What is a Mouth Mouse / Mundmaus?

The mouth mouse is intended for handicapped people, which suffer for instance tetraplegia. Instead of using their extremities, they use their mouth and tounge inlcuding puffing to control the mouse motion and clicking.

What is tetraplegia?

These people for instance cannot move any of their extermities up to very severe cases, where they can neither move nor hold their head, which means their available movements are very limited. The extreme case, where people cannot move or hold their head, their head needs to be fixed with a strap band. They are only able to do facials, use their mouth, their tounge. These people are also artificially respirated, which means they cannot puff air, but are limited to use the available air in their mouth and contract their cheeks to simulate puffing.

What is the intention of this project?

Such commercial mice can be very expensive up to 2.000 EUR (what I have seen). Not all health insurances pay for this. They pay in Germany, Switzerland, Denmark, Norway and Sweden for instance but not in Austria. This mouse is approx. 32 EUR (ESP32 chip [10 EUR], joystick [2 EUR], water flow sensor [10 EUR], wires [7 EUR], silicon tube [3 EUR]). The code to make this work is for free and will be kept freely available forever. It is intended to make this available at no cost, but the parts one needs to buy. It is kept very simplistic in terms of required parts, which are available everywhere to make sure everyone has access and is able to build this.

What are the features of the mouse?

• Bluetooth connectivity, no cables to the PC, hence you can use distant large screens, like the TV with a Raspberry for instance, which has bluetooth build in.
• Puffing is clicking in click mode. In Drag'n'Drop mode (activated by pressing the joystick down - feels like a click) one puff picks the object, like a window or a card in a card game for instance. A second puff will release it where the pointer was moved to.
• The joystick is used to move the mouse pointer.

Why bluetooth?

Simply because the ESP32 cannot be run as a USB device like the pyboard, hence I had to find an alternative. Eventually this is more practical, since less cabling and longer USB cables may result into problems with a Microcomputer like this.

How did I use it?

I used a Raspberry PI 3B running Raspbian as the computer connected to the TV. The mouse you will build is then connected via Bluetooth to the Raspberry. It will always automatically reconnect, hence super simple to use. If you opt for the Display you will see status messages.

Can this be used in a different setup?

Absolutely. Assume you can use your fingers, but not move your arm, the setup can be adjusted to use the joystick for clicking and double blick, also drag and drop. Alternatively, separate buttons for the other hand can be added for left and right click, also for instance a third one for drag and drop if holding a button is too difficult.

Can I contribute?

Absolutely. I am not a professionial developer and appreciate coding feedback, input and suggestions as well as contributions. If there are other ideas or better ideas, let's collaborate and improve life of severly impacted humand beings instead of looking for their money!

Technologies

Everything is based on an ESP32 (think of it as a Microcomputer) and MicroPython as the programming language. You will need to get the following:

• ESP32 - 10 EUR
• Thumb Joystick - 2 EUR
• Water Flow Sensor - 10 EUR
• DuPont Cables also names Jumper Wires - 7 EUR
• T-fitting from Gardena to sit on top if the Joystick instead of the thumb piece, glue with hot melt gun (Heißklebepistole) and seal before the T connection to the water flow sensor. Remove lower part, see picture - 2.50 EUR per piece
• Tube from water flow sensor (inner diameter 7mm), see picture. I used a piece of the (german: Rektalkatheter) rectal catheter
• Silicon tube from rectal catheter tube after water flow sensor to the T-fitting from Gardena - 3 EUR. This is quite important, since the inner diameter needs to fit the T-fitting, must be wide enough for easy puffing because of resistance. Silikon keeps it very flexible to not influence and put pressure on the Jostick.
• Optional: Display - 7.50 EUR. If you use the display you can see if bluetooth (ble) is successfully connected, amount of clicks and if the mode was switched to drag and drop or is in regular clicking mode.
• Optional: Microphone Stand - 15 EUR
• Optional: Raspberry PI 4 with 4GB at approx 60 EUR - no case, power supply, neither HDMI cable included. Sets vary between 100-120 EUR.
• Optional: Battery for ESP32 instead of USB cable - 10.50 EUR, alternative with 4 Batteries at 14.90 EUR. This is excluding the batteries itself. Make sure to get 18650 - I ordered LG 18650 HG2 and got 6 for 25.50 EUR. I have not yet tested them and have thus no experience how long either set may last.
• Optional: Bluetooth USB Stick for PC - 12 EUR

Credits

• the ST7735.py file is orignally from boochow's repo. I made no changes.
• the sysfont.py is from GuyCarver's repo
• the bluetooth code I assembled from samples from MicroPython. Thank you very much for this!!!

