Micropython Rotary Save

MicroPython module to read a rotary encoder.

Project README

MicroPython Rotary Encoder Driver

A MicroPython driver to read a rotary encoder. Works with Pyboard, Raspberry Pi Pico, ESP8266, and ESP32 development boards. This is a robust implementation providing effective debouncing of encoder contacts. It uses two GPIO pins configured to trigger interrupts, following Ben Buxton's implementation:

Key Implementation Features

Interrupt based

Whenever encoder pins DT and CLK change value a hardware interrupt is generated. This interrupt causes a python-based interrupt service routine (ISR) to run. The ISR interrupts normal code execution to process state changes in the encoder pins.

Transition state machine

A gray code based transition state table is used to process the DT and CLK changes. The use of the state table leads to accurate encoder counts and effective switch debouncing. Credit: Ben Buxton

File Installation

Two files are needed to use this module

platform-independent file rotary.py - a core file for all development boards
platform-specific file:
- rotary_irq_esp.py Platform-specific code for ESP8266 and ESP32 development boards
- rotary_irq_pyb.py Platform-specific code for Pyboard development boards
- rotary_irq_rp2.py Platform-specific code for Raspberry Pi Pico development boards

Copying files to development boards

Copy files to the internal MicroPython filesystem using a utility such as ampy or rshell Ampy example below for Pyboards. Note: -d1 option is often needed for ESP8266 boards

ampy -pCOMx put rotary.py
ampy -pCOMx put rotary_irq_pyb.py

mip install

Starting with MicroPython 1.20.0, it can be installed from mip via:

>>> import mip
>>> mip.install("github:miketeachman/micropython-rotary")

Or from mpremote via:

mpremote mip install github:miketeachman/micropython-rotary

Class `RotaryIRQ`

Constructor

   RotaryIRQ(
       pin_num_clk, 
       pin_num_dt, 
       min_val=0, 
       max_val=10, 
       incr=1,
       reverse=False, 
       range_mode=RotaryIRQ.RANGE_UNBOUNDED,
       pull_up=False,
       half_step=False,
       invert=False)

argument	description	value
pin_num_clk	GPIO pin connected to encoder CLK pin	integer
pin_num_dt	GPIO pin connected to encoder DT pin	integer
min_val	minimum value in the encoder range. Also the starting value	integer
max_val	maximum value in the encoder range (not used when range_mode = RANGE_UNBOUNDED)	integer
incr	amount count changes with each encoder click	integer (default=1)
reverse	reverse count direction	True or False(default)
range_mode	count behavior at min_val and max_val	RotaryIRQ.RANGE_UNBOUNDED(default) RotaryIRQ.RANGE_WRAP RotaryIRQ.RANGE_BOUNDED
pull_up	enable internal pull up resistors. Use when rotary encoder hardware lacks pull up resistors	True or False(default)
half_step	half-step mode	True or False(default)
invert	invert the CLK and DT signals. Use when encoder resting value is CLK, DT = 00	True or False(default)

range_mode	description
RotaryIRQ.RANGE_UNBOUNDED	encoder has no bounds on the counting range
RotaryIRQ.RANGE_WRAP	encoder will count up to max_val then wrap to minimum value (similar behaviour for count down)
RotaryIRQ.RANGE_BOUNDED	encoder will count up to max_val then stop. Count down stops at min_val

Methods

value() Return the encoder value

set(value=None, min_val=None, max_val=None, incr=None, reverse=None, range_mode=None) Set encoder value and internal configuration parameters. See constructor for argument descriptions. None indicates no change to the configuration parameter

Examples:

set(min_val=0, max_val=59) change encoder bounds - useful to set minutes on a clock display
set(value=6) change encoder value to 6. calling value() will now return 6

reset() set encoder value to min_val. Redundant with the addition of the set() method. Retained for backwards compatibility)

add_listener(function) add a callback function that will be called on each change of encoder count

remove_listener(function) remove a previously added callback function

close() deactivate microcontroller pins used to read encoder

Note: None of the arguments are checked for configuration errors.

