How to Control Stepper Motor using Potentiometer and Arduino
Controlling Stepper Motor using
Potentiometer and Arduino
Stepper motors are increasingly taking its position in the world of the
electronics.
Starting from a normal
Surveillance camera to a complicated CNC machines/Robot these Stepper Motors are used everywhere as
actuators since they provide accurate controlling. In this tutorial we will learn about the most
commonly/cheaply available stepper motor 28-BYJ48 and how to interface it with Arduinousing ULN2003
stepper module.
In
last project we have simply Interfaced
Stepper Motor with Arduino, where you can rotate the stepper
motor by entering the rotation angle in Serial Monitor of Arduino. Here in this project, we will Rotate the
Stepper Motor using Potentiometer and Arduino, like if you turn the
potentiometer clockwise then stepper will rotate clockwise and if you turn
potentiometer anticlockwise then it will rotate anticlockwise.
Stepper Motors:
Let us
take a look at this 28-BYJ48 Stepper motor.
Okay,
so unlike a normal DC motor this one has five wires of all fancy colors coming
out of it and why is it so? To understand this we should first know how a
stepper works and what its specialty is. First of all steppers motors do not rotate, they
step and so they also known as step motors. Meaning, they will move only one step at a time. These motors have a sequence of coils present in
them and these coils have to be energized in a particular fashion to make the
motor rotate.
When each coil is being
energized the motor takes a step and a sequence of energization will make the
motor take continuous steps, thus making it to rotate. Let us take a look at the coils present inside the
motor to know exactly know from where these wires come from.
As you
can see the motor has Unipolar 5-lead
coil arrangement.
There are four coils which
have to be energized in a particular sequence. The Red wires will be supplied with +5V and the remaining four wires will be pulled to
ground for triggering the respective coil. We use a microcontroller like Arduino energize these coils in a
particular sequence and make the motor perform the required number of steps.
So
now, why is this motor called the 28-BYJ48? Seriously!!! I don’t know. There
is no technical reason for this motor for being named so; maybe we should dive
much deeper into it. Let us look at some of the
important technical data obtained from the datasheet of this motor in the
picture below.
Technical Data from the
Datasheet of Stepper Motor
That
is a head full of information, but we need to look at few important ones to
know what type of stepper we are using so that we can program it efficiently. First we know that it is a 5V Stepper motor since
we energize the Red wire with 5V. Then,
we also know that it is a four phase stepper motor since it had four coils in
it.
Now, the gear ratio is given
to be 1:64. This
means the shaft that you see outside will make one complete rotation only if
the motor inside rotates for 64 times. This is because of the gears that are connected between the
motor and output shaft, these gears help in increasing the torque.
Another
important data to notice is the Stride Angle: 5.625°/64. This means that the motor when operates in 8-step sequence will move 5.625 degree for each step and it will take 64 steps
(5.625*64=360) to complete one full rotation.
Calculating the Steps per Revolution for Stepper
Motor:
It is
important to know how to calculate the steps per Revolution for your stepper
motor because only then you can program it effectively.
In
Arduino we will be operating the motor in 4-step sequence so the stride angle will be 11.25° since it is 5.625°(given
in datasheet)
for 8 step sequence it
will be 11.25° (5.625*2=11.25).
Steps per revolution = 360/step angle
Here,
360/11.25 = 32 steps per revolution.
Why so we need Driver modules for Stepper motors?
Most stepper
motors will operate only with the help of a driver module. This is because the controller module (In our case Arduino) will not be able to provide enough current from
its I/O pins for the motor to operate. So we will use an external module like ULN2003 module
as stepper motor driver. There
are a many types of driver module and the rating of one will change based on
the type of motor used. The primary principle for all
driver modules will be to source/sink
enough current for the motor to operate.
Circuit Diagram for Rotating Stepper
Motor using Potentiometer:
The
circuit Diagram for the Controlling Stepper Motor using Potentiometer
and Arduino is shown above. We
have used the 28BYJ-48 Stepper motor and the
ULN2003 Driver module. To energise the four coils of
the stepper motor we are using the digital pins 8,9,10 and 11. The driver module is powered by the 5V pin of the
Arduino Board. A potentiometer is connected to A0 based in
whose values we will rotate the Stepper motor.
But,
power the driver with External Power supply when you are connecting some load
to the steppe motor. Since I am just using the
motor for demonstration purpose I have used the +5V rail of the Arduino Board. Also remember to connect the Ground of the Arduino
with the ground of the Driver module.
Code for Arduino Board:
Before
we start programming with our Arduino, let us understand what should actually
happen inside the program. As
said earlier we will be using 4-step
sequence method so we will have four steps to perform for making one complete
rotation.
Step
|
Pin
Energized
|
Coils
Energized
|
Step
1
|
8
and 9
|
A
and B
|
Step
2
|
9
and 10
|
B
and C
|
Step
3
|
10
and 11
|
C
and D
|
Step
4
|
11
and 8
|
D
and A
|
The
Driver module will have four LED using which we can check which coil is being
energised at any given time. The
complete demonstration video can be found at the end of
this tutorial.
In
this tutorial we are going to program the Arduino in such a way that we can turn
the potentiometer connected to pin A0 and control the direction of the Stepper
motor.
The complete program can be
found at the end of the tutorial few important lines are explained below.
The
number of steps per revolution for our stepper motor was calculated to be 32;
hence we enter that as shown in the line below
#define
STEPS 32
Next
you have to create instances in which we specify the pins to which we have
connected the Stepper motor.
Stepper
stepper (STEPS, 8, 10, 9, 11);
Note: The pins number are
disordered as 8,10,9,11 on purpose. You
have to follow the same pattern even if you change the pins to which your motor
is connected.
Since
we are using the Arduino stepper library, we can set the speed of the motor
using the below line. The speed can range between 0
to 200 for 28-BYJ48 stepper motors.
stepper.setSpeed(200);
Now, to make the motor move one step clockwise we
can use the following line.
stepper.step(1);
To make the motor move one step anti-clockwise we can use the following line.
stepper.step(-1);
In our program we will read the value of the
Analog pin A0 and compare it with previous value (Pval). If it
has increased we move 5 steps in clockwise and if it is decreased then we move
5 steps in anti-clockwise.
potVal
= map(analogRead(A0),0,1024,0,500);
if
(potVal>Pval)
stepper.step(5);
if
(potVal<Pval)
stepper.step(-5);
Pval = potVal;
Working:
Once the connection is made the hardware should
look something like this in the picture below.
Now, upload the below program in your Arduino UNO
and open the serial monitor. As
discussed earlier you have to rotate the potentiometer to control the
rotation of the Stepper motor. Rotating
it in clockwise will turn the stepper motor in clockwise direction and vice
versa.
Hope you understood the project and enjoyed
building it.
The complete working of the
project is shown in the video below. If you have any doubts post them on the comment
section below or on our forums.
Demo & Code
How to Control Stepper Motor using Potentiometer and Arduino
Reviewed by XXX
on
สิงหาคม 27, 2560
Rating:
Reviewed by XXX
on
สิงหาคม 27, 2560
Rating:
ไม่มีความคิดเห็น