWrite(MotorLeft1,LOW);
digitalWrite(MotorLeft2,HIGH);
delay(a * 100);
}
void right(int b) //turn right(single wheel)
{
digitalWrite(MotorLeft1,LOW);
digitalWrite(MotorLeft2,HIGH);
digitalWrite(MotorRight1,LOW);
digitalWrite(MotorRight2,LOW);
delay(b * 100);
}
void left(int c) //turn left(single wheel)
{
digitalWrite(MotorRight1,LOW);
digitalWrite(MotorRight2,HIGH);
digitalWrite(MotorLeft1,LOW);
digitalWrite(MotorLeft2,LOW);
delay(c * 100);
}
void turnR(int d) //turn right(two wheels)
{
digitalWrite(MotorRight1,HIGH);
digitalWrite(MotorRight2,LOW);
digitalWrite(MotorLeft1,LOW);
digitalWrite(MotorLeft2,HIGH);
delay(d * 100);
}
void turnL(int e) //turn left(two wheels)
{
digitalWrite(MotorRight1,LOW);
digitalWrite(MotorRight2,HIGH);
digitalWrite(MotorLeft1,HIGH);
digitalWrite(MotorLeft2,LOW);
delay(e * 100);
}
void stopp(int f) //stop
{
digitalWrite(MotorRight1,LOW);
digitalWrite(MotorRight2,LOW);
digitalWrite(MotorLeft1,LOW);
digitalWrite(MotorLeft2,LOW);
delay(f * 100);
}
void back(int g) //go back
{
digitalWrite(MotorRight1,HIGH);
digitalWrite(MotorRight2,LOW);
digitalWrite(MotorLeft1,HIGH);
digitalWrite(MotorLeft2,LOW);;
delay(g * 100);
}
void detection() //measurement 3 angle(front ,left,right)
{
int delay_time = 250; //
ask_pin_F(); // detection distance in front
if(Fspeedd < 10) // if distance less than 10mm
{
stopp(1); // clear output
back(2); // go back 0.2s
}
if(Fspeedd < 25) // if distance less than 25mm
{
stopp(1); // clear output
ask_pin_L(); // detection distance in left delay(delay_time);
// Waiting for the servo motor is stable ask_pin_R(); //
detection distance in right delay(delay_time); // waiting
for servo motor state
if(Lspeedd > Rspeedd) //if left distance greater than right
{
directionn = Lgo; //go left
}
if(Lspeedd <= Rspeedd) //if left distance less than right
{
directionn = Rgo; //go right
}
if (Lspeedd < 15 && Rspeedd < 15) //if distance less 10mm both right and left
{
directionn = Bgo; //go back
}
}
else //if distance greater than 25mm
{
directionn = Fgo; //go straight
}
}
//*********************************************
void ask_pin_F() // detection distance in front
{
myservo.write(90);
digitalWrite(outputPin, LOW); // ultrasonic echo low level in 2us
delayMicroseconds(2);
digitalWrite(outputPin, HIGH); // ultrasonic echo high level in 10us, At least 10us
delayMicroseconds(10);
digitalWrite(outputPin, LOW); // ultrasonic echo low leve
float Fdistance = pulseIn(inputPin, HIGH); // read time
Fdistance= Fdistance/5.8/10; // turn time to distance
Serial.print("F distance:"); //output distance (mm)
Serial.println(Fdistance); //display distance
Fspeedd = Fdistance; // write distance to Fspeed
}
//******************************************************
void ask_pin_L() // detection distance in left
{ myservo.write(177)
; delay(delay_time);
digitalWrite(outputPin, LOW); // ultrasonic echo low level in 2us
delayMicroseconds(2);
digitalWrite(outputPin, HIGH); // ultrasonic echo high level in 10us, At least 10us
delayMicroseconds(10);
digitalWrite(outputPin, LOW); // ultrasonic echo low level
float Ldistance = pulseIn(inputPin, HIGH); // read time
Ldistance= Ldistance/5.8/10; // turn time to distance
Serial.print("L distance:"); //output distance (mm)
Serial.println(Ldistance); //display distance
