Tinkering workshop

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Yoana:

introduction on Adafruit Circuit Playground Express

install CircuitPython

install mu editor

Interacting to the Serial Console

The REPL

short cuts:

Indentation and commenting options

Python programs are Space holder Character Sensitive.

To indent the three lines, I selected them all and then pressed the Tab key.

To unindent, select some lines and press Shift-Tab. For commenting: select lines and press command(control)-k

http://interactionstation.wdka.hro.nl/wiki/Cpx-basic


Nan== install library..

examples:

library CircuitPython Made Easy

1. Smiley face with NeoPixels


2. Capacitive Touch & NeoPixels

3. Play audio file

4. Drum machine

5. final infrared tagging games(maybe)



timing / schedule

start 13:00 end 17:00


13:00 - 14:00 Yoana introduction part

14:00 - 14:15 - break

14:15 - 16:00 Nan's part

16:00 - 16:15 break

16:15 - 17:00 Play

3. Hello, World!

In the code area, where it says, # Write your code here :-), write the following code:

print( 8 )

Then click the Save button to save the code and run it on the CircuitPlayground.

You should see this message appear in the Serial Dialogue Panel:

code.py output: 8

Change the message to something else. If you want to print characters instead of numbers, you must use quotation marks.

print( "hello" )

Let's program the device to print two things, with a time delay in between the two print statements:

import time

print( "hello" )

time.sleep( 0.5 )

print( "Nan" )

Now let's make a loop, so the message will be running forever:

import time

while True:

 print( "hello" )
 time.sleep( 0.5 )
 print( "Nan" )



Indentation and commenting options

Python programs are Space holder Character Sensitive.

To indent the three lines, I selected them all and then pressed the Tab key.

To unindent, select some lines and press Shift-Tab. For commenting: select lines and press command(control)-k

Mu CircuitPython Mode Cheat Sheet 1.jpg


6. CircuitPython Made Easy

Libraries:

Libraries are codes other people have written for you. The libraries we will be using are included as part of the CircuitPython code, but you still must import them into your program. Other libraries, for many uses, must be downloaded and placed in a folder named lib on the CIRCUITPY drive.


CircuitPython Libraries already included in CPX, But if you are using CPB, (CPX = Circuit Playground Express, CPB = Circuit Playground Bluefruit)

you need to install CircuitPython Libraries by download the file and put them in the folder named lib on the CIRCUITPY drive.

we will useCircuitPython Made Easy libraries, a simple way to include the Circuit Playground functionality in our code.

more reference and examples:

https://learn.adafruit.com/circuitpython-made-easy-on-circuit-playground-express

code examples

Neopixel smiley face

 1from adafruit_circuitplayground import cp
 2
 3# The NeoPixels are super-bright. Change the global brightness.
 4cp.pixels.brightness = 0.3
 5
 6while True:
 7    # The smiley's eyes
 8    cp.pixels[0] = (255, 0, 0)
 9    cp.pixels[9] = (255, 0, 0)
10
11    # The smiley's mouth
12    cp.pixels[3] = (255, 0, 255)
13    cp.pixels[4] = (255, 0, 255)
14    cp.pixels[5] = (255, 0, 255)
15    cp.pixels[6] = (255, 0, 255)

touch sense

import time from adafruit_circuitplayground import cp

cp.pixels.brightness=0.6 light_color=(150,0,150) OFF=(0,0,0)

while True:

   if cp.touch_A4:
       cp.pixels[1]=light_color
   else:
       cp.pixels[1]=OFF
   time.sleep(0.1)

Drum Machine

https://learn.adafruit.com/adafruit-circuit-playground-express/playground-drum-machine


 1#light meter
 2
 3import time
 4from adafruit_circuitplayground import cp
 5cp.pixels.auto_write = False
 6cp.pixels.brightness = 0.3
 7 
 8 
 9def scale_range(value):
10#"""Scale a value from 0-320 (light range) to 0-9 (NeoPixel range).
11#    Allows remapping light value to pixel position."""
12    return round(value / 280 * 9)
13    
14while True:
15    peak = scale_range(cp.light)
16    print(cp.light)
17    print(int(peak))
18 
19    for i in range(10):
20        if i <= peak:
21            cp.pixels[i] = (0, 255, 255)
22        else:
23            cp.pixels[i] = (0, 0, 0)
24    cp.pixels.show()
25    time.sleep(0.2)



touch sense

 1from adafruit_circuitplayground import cp
 2 
 3cp.pixels.brightness = 0.3
 4 
 5while True:
 6    if cp.touch_A1:
 7        print("Touched A1!")
 8        cp.pixels[6] = (255, 0, 0)
 9    if cp.touch_A2:
10        print("Touched A2!")
11        cp.pixels[8] = (210, 45, 0)
12    if cp.touch_A3:
13        print("Touched A3!")
14        cp.pixels[9] = (155, 100, 0)
15    if cp.touch_A4:
16        print("Touched A4!")
17        cp.pixels[0] = (0, 255, 0)
18    if cp.touch_A5:
19        print("Touched A5!")
20        cp.pixels[1] = (0, 135, 125)
21    if cp.touch_A6:
22        print("Touched A6!")
23        cp.pixels[3] = (0, 0, 255)
24    if cp.touch_TX:
25        print("Touched TX!")
26        cp.pixels[4] = (100, 0, 155)
27    time.sleep(0.1)

