Python library for the Pimoroni IO Expander
Project description
IO Expander
IO Expander Breakout uses a Nuvoton MS51 microcontroller and I2C to give you 14 additional input/output pins to connect things up to. Eight of the pins are hooked up to an Analog to Digital Converter and six of the pins can be used as (up to 16-bit) PWM outputs.
This library is also used to power our other Nuvoton-based boards and breakouts!
Where to buy
HATs
- Weather HAT: https://shop.pimoroni.com/products/weather-hat-only
- Inventor HAT Mini: https://shop.pimoroni.com/products/inventor-hat-mini
Breakouts
- IO Expander Breakout: https://shop.pimoroni.com/products/io-expander
- RGB Potentiometer Breakout: https://shop.pimoroni.com/products/rgb-potentiometer-breakout
- RGB Encoder Breakout: https://shop.pimoroni.com/products/rgb-encoder-breakout
- MICS6814 3-in-1 Gas Sensor Breakout: https://shop.pimoroni.com/products/mics6814-gas-sensor-breakout
Getting the Library
Stable library only (no examples) from PyPi:
- Just run
python3 -m pip install pimoroni-ioexpander
In some cases you may need to install pip with: sudo apt install python3-pip
Stable library, with latest examples from GitHub:
git clone https://github.com/pimoroni/ioe-python
cd ioe-python
./install.sh
Latest/development library and examples from GitHub:
git clone https://github.com/pimoroni/ioe-python
cd ioe-python
./install.sh --unstable
Configuring your Raspberry Pi
Enable I2C
In order to use the IO Expander, you need to enable the I2C interface of your Raspberry Pi. This can be done in the terminal by running:
sudo raspi-config nonint do_i2c 0
Alternatively, you can enable the I2C interface by:
- running
sudo raspi-config
and enabling the option under Interfacing Options. - opening the graphical Raspberry Pi Configuration application from the Preferences menu.
You may need to reboot after enabling I2C for the change to take effect.
Note for Raspberry Pi 1
The first version of the Raspberry Pi uses SMBus 0 instead of 1. The ioe-python library uses SMBus 1 by default.
You can change the SMBus that is used by adding smbus_id=0
to your calls to io.IOE(...)
. If you want your code to run on multiple revisions of the Pi without having to change your code depending on the Raspberry Pi revision, you can make your code check the Revision
part of /proc/cpuinfo
and set the SMBus accordingly. Revisions 0002
and 0003
use SMBus 0. All others use SMBus 1.
Examples and Usage
There are various examples to get you started with your IO Expander. With the library installed on your Raspberry Pi, these can be found in the ~/Pimoroni/pimoroni-ioexpander/examples
directory.
To take IO Expander further, the full API is described in the library reference, with additional feature specific information found in the docs folder.
Removing the Library
To uninstall the library only (keeping all examples):
- Just run
python3 -m pip uninstall pimoroni-ioexpander
Or if you have grabbed the library from Github:
cd ioe-python
./uninstall.sh
Reference
Pins
IO Expander
All pins are capable as functioning as general purpose inputs and outputs, and reading rotary encoders, but may additionally function as a PWM output and/or ADC input.