Lspeedd = Ldistance; // write distance to Lspeed
}
//******************************************************************************
void ask_pin_R() // detection distance in right
{ myservo.write(5);
delay(delay_time);
digitalWrite(outputPin, LOW); //
delayMicroseconds(2);
digitalWrite(outputPin, HIGH); //
delayMicroseconds(10);
digitalWrite(outputPin, LOW); //
float Rdistance = pulseIn(inputPin, HIGH); //
Rdistance= Rdistance/5.8/10; //
Serial.print("R distance:"); //
Serial.println(Rdistance); //
Rspeedd = Rdistance; //
}
//***********************************(LOOP)
void loop()
{
SL = digitalRead(SensorLeft);
SM = digitalRead(SensorMiddle);
SR = digitalRead(SensorRight);
performCommand();
//******************************normal remote control mode
if (irrecv.decode(&results))
{ // Decoding success,receive infrared signal
/*********************************************/
if (results.value == IRfront)//go straight
{
advance(10);//go straight
}
/***************************************/
if (results.value == IRback)//go back
{
back(10);//go back
}
/***********************************************************************/
if (results.value == IRturnright)//turn right
{
left(6); // turn left;
}
/***********************************************************************/
if (results.value == IRstop)//stop
{
digitalWrite(MotorRight1,LOW);
digitalWrite(MotorRight2,LOW);
digitalWrite(MotorLeft1,LOW);
digitalWrite(MotorLeft2,LOW);
}
//*************************************cny70 automatic mode
if (results.value == IRcny70)
{
while(IRcny70)
{
SL = digitalRead(SensorLeft);
SM = digitalRead(SensorMiddle);
SR = digitalRead(SensorRight);
if (SM == HIGH)//middle sensor in black area
{
if (SL == LOW & SR == HIGH) // left sensor in black area,right sensor in white area ,so turn left
{
digitalWrite(MotorRight1,LOW);
digitalWrite(MotorRight2,HIGH);
analogWrite(MotorLeft1,0);
analogWrite(MotorLeft2,80);
}
else if (SR == LOW & SL == HIGH) //left white,right black ,turn right
{
analogWrite(MotorRight1,0);//
analogWrite(MotorRight2,80);
digitalWrite(MotorLeft1,LOW);
digitalWrite(MotorLeft2,HIGH);
}
else // left and right both in white ,go straight
{
digitalWrite(MotorRight1,LOW);
digitalWrite(MotorRight2,HIGH);
digitalWrite(MotorLeft1,LOW);
digitalWrite(MotorLeft2,HIGH);
analogWrite(MotorLeft1,200);
analogWrite(MotorLeft2,200);
analogWrite(MotorRight1,200);
analogWrite(MotorRight2,200);
}
}
else // middle sensor in white area
{
if (SL == LOW & SR == HIGH)// left black,right white,turn left
{
digitalWrite(MotorRight1,LOW);
digitalWrite(MotorRight2,HIGH);
digitalWrite(MotorLeft1,LOW);
digitalWrite(MotorLeft2,LOW);
}
else if (SR == LOW & SL == HIGH) // left white,right black ,turn right
{
digitalWrite(MotorRight1,LOW);
digitalWrite(MotorRight2,LOW);
digitalWrite(MotorLeft1,LOW);
digitalWrite(MotorLeft2,HIGH);
}
else // left and right both in white ,stop
{
digitalWrite(MotorRight1,HIGH);
digitalWrite(MotorRight2,LOW);
digitalWrite(MotorLeft1,HIGH);
digitalWrite(MotorLeft2,LOW);;
}
}
if (irrecv.decode(&results))
{
irrecv.resume();
Serial.println(results.value,HEX);
if(results.value ==IRstop)
{
digitalWrite(MotorRight1,HIGH);
digitalWrite(MotorRight2,HIGH);
digitalWrite(MotorLeft1,HIGH);
digitalWrite(MotorLeft2,HIGH);
break;
}
}
}
results.value=0;
}
