Introduction: DIY Arduino Motor Shield (L298N 2x4A)
Today, I'm going to show
you how to make an Arduino motor shield (driver) at a low cost. It
works splendidly, its posses almost all the characteristics of the
original Arduino motor shield. It's almost considered as a clone. The
original Arduino motor shield has the same motor driver chip (L298), the
only difference with it, is the package type, my project contains the
vertical version of the chip L298 (with a "N").
Structure:
It's controlled using 4 PWM pins. The connections are: 11&10 for the R-Motor and 6&5 for the L-Motor. With the help of eight fast recovery diodes (1N4937) it shows a very fast response of stopping/ braking, that's why I'm going to use it for the national SUMOBOT competition.
What Is A Motor Shield?
A motor shield is a circuit that drives different loads such as motors, lights and etc... The Arduino Board (Microcontroller) itself isn't designed to operate high current loads, that's why we use motor shields, it is a circuit that is controlled by your arduino board to drive high power accessories.
Cost:
It only cost me P363.75 (Converted: $8.87)! The prices would decrease to P262.50 (Converted: $6.40) if I sticked to the original plan, since it's for competitional purposes, I substituted some parts with a higher rate of response.
About The Guide:
The guide includes the datasheet, schematic diagram, PCB layout, Arduino test files and etc.... All you need is an hour and the 6 step instructable.
Specs:
____________________________________________________
Voltage Range: 5- 50 volts
Current Range: 2-4 Amperes
Power: 25w @75°C
Working Temparature: -40°C to 150°C
Board Compatibility: Arduino Uno
Motor Outputs: 2 Motors (Left & Right)
Possible Robot Movements: Left, Right, Forward, Backward & etc..
PWM Pins: [12&11] [6&5]
The PCB layout is my original design, it was created using Fritzing Software, please ask for permission if anyone is willing to modify and republish it.
This Instructable is dedicated to the: DB Makati ROBOTICS Team
Structure:
It's controlled using 4 PWM pins. The connections are: 11&10 for the R-Motor and 6&5 for the L-Motor. With the help of eight fast recovery diodes (1N4937) it shows a very fast response of stopping/ braking, that's why I'm going to use it for the national SUMOBOT competition.
What Is A Motor Shield?
A motor shield is a circuit that drives different loads such as motors, lights and etc... The Arduino Board (Microcontroller) itself isn't designed to operate high current loads, that's why we use motor shields, it is a circuit that is controlled by your arduino board to drive high power accessories.
Cost:
It only cost me P363.75 (Converted: $8.87)! The prices would decrease to P262.50 (Converted: $6.40) if I sticked to the original plan, since it's for competitional purposes, I substituted some parts with a higher rate of response.
About The Guide:
The guide includes the datasheet, schematic diagram, PCB layout, Arduino test files and etc.... All you need is an hour and the 6 step instructable.
Specs:
____________________________________________________
Voltage Range: 5- 50 volts
Current Range: 2-4 Amperes
Power: 25w @75°C
Working Temparature: -40°C to 150°C
Board Compatibility: Arduino Uno
Motor Outputs: 2 Motors (Left & Right)
Possible Robot Movements: Left, Right, Forward, Backward & etc..
PWM Pins: [12&11] [6&5]
The PCB layout is my original design, it was created using Fritzing Software, please ask for permission if anyone is willing to modify and republish it.
This Instructable is dedicated to the: DB Makati ROBOTICS Team
(Merry Christmas & A Happy New Year!!)
Here's A Video Of My Sumobot Containing The DIY L298N Motor Driver Circuit:
Step 1: Parts & Materials
I bought my parts from ALEXAN,
a local electronic store with tons of branches (Found Only In The
Philippines). Everything is cheap here, the links that I gave are only
alternative for online purchases. My real price list and spending is a
lot different and cheaper. If you live in the Philippines, you can buy parts from DEECO, Alexan, E-Gizmo or Raon.