# | Port | ADC | PWM | Encoder |
---|---|---|---|---|
1 | P1.5 | [Ch 5] | Ch 1 | |
2 | P1.0 | [Ch 2] | Ch 2 | |
3 | P1.2 | [Ch 0] | Ch 3 | |
4 | P1.4 | [Ch 1] | Ch 4 | |
5 | P0.0 | [Ch 3] | Ch 5 | |
6 | P0.1 | [Ch 4] | Ch 6 | |
7 | P1.1 | [Ch 7] | Ch 1 | Ch 7 |
8 | P0.3 | [Ch 6] | Ch 5 | Ch 8 |
9 | P0.4 | [Ch 5] | Ch 3 | Ch 9 |
10 | P3.0 | [Ch 1] | Ch 10 | |
11 | P0.6 | [Ch 3] | Ch 11 | |
12 | P0.5 | [Ch 4] | Ch 2 | Ch 12 |
13 | P0.7 | [Ch 2] | Ch 13 | |
14 | P1.7 | [Ch 0] | Ch 14 |
[ ] = labelled pin functions
Super IO Expander
# | Port | ADC | PWM | Alt PWM | Encoder |
---|---|---|---|---|---|
[1] | P3.5 | Ch 14 | |||
[2] | P3.6 | Ch 15 | |||
3 | P0.6 | [Ch 3] | Ch 11 | ||
4 | P0.7 | [Ch 2] | Ch 13 | ||
5 | P1.7 | [Ch 0] | Mod 3 Ch 0 | ||
6 | P3.0 | [Ch 1] | Mod 2 Ch 1 | Ch 10 | |
7 | P0.4 | [Ch 5] | Mod 0 Ch 3 | Mod 2 Ch 1 | Ch 9 |
8 | P0.5 | [Ch 4] | Mod 0 Ch 2 | Mod 2 Ch 0 | |
9 | P1.3 | [Ch 13] | Ch 0 | ||
10 | P2.5 | [Ch 15] | |||
11 | P1.1 | [Ch 7] | Mod 0 Ch 1 | Mod 1 Ch 1 | |
12 | P0.3 | [Ch 6] | Mod 0 Ch 5 | Mod 3 Ch 1 | Ch 8 |
13 | P2.4 | [Ch 12] | Ch 7 | ||
14 | P2.3 | [Ch 11] | Mod 1 Ch 0 | Ch 6 | |
15 | P3.3 | [Mod 0 Ch 0] | |||
16 | P0.1 | [Mod 0 Ch 4] | Mod 3 Ch 0 | ||
17 | P1.5 | [Mod 0 Ch 5] | Mod 3 Ch 1 | Ch 1 | |
18 | P1.4 | Ch 14 | [Mod 0 Ch 1] | Mod 1 Ch 1 | Ch 4 |
19 | P0.0 | [Mod 0 Ch 3] | Mod 2 Ch 1 | Ch 5 | |
20 | P1.0 | [Mod 0 Ch 2] | Mod 2 Ch 0 | Ch 2 | |
21 | P2.1 | Ch 9 | [Mod 2 Ch 0] | ||
22 | P2.2 | Ch 10 | [Mod 1 Ch 1] | ||
23 | P1.2 | Mod 0 Ch 0 | [Mod 1 Ch 0] | Ch 3 | |
24 | P3.2 | [Mod 3 Ch 0] | |||
25 | P3.4 | [Mod 3 Ch 1] | |||
26 | P3.1 | [Mod 2 Ch 1] | Ch 12 |
[ ] = labelled pin functions
Functions
In all cases you will need to create an instance of the IOE
class to manage your IO expander (or the SuperIOE
if using a Super IO Expander board):
import ioexpander
# For IO Expander boards
ioe = ioexpander.IOE()
# For Super IO Expander boards
ioe = ioexpander.SuperIOE()
General-purpose IO
All pins support general-purpose IO and can be configured either as a high-impedance input, quasi-bidirectional input with pull-up, open-drain output or push-pull output. These modes are applicable to different use-cases and we mention some basic examples below.
High-impedance input
For input pins you will usually use ioexpander.IN
which sets pins to input-only, high-impedance mode. This mode does not support pull-ups on the pins, and is useful for reading logic levels which are asserted to a high/low value.
To set a pin as a high-impedance input:
ioe.set_mode(1, ioexpander.IN)
And read its value:
value = ioe.input(1)
Input with pull-up
For reading buttons, or other inputs which sink the connected pin to ground (open drain IO pins for example) you should use the ioexpander.IN_PU
mode.
In this mode the pin is set to a quasi-bidirectional input, and a pull-up resistor is asserted pulling the logic level weakly HIGH.
ioe.set_mode(1, ioexpander.IN_PU)
Wire a button between ground, and the IO pin and read its value:
value = ioe.input(1)
A value of 0 (LOW
) corresponds to a pushed button.
