Communication over Wires

Chapter 1 image


Everything is connected nowadays! Computers and devices connect to each other to form networks. And these networks connect to form the Internet. When we say computers or devices, these can be anything from a traditional laptop to a cellphone, to a washing machine, to a humidity sensor. Of course, it can also be your micro:bit. More and more, the Internet is becoming an Internet of Things.

In this chapter, you will form your own network using wires to connect two micro:bits. Doing this, you will learn:

  • the concept of a communications medium, and signals

  • the concept of binary and bit

  • the concept of a network

What you’ll need?

2 micro:bits
4 crocodile clip leads
1 battery holder, and 2 AAA batteries
1 teammate


For two micro:bits to be able to send messages to each other, they somehow need to be connected, whether by wires or wirelessly - we call this a communications medium.

A message could be a string like “Hello”, a number like “9”, or an icon image. The micro:bits convert each message to a signal to send it over the communications medium.

Definition 1: Communications medium

A communication medium is the physical path over which a signal is transmitted.

Definition 2: Signal

Signals are the electromagnetic voltages or waves transmitted on a physical wired or wireless medium.

For example, take the case when we say “Hello” into a landline telephone. The telephone handset converts the sounds into an electrical voltage signal. Then, this signal is transmitted to the receiving telephone by wires; and at the receiver, it is converted back into sound.

Exercise 1

What is the wireless physical medium that makes radio communication possible?

Computers, and also your micro:bit, cannot process signals without converting them to binary data: 0s and 1s. Also, the binary data processed by computers need to be converted into signals before they can travel a communication medium.

Definition 3: Bit

A bit is the smallest unit of data in a computer. It is like an atom. A bit can be either a 1 or a 0.

A group of 8 bits is a byte. Table [tab:bit] shows other example groupings.

Name Size
Byte (B) 8 bits
Kilobyte (KB) 1024 bytes
Megabyte (MB) 1024 kilobytes
Gigabyte (GB) 1024 megabytes
Terabyte (TB) 1024 gigabytes

By connecting computers or any device through different communications mediums, we create networks.

Definition 4: Network

A computer network is a collection of computers or devices, which are connected to communicate with each other. In a computer network, there is at least two computers. Two or more networks can connect to form a larger network: a network of networks. Internet is a massive network of networks!

In this chapter, you will create a network of two micro:bits, connected via wires.

Programming: A Simple Heart Transfer

In this section, you will connect two micro:bits via wires. You will send a Heart icon from one micro:bit to another. The figure below shows how a heart icon should look like on the micro:bit display 1.

Micro:bit displaying a heart icon.

Figure 1: Micro:bit displaying a heart icon

This activity is best done with a teammate. In the following, you will go through four tasks to program your micro:bits.

Task 1: Watch the “Simple Heart Transfer”

Description: We have created a video to show how your connections and program should work in this activity. See the video at Simple Heart Transfer.

Instruction: Watch the Simple Heart Transfer in the video.

Important: Do not skip this task. It will help you to test whether the files you downloaded for Task 2 work. It will also help you to write your program for this chapter.

Task 2: Connect your micro:bits and test telegraph

Description: You will connect your micro:bits using wires, and use a program to check the connections. You can follow the instructions below, or there is a more detailed step-by-step instructions in the Micro-bit telegraph activity2 on the micro:bit website.

Instruction: Using crocodile clips, connect the 3V pin between the two micro:bits, and connect the GND pins. Then connect pin 1 on one micro:bit to pin 2, and vice-versa. Be careful to get the crocodile clip connections right: two of the wires connect straight (3V-to-3V and GND-to-GND) but the other two cross over (1-to-2 and 2-to-1).

See the figure showing connections for an example, and look at the colours carefully (you don’t need to use the same colours of course, but they must make the same connections).

Wiring micro:bits.Two of the wires connect straight(3V-to-3V and GND-to-GND) but the other two cross over (1-to-2 and 2-to-1).

Figure 2: Wiring micro:bits. Two of the wires connect straight (3V-to-3V and GND-to-GND) but the other two cross over (1-to-2 and 2-to-1)

To test, use the program from the figure showing the Telegraph program; press button A on each micro:bit and check that the LED illuminates on the other one. You will use the blocks from the Pins menu. This menu is under Advanced. Click on the More link to see all the options.

let signal = 0
input.onButtonPressed(Button.A, function () {
    pins.digitalWritePin(DigitalPin.P1, 1)
    pins.digitalWritePin(DigitalPin.P1, 0)
basic.forever(function () {
    signal = pins.digitalReadPin(DigitalPin.P2)
    if (signal == 1) {
        led.plot(2, 2)
    } else {
        led.unplot(2, 2)

Figure 3: Telegraph program. Pressing button A sends a signal to the other side using Pin 1. The receiver micro:bit listens on Pin 2 to check if a signal is received. If there is a signal, it lights up the (2,2) pixel on the display.

Task 3: Test “Simple Heart Transfer” Hex files

Description: We provided two files, named microbit1_wired_simpleheart_secret.hex and microbit2_wired_simpleheart_secret.hex in this folder, for you to test how the final program should work. These files will run on your micro:bits, but you will not be able to display the code using the JavaScript Blocks editor.

Instruction: Download the Simple Heart Transfer code into your micro:bits. There are two different hex files for micro:bit 1 and micro:bit 2. Test the program by tilting your micro:bits and checking when the heart icon is displayed.

Task 4: Program a heart transfer

Description: In this task, you will program your micro:bits to get a similar behaviour to what you observed in the Tasks 2 and 3. To do this task, you will need to think about the following questions:

  1. Which input will the micro:bits react to in your program?

  2. How do the microbits send data to each other?

  3. Hint: Do you think they are sending each other an actual Heart icon?

Instruction: For question 1, look at the options under the JavaScript Blocks editor Input menu. For question 2, use the example Telegraph program above. For question 3, here is another big hint. Hint: Assume micro:bit 2 knows that it will be receiving a Heart icon from micro:bit 1.

Program your micro:bit 1 so that:

  1. It displays a heart icon until it is tilted over micro:bit 2.

  2. When tilted over micro:bit 2, it sends a pulse to micro:bit 2 over the correct pin.

  3. When micro:bit 1 receives a pulse on its correct pin, it displays a heart icon .

Program your micro:bit 2 so that:

  1. It displays a heart icon when it receives a pulse on its correct pin.

  2. When tilted over micro:bit 1, it sends a pulse to micro:bit 2 over the correct pin.

Extended activity

Exercise 2

Watch the Wired_pixel_by_pixel_heart.m4v. Based on this video, discuss with your teammate how you can send more complex data across wires. Make a proposal and discuss with others.

Exercise 3

Watch the two videos under the Resources section. How are they related to your activity? Discuss.


  1. What is a bit?

  2. How many bits are there in a kilobyte?

  3. Explain the use of Ground (GND) and 3V pins in your micro:bit.

  4. How many bits did you send to the receiver in your “Simple Heart Transfer” program?

  5. How are the bits in your program sent over the wire in your program?


  1. This image is by micro:bit Educational Foundation at

  2. Microbit telegraph activity