Example

CLK pin attached to GPIO12
DT pin attached to GPIO13
GND pin attached to GND
+ pin attached to 3.3V
Range mode = RotaryIRQ.RANGE_WRAP
Range 0...5

import time
from rotary_irq_esp import RotaryIRQ

r = RotaryIRQ(pin_num_clk=12, 
              pin_num_dt=13, 
              min_val=0, 
              max_val=5, 
              reverse=False, 
              range_mode=RotaryIRQ.RANGE_WRAP)
              
val_old = r.value()
while True:
    val_new = r.value()
    
    if val_old != val_new:
        val_old = val_new
        print('result =', val_new)
        
    time.sleep_ms(50)

For clockwise turning the encoder will count 0,1,2,3,4,5,0,1 ...
For counter-clockwise turning the encoder will count 0,5,4,3,2,1,0,5,4 ....

Tested With:

Development Boards

Pyboard D
PYBv1.1
TinyPico
Lolin D32 (ESP32)
Lolin D32 Pro (ESP32 with 4MB PSRAM)
Adafruit Feather Huzzah ESP8266
Adafruit Feather Huzzah ESP32
Raspberry Pi Pico
Raspberry Pi Pico W

Rotary Encoders

KY-040 rotary encoder
Fermion: EC11 Rotary Encoder Module (thanks @sfblackwell)

Wiring for KY-040 encoder

Encoder Pin	Connection
+	3.3V
GND	Ground
DT	GPIO pin
CLK	GPIO pin

Recommended ESP8266 input pins

This Rotary module requires pins that support interrupts. The following ESP8266 GPIO pins are recommended for this rotary encoder module

GPIO4
GPIO5
GPIO12
GPIO13
GPIO14

The following ESP8266 GPIO pins should be used with caution. There is a risk that the state of the CLK and DT signals can affect the boot sequence. When possible, use other GPIO pins.

GPIO0 - used to detect boot-mode. Bootloader runs when pin is low during powerup.
GPIO2 - used to detect boot-mode. Attached to pull-up resistor.
GPIO15 - used to detect boot-mode. Attached to pull-down resistor.

One pin does not support interrupts.

GPIO16 - does not support interrupts.

Recommended ESP32 input pins

This Rotary module requires pins that support interrupts. All ESP32 GPIO pins support interrupts.

The following ESP32 GPIO strapping pins should be used with caution. There is a risk that the state of the CLK and DT signals can affect the boot sequence. When possible, use other GPIO pins.

GPIO0 - used to detect boot-mode. Bootloader runs when pin is low during powerup. Internal pull-up resistor.
GPIO2 - used to enter serial bootloader. Internal pull-down resistor.
GPIO4 - technical reference indicates this is a strapping pin, but usage is not described. Internal pull-down resistor.
GPIO5 - used to configure SDIO Slave. Internal pull-up resistor.
GPIO12 - used to select flash voltage. Internal pull-down resistor.
GPIO15 - used to configure silencing of boot messages. Internal pull-up resistor.

Examples

MicroPython example code is contained in the Examples folder
simple example
uasyncio example
uasyncio with classes example

Oscilloscope Captures

CLK and DT transitions captured on an oscilloscope. CLK = Yellow. DT = Blue

One clockwise step

One counter-clockwise step ccw

Board Hall of Fame

Testing with Pyboard D, Pyboard v1.1, TinyPico, and Raspberry Pi Pico development boards pyboard b tiny pico

Acknowlegements

This MicroPython implementation is an adaptation of Ben Buxton's C++ work:

https://github.com/buxtronix/arduino/tree/master/libraries/Rotary

Other implementation ideas and techniques taken from:

Future Ambitions

argument error checking

Open Source Agenda is not affiliated with "Micropython Rotary" Project. README Source: miketeachman/micropython-rotary

Stars

253

Open Issues

Last Commit

2 weeks ago

Repository

miketeachman/micropython-rotary

License

MIT

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