Introduction: MIDI Keyboard
My background in music production inspired me to create my own MIDI keyboard. MIDI keyboards are essential in the music creation process and can be found in every music studio. Almost every modern song we listen to consists of MIDI signals. The advantage here is that you can access the biggest and best sample libraries and virtual instruments by only using your laptop and a MIDI controller.
Supplies
Step 1: Planning
The first step was to decide the shape of the MIDI Keyboard. The "console box" template on Festi's Boxes.py had the perfect shape for a small on desk MIDI device. However, I changed the length of the size from 100mm to 200mm to give it enough space for the actual keyboard and the microcontroller and cables.
With Adobe Illustrator I changed the stroke size to 0.01mm and the color to RGB Red, so the Laser cutter could recognise the shape.
For the keyboard I used my own design which was also done with Adobe Illustrator. A basic 12 note keyboard layout was the foundation for my design. Note that the stroke color and size was not changed because the laser cutter engraved the keyboard on the wood.
Step 2: Cutting
A Trotec laser cutter was used to cut out the design. The material was 1/4" baltic birch. Several test cuts were made on cardboard first.
Step 3: Assembly
The different parts were glued together with wood glue, except for the top part which represents the lid. Through that lid the electronic was places inside, providing enough space for the alligator clips. For the keyboard part, first the copper tape was placed on each key and then the screw through the copper tape. The screws serve the purpose of making it easier for the alligator clips to attach. Additionally, another layer of copper tape was placed on top of the screw for more stability. Inside the box is the Rasperry Pi Pico on a breadboard attached to the MPR121Touchpad with alligator clips.
Step 4: Testing
Download the following code.py and load it up to MuEditor. It should create a new MIDI channel which will be recognised by your audio software (also known as "DAW"). For this example I selected Logic Pro but any other digital audio workstation (DAW) should work as well as MIDI is a universal language. Create a software instrument in your DAW and start jamming!
Step 5: Code
# Note: This program has set the keyboard to the C4 octave, you can change that using the MIDI note map
import board, time
# Pico MPR121 Debouncing Touchpads
import adafruit_mpr121
from adafruit_debouncer import Button
i2c = board.STEMMA_I2C()
touch_pad = adafruit_mpr121.MPR121(i2c) #12 touchpads
# For loop to create pads list with (debounced) Buttons
pads = []
for t_pad in touch_pad:
pads.append(Button(t_pad, value_when_pressed = True))
#MIDI
import usb_midi
import adafruit_midi
from adafruit_midi.note_on import NoteOn
from adafruit_midi.note_off import NoteOff
from adafruit_midi.pitch_bend import PitchBend
from adafruit_midi.control_change import ControlChange
midi = adafruit_midi.MIDI(midi_out=usb_midi.ports[1], out_channel=0)
print("Midi test")
print("Default output MIDI channel:", midi.out_channel + 1)
while True:
for i in range(len(pads)):
pads[i].update() # gets current state of each debounced pad
if pads[i].pressed:
print(f"You touched pad number {i}!")
# 72 = C4, 60 = C3 (always +/- 12 to change the octave)
midi.send([NoteOn(72+i, 80), PitchBend(8192)]) # No PitchBend at 8192 (represents the middle vlaue from 0 to 16383)
if pads[i].released:
print(f"You let go of pad number {i}!")
midi.send([NoteOff(72+i, 80), PitchBend(8192)])