Play audio file

 1#Copy the "dip.wav" file to your CIRCUITPY drive.
 2 
 3#Once the file is copied, this example plays a wav file!"""
 4from adafruit_circuitplayground import cp
 5cp.pixels.brightness = 0.3
 6
 7while True:
 8    if cp.touch_A1:
 9        print("Touched A1!")
10        cp.pixels[6] = (255, 0, 0)
11        cp.play_file("dip.wav")

infrared tagging game:

  1from adafruit_circuitplayground.express import cpx
  2import board
  3from adafruit_circuitplayground import cp
  4import time
  5import pulseio
  6import array
  7import touchio
  8import digitalio
  9
 10# change into your own color by changing the rgb value
 11myID_colour=(0,255,255)
 12# NeoPixel brightness
 13
 14# Create IR input, maximum of 59 bits.
 15pulseIn = pulseio.PulseIn(board.IR_RX, maxlen=59, idle_state=True)
 16# Clears any artifacts
 17pulseIn.clear()
 18pulseIn.resume()
 19
 20# Creates IR output pulse
 21pwm = pulseio.PWMOut(board.IR_TX, frequency=38000, duty_cycle=2 ** 15)
 22pulse = pulseio.PulseOut(pwm)
 23
 24# Array for button A pulse, this is the pulse output when the button is pressed
 25# Inputs are compared against this same array
 26# array.array('H', [x]) must be used for IR pulse arrays when using pulseio
 27# indented to multiple lines so its easier to see
 28pulse_A = array.array('H', [1000, 3800, 65000, 950, 300, 200, 300, 1000, 350, 175,
 29    275, 215, 275, 250, 275, 215, 275, 225, 275, 215, 275, 1000, 300, 225, 275,
 30    950, 300, 950, 300, 1000, 300, 950, 300, 250, 275, 700, 300, 950, 300, 450,
 31    300, 475, 300, 215, 275, 725, 300, 950, 300, 200, 300, 715, 325, 900, 315,
 32    425, 315, 1000, 65000])
 33pulse_B = array.array('H', [1000, 3800, 65000, 960, 300, 200, 300, 950, 350, 190,
 34    215, 245, 300, 225, 275, 225, 275, 215, 275, 200, 300, 700, 300, 200, 300,
 35    700, 300, 1000, 315, 675, 300, 1000, 300, 200, 300, 700, 300, 950, 300,
 36    950, 300, 700, 300, 700, 300, 450, 300, 475, 275, 715, 300, 225, 275, 450,
 37    300, 450, 300, 1000, 65000])
 38
 39# Fuzzy pulse comparison function. Fuzzyness is % error
 40def fuzzy_pulse_compare(pulse1, pulse2, fuzzyness=0.5):
 41    if len(pulse1) != len(pulse2):
 42        return False
 43    for i in range(len(pulse1)):
 44        threshold = int(pulse1[i] * fuzzyness)
 45        if abs(pulse1[i] - pulse2[i]) > threshold:
 46            return False
 47    return True
 48
 49# Initializes NeoPixel ring
 50cp.pixels.brightness= 0.2
 51# my id color
 52cp.pixels.fill(myID_colour)
 53#cp.pixels.show()
 54
 55# serial print once when activated
 56print('IR Activated!')
 57
 58while True:
 59# when button is pressed, send IR pulse
 60# detection is paused then cleared and resumed after a short pause
 61# this prevents reflected detection of own IR
 62    while cp.touch_A3:
 63        pulseIn.pause()  # pauses IR detection
 64        pulse.send(pulse_A)  # sends IR pulse
 65        time.sleep(.2)  # wait so pulses dont run together
 66        pulseIn.clear()  # clear any detected pulses to remove partial artifacts
 67        pulseIn.resume()  # resumes IR detection
 68    while cp.touch_A4:
 69        pulseIn.pause()
 70        pulse.send(pulse_B)
 71        time.sleep(.2)
 72        pulseIn.clear()
 73        pulseIn.resume()
 74# Wait for a pulse to be detected of desired length
 75    while len(pulseIn) >= 59:  # our array is 59 bytes so anything shorter ignore
 76        pulseIn.pause()
 77# converts pulseIn raw data into useable array
 78        detected = array.array('H', [pulseIn[x] for x in range(len(pulseIn))])
 79#        print(len(pulseIn))
 80#        print(detected)
 81
 82    # Got a pulse, now compare against stored pulse_A and pulse_B
 83        if fuzzy_pulse_compare(pulse_A, detected):
 84            print('Received correct Button A control press!')
 85            t_end = time.monotonic() + 0.8  # saves time 2 seconds in the future
 86            while time.monotonic() < t_end: # plays sparkels until time is up
 87                for x in range(10):
 88                    if x!= 0 and x!=2 and x!=4:
 89                        cp.pixels[x]=(250, 55, 100)
 90
 91                    else:
 92                        cp.pixels[x]=(0, 0, 0)
 93                cp.play_file("kiss.wav")
 94                time.sleep(1.5)
 95                cp.pixels.fill(myID_colour)
 96
 97        if fuzzy_pulse_compare(pulse_B, detected):
 98            print('Received correct Button B control press!')
 99            t_end = time.monotonic() + 0.8
100            while time.monotonic() < t_end:
101                #rainbow_cycle(.001)
102                cp.pixels.fill((255, 0, 0))
103                cp.play_file("explosion.wav")
104                time.sleep(0.5)
105                cp.pixels.fill(myID_colour)
106
107
108
109        time.sleep(.1)
110        pulseIn.clear()
111        pulseIn.resume()