Setup

• Follow the fritzing for cabling the different pieces Ideally run Linux for the next steps - use the Raspberry for instance
• Download all .py files from this repo into a folder
• Download the MicroPython firmware - I used the IDF4 latest unstable version, which ran just and has all features used in this project per 7th January 2021.
• Run following commands to install necessary software

sudo apt install screen
sudo pip3 install rshell
sudo pip3 install esptool

Next you need to flash the ESP32 chip. Any commands you run wrong can damage or destroy your ESP32. Running it per below is your own risk. MicroPython may have changed the instructions during me writing this up to now, hence please double check on their webpage. Connect the ESP32 via a Micro USB cable to the Raspberry or any other PC running Linux. If this is the first time you put MicroPython on the ESP32, you need to erase the flash as per below. If you have multiple USB to Serial devices connected your ttyUSB[n] may have a different number! You may need to press the "boot" button the the ESP32 chip in case the esptool fails with reading errors.

sudo esptool.py --chip esp32 --port /dev/ttyUSB0 erase_flash

After that you can upload the MicroPython firmware you previously downloaded. Make sure to adjust the directory if necessary.

sudo esptool.py --chip esp32 --port /dev/ttyUSB0 --baud 460800 write_flash -z 0x1000 esp32-idf3-20210107-unstable-v1.13-268-gf7aafc062.bin

Now since the "operating system" is successfully uploaded, you need to copy all .py files to the chip, which is only one command, which mirrors the folder you downloaded the files to. You need to be in the folder or replace the "." after -m with the correct path.

sudo rshell --buffer-size=30 -p /dev/ttyUSB0 rsync -m . /pyboard

If you cabled everything correctly you can follow your mouse booting using screen:

sudo screen /dev/ttyUSB0 115200

To exit screen and release the block on the tty for an additional file sync, simple press CTRL-A followed by k and confirm with y Last not least we need to connect the mouse to the Raspberry. You need at least kernel 5.10. Version 5.4 is buggy. You can upgrade from 5.4 to 5.10 using rpi-update. There will be warnings you will need to accept. To connect the mouse we need bluetoothctl which we first need to install.

sudo apt install bluetoothctl

After that we need to trust and connect to the mouse after scanning for it. You will need to replace "mac" with the MAC address. Once bluetoothctl start the next commands are part of this extra command "shell".

bluetoothctl
scan on
trust "mac"
connect "mac"
exit

That's it. You should see the pointer moving now. You will however not see the mouse as "paired" in the bluetooth icon on the taskbar. If you pair it will not reconnect successfully after rebooting either the Raspberry or the mouse. Pairing is also not necessary for this to work.

Problems with flashing

If the flashing times out you may need to keep the "boot" button pressed until the connection is successfully established. Also never use Pin 0 - any connection to Pin 0 can cause issues with uploading or updating your py files later.

Wiring and pictures

Below you'll find how to wire everything from the individual devices to the ESP32 board and respective Pins. If you use the display you will need the "Wago Klemme" as described below. In the pictures folder you will get an impression on how to assemble everything. I used a wood piece to put everything together. I am currently working on a 3D print model with a friend to further improve the setup. Once available I will share additional pictures and the 3D model so you can either print yourself or ask somebody you know.

How to wire the joystick

Despite that the chip (KY-023) labels with 5V, 3.3V are correct and work with the settings in the joystick.py and the move ranges in main.py, so please connect to 3.3V and not 5V. If you also use the ST7735 display you will need a "Wago Klemme". This is necessary since the 5V and 3.3V Pins only exist once. The Wago Klemme will allow you to connect more than one device.

• 5V connects to the Wago Klemme which in turn connects to 3.3V.
• GND connects to any GND on the ESP32. There is no need for a Wago Klemme, since the amount of GND Pins on the ESP32 is sufficient for this project.
• VRX connects to Pin G33
• VRY connects to Pin G35
• SW connects to Pin G21

How to wire the water flow sensor

This one is pretty simple.

• Red to 5V or to a Wago Klemme if you use the display.
• Black to GND
• Yellow to G32

How to wire the display

Check the uploaded picture if you'd like else it does as:

• 3V to WAGO Klemme
• RESET to G14
• GND to GND
• LED to 5V Wago Klemme
• SDA to G23
• SCK to G18
• CS to G17
• A0 to G2

ESP32 Pin Overview

Unfortunately in German, but I am sure feasible to understand. I use ESP32s from AZ Delivery in case you want to try to find an English version.