Parts:
- L298N Motor Driver Chip
- 7806 Regulator Chip
- 1N4937 Fast Recovery Diode
- 1 Ohm ¼ watt Resistor
- Screw Terminal Blocks
- PCB Board (Regular or Photo-positive)
- Male or Female Pins (Used to connect to Arduino)
- Heatsink (Bought or DIY)
7806 Regulator Chip = (Substitute: 7805- 7809)
1 Ohm ¼ watt Resistor = (Substitute: Up to 10 Ohms)
1N4937 Fast Recovery Diode = (Substitute: 1N4007 or 4148)
Parts:
- L298N Motor Driver Chip
- 7806 Regulator Chip
- 1N4937 Fast Recovery Diode
- 1 Ohm ¼ watt Resistor
- Screw Terminal Blocks
- PCB Board (Regular or Photo-positive)
- Male or Female Pins (Used to connect to Arduino)
- Heatsink (Bought or DIY)
7806 Regulator Chip = (Substitute: 7805- 7809)
1 Ohm ¼ watt Resistor = (Substitute: Up to 10 Ohms)
1N4937 Fast Recovery Diode = (Substitute: 1N4007 or 4148)
Step 2: PCB Making
In
this step, I will show you the schematic diagrams, datasheets and PCB
layouts. Just download the files below. If you don't know how to make a
PCB, please visit my other instructable guide "DIY Customized Circuit Board (PCB Making)".
I used a Photo-postive PCB board instead of the traditional toner
transfer. The photo-postive PCB is a bit rare in the U.S. that's why
some should stick with the toner transfer method. Also don't forget to
drill holes on them :)))
In making the photo-positive PCB, it's better to stay in a dark area and have a 10W fluorescent lamp beside you, also use a kitchen timer to set a 5 minute alarm for counting the exposure time.
In making the photo-positive PCB, it's better to stay in a dark area and have a 10W fluorescent lamp beside you, also use a kitchen timer to set a 5 minute alarm for counting the exposure time.
Step 3: Soldering the Parts
I've bent the L298N chip
with a pair of long nose pliers to fit into my robot (sumobot). Please
pay particular attention to the part placement. The diodes should be
soldered with their proper polarity. Please do not throw the leads that you have just cut since you are going to use them for your jumpers (recycle!).
The 7806 regulator chip was also bent for the whole circuit to fit in my robot. Since I could not find a heat sink that was thin and small enough for the whole circuit to fit, I made my own heat sink by using a small sheet of metal .
Almost everything is uniform in values. The diodes are all the same, and also the resistors.
The 7806 regulator chip was also bent for the whole circuit to fit in my robot. Since I could not find a heat sink that was thin and small enough for the whole circuit to fit, I made my own heat sink by using a small sheet of metal .
Almost everything is uniform in values. The diodes are all the same, and also the resistors.
Step 4: Installation of Motor Driver
The whole thing should
fit snugly on top of your Arduino board, before powering it, be sure to
check that nothing protrudes on your board that could cause short
circuiting between both boards (crystal, Atmega Chip, IDE, USB, Pins
& etc...)
Anyways, the motor outputs doesn't have a label of polarity, it's all about your codes, it has a reverse function, that's why the output polarity is interchangeable.
For the power, the left side of the terminal block is the positive and the right is the negative. There's no need for connecting a power cable to your Arduino since the 6v regulated power supply of the Motor driver circuit is connected to the "vin" pin of your Arduino board. The power input should now be connected to your Motor Driver circuit instead of the Arduino's DC Jack.
Anyways, the motor outputs doesn't have a label of polarity, it's all about your codes, it has a reverse function, that's why the output polarity is interchangeable.
For the power, the left side of the terminal block is the positive and the right is the negative. There's no need for connecting a power cable to your Arduino since the 6v regulated power supply of the Motor driver circuit is connected to the "vin" pin of your Arduino board. The power input should now be connected to your Motor Driver circuit instead of the Arduino's DC Jack.
Step 5: Testing Your Motor Driver (Programming & Codes)
Here's an Arduino code used to TEST the motor driver circuit.
There are two options, it's either your copy and paste it or just
download the Arduino file below, please do not remove the file from the
folder after extracting, since the file will corrupt.