//********************************ultracsonic automaitc mode
if (results.value ==IRAutorun )
{
while(IRAutorun)
{
myservo.write(90); //make the servo motor reset
detection(); //
if(directionn == 8) //directionn = 8(go straight)
{
if (irrecv.decode(&results))
{
irrecv.resume();
Serial.println(results.value,HEX);
if(results.value ==IRstop)
{
digitalWrite(MotorRight1,LOW);
digitalWrite(MotorRight2,LOW);
digitalWrite(MotorLeft1,LOW);
digitalWrite(MotorLeft2,LOW);
break;
}
}
results.value=0;
advance(1); //
Serial.print(" Advance "); //
Serial.print(" ");
}
if(directionn == 2) //2(go back)
{
if (irrecv.decode(&results))
{
irrecv.resume();
Serial.println(results.value,HEX);
if(results.value ==IRstop)
{
digitalWrite(MotorRight1,LOW);
digitalWrite(MotorRight2,LOW);
digitalWrite(MotorLeft1,LOW);
digitalWrite(MotorLeft2,LOW);
break;
}
}
results.value=0;
back(8); //
turnL(3); //To prevent the jammed
Serial.print(" Reverse "); //
}
if(directionn == 6) // 6(turn right)
{
if (irrecv.decode(&results))
{
irrecv.resume();
Serial.println(results.value,HEX);
if(results.value ==IRstop)
{
digitalWrite(MotorRight1,LOW);
digitalWrite(MotorRight2,LOW);
digitalWrite(MotorLeft1,LOW);
digitalWrite(MotorLeft2,LOW);
break;
}
}
results.value=0;
back(1);
turnR(6); //
Serial.print(" Right "); //
}
if(directionn == 4) // 4(turn left)
{
if (irrecv.decode(&results))
{
irrecv.resume();
Serial.println(results.value,HEX);
if(results.value ==IRstop)
{
digitalWrite(MotorRight1,LOW);
digitalWrite(MotorRight2,LOW);
digitalWrite(MotorLeft1,LOW);
digitalWrite(MotorLeft2,LOW);
break;
}
}
results.value=0;
back(1);
turnL(6); //
Serial.print(" Left "); //
}
if (irrecv.decode(&results))
{
irrecv.resume();
Serial.println(results.value,HEX);
if(results.value ==IRstop)
{
digitalWrite(MotorRight1,LOW);
digitalWrite(MotorRight2,LOW);
digitalWrite(MotorLeft1,LOW);
digitalWrite(MotorLeft2,LOW);
break;
}
}
}
results.value=0;
}
/***********************************************************************/
else
{
digitalWrite(MotorRight1,LOW);
digitalWrite(MotorRight2,LOW);
digitalWrite(MotorLeft1,LOW);
digitalWrite(MotorLeft2,LOW);
}
irrecv.resume(); //
}
}
void performCommand() {
if (Serial.available()) {
val = Serial.read();
}
if (val == 'f') { // Forward
advance(10);
} else if (val == 'z') { // Stop Forward
stopp(10) ;
} else if (val == 'b') { // Backward
back(10);
} else if (val == 'y') { // Stop Backward
back(10);
} else if (val == 'l') { // Right
turnR(10);
} else if (val == 'r') { // Left
turnL(10);
} else if (val == 'v') { // Stop Turn
stopp(10) ;
} else if (val == 's') { // Stop
stopp(10) ;
}
}
Conclusion
We can do a lot experiment through the robot in the summer vocation if you love to stay at home.
Detailed code and process will help us enjoy the whole expreriment. Even we are a fresh men in Arduino and know little about how to make robot.
What's more, ICStation has a discount during the holidays. We can get 55% discount before 10th July 2016
http://www.icstation.com/robot-learning-kits-ardui...
If you think it's a good project, could you please share with your friends?
If you have any suggestion, please comment and we will answer you as soon as possible.
If you have some more ideas about making a review about ICStation's products, please contact icstation13@gmail.com