Output
For output pins you may choose one of the following output modes:
ioexpander.PIN_MODE_PP
- Output, Push-Pull mode. Drives a pin either HIGH or LOW.ioexpander.PIN_MODE_OD
- Output, Open-Drain mode. Drives low, or leaves the pin floating
Push-pull mode is non-inverting, and useful for controlling a connected device (such as a shift register or motor driver), or switching an NPN transistor.
Open-drain mode effectively inverts the signal, since outputting a HIGH will connect the pin to Ground. Open-drain outputs are used in multi-drop protocols like i2c, but can also be used for devices or digital logic that requires an active low input.
To set a pin as a push-pull output:
ioe.set_mode(1, ioexpander.PIN_MODE_PP)
And set its value:
ioe.output(1, 0) # Low (Floating in OD)
ioe.output(1, 1) # High (Low in OD)
Or an open-drain output:
ioe.set_mode(1, ioexpander.PIN_MODE_OD)
And set its value:
ioe.output(1, 0) # High (High-impedance floating)
ioe.output(1, 1) # Low (Pulls to ground)
Note: when using open-drain mode (PIN_MODE_OD
), writing a 1
will pull the pin low and writing a 0
will leave the pin floating.
Analog Inputs (ADC)
Pins 7, 8, 9 10, 11, 12, 13, and 14 support analog input.
IO Expander's input
method will automatically give you a voltage for pins configured in ADC mode:
ioe.set_mode(7, ioexpander.ADC)
voltage = ioe.input(7)
This is scaled against the ADC vref value, which can be read/set with:
ioe.set_adc_vref(5)
vref = ioe.get_adc_vref()
For accurate analog readings, the vref value (which defaults to 3.3) should match the voltage at which the breakout is being powered. In most cases this will be either 3.3v or 5v.
Pulse Width Modulation Outputs (PWM)
Pins 1, 2, 4, 5, and 6 support PWM output as marked. Additionally pins 7, 8, 9 and 12 (marked as ADC on the IO expander) can be configured as PWM outputs.
ioe.set_mode(1, ioexpander.PWM)
PWM outputs can optionally be inverted which us useful where you might be driving inverting buffers or common-cathode LEDs:
ioe.set_mode(1, ioexpander.PWM, invert=True)
PWM, by default, uses the 24MHz FSYS clock and has 16bit period and duty-cycle registers.
There are 8 dividers available to slow the clock input into the PWM generator:
- 1/1
- 1/2
- 1/4
- 1/8
- 1/16
- 1/32
- 1/64
- 1/128
These can be set with set_pwm_control
:
ioe.set_pwm_control(divider=8)
In order to dial in the frequency you need, you must consider the 24MHz clock, the available divider options and the maximum value of the period register.
For example, for a 50Hz servo frequency you would use a 1/8 divider, and a period of 60,000:
24,000,000 / 8 / 60,000 = 50
ioe.set_pwm_control(divider=8)
ioe.set_pwm_period(60000)
Then you can use duty-cycle values from 3000 to 6000 (1ms to 2ms) to create a servo control pulse.
Rotary Encoder Decoding
The IO Expander supports decoding the waveform from up to four rotary encoders. The A and B pins must be specified and are configured as schmitt trigger inputs with a pull-up, if the C pin is specified then it's set to open-drain and driven low. For example:
ENC_CHANNEL = 1
POT_ENC_A = 12
POT_ENC_B = 3
POT_ENC_C = 11
ioe.setup_rotary_encoder(ENC_CHANNEL, POT_ENC_A, POT_ENC_B, pin_c=POT_ENC_C)
Each encoder channel has its own signed, 8bit count register which stores the continuous count of pulses as the encoder is rotated. This register is not reset between reads, and will overflow from 127 to -128 in one direction, and from -128 to 127 in the other.
In order to maintain a count across reads, this overflow event should be used to increment/decrement an offset which is then added to the register value. This is all done inside the IO Expander library, so you can simply read a continuous value using:
count = ioe.read_rotary_encoder(1)
This value will correspond to the number of rotations of your rotary encoder dial, multiplied by the resolution of the encoder.
The rotary encoder channels will assert an interrupt when a value is changed, in your program main loop you should check for this interrupt, read the encoder value and clear the interrupt flag:
while True:
if