Movements After Observing:
1st.) Forward Clockwise Motor Movement (slow)
2nd.) Forward Clockwise Motor Movement (medium)
3rd.) Forward Clockwise Motor Movement (fast)
4th.) Complete Stop
5th.) Reverse Counter-clockwise Motor Movement (medium)
Here's A Video On How The Codes Would Work: (Use headphones to hear the motors)
int outPin = 5;
int outPin2 = 6;
int outPin4 = 10;
int outPin3 = 11;
void setup()
{
Serial.begin(9600); // setup serial
pinMode(outPin, OUTPUT);
pinMode(outPin2, OUTPUT);
pinMode(outPin3, OUTPUT);
pinMode(outPin4, OUTPUT);
}
void loop()
{
delay(3000);
analogWrite(outPin, 50);
digitalWrite(outPin2, LOW);
analogWrite(outPin3, 50);
digitalWrite(outPin4, LOW);
Serial.print(" ");
Serial.print("slow");
delay(3000);
analogWrite(outPin, 150);
digitalWrite(outPin2, LOW);
analogWrite(outPin3, 150);
digitalWrite(outPin4, LOW);
Serial.print(" ");
Serial.print("med");
delay(3000);
analogWrite(outPin, 255);
digitalWrite(outPin2, LOW);
analogWrite(outPin3, 255);
digitalWrite(outPin4, LOW);
Serial.print(" ");
Serial.print("fast");
delay(3000);
analogWrite(outPin, 0);
digitalWrite(outPin2, LOW);
analogWrite(outPin3, 0);
digitalWrite(outPin4, LOW);
Serial.print(" ");
Serial.print("stop");
delay(3000);
analogWrite(outPin2, 100);
digitalWrite(outPin, LOW);
analogWrite(outPin4, 100);
digitalWrite(outPin3, LOW);
Serial.print(" ");
Serial.print("backwards");
delay(3000);
analogWrite(outPin, 0);
digitalWrite(outPin2, LOW);
analogWrite(outPin3, 0);
digitalWrite(outPin4, LOW);
Serial.print(" ");
Serial.print("stop");
}
Movements After Observing:
1st.) Forward Clockwise Motor Movement (slow)
2nd.) Forward Clockwise Motor Movement (medium)
3rd.) Forward Clockwise Motor Movement (fast)
4th.) Complete Stop
5th.) Reverse Counter-clockwise Motor Movement (medium)
Here's A Video On How The Codes Would Work: (Use headphones to hear the motors)
int outPin = 5;
int outPin2 = 6;
int outPin4 = 10;
int outPin3 = 11;
void setup()
{
Serial.begin(9600); // setup serial
pinMode(outPin, OUTPUT);
pinMode(outPin2, OUTPUT);
pinMode(outPin3, OUTPUT);
pinMode(outPin4, OUTPUT);
}
void loop()
{
delay(3000);
analogWrite(outPin, 50);
digitalWrite(outPin2, LOW);
analogWrite(outPin3, 50);
digitalWrite(outPin4, LOW);
Serial.print(" ");
Serial.print("slow");
delay(3000);
analogWrite(outPin, 150);
digitalWrite(outPin2, LOW);
analogWrite(outPin3, 150);
digitalWrite(outPin4, LOW);
Serial.print(" ");
Serial.print("med");
delay(3000);
analogWrite(outPin, 255);
digitalWrite(outPin2, LOW);
analogWrite(outPin3, 255);
digitalWrite(outPin4, LOW);
Serial.print(" ");
Serial.print("fast");
delay(3000);
analogWrite(outPin, 0);
digitalWrite(outPin2, LOW);
analogWrite(outPin3, 0);
digitalWrite(outPin4, LOW);
Serial.print(" ");
Serial.print("stop");
delay(3000);
analogWrite(outPin2, 100);
digitalWrite(outPin, LOW);
analogWrite(outPin4, 100);
digitalWrite(outPin3, LOW);
Serial.print(" ");
Serial.print("backwards");
delay(3000);
analogWrite(outPin, 0);
digitalWrite(outPin2, LOW);
analogWrite(outPin3, 0);
digitalWrite(outPin4, LOW);
Serial.print(" ");
Serial.print("stop");
}
No comments:
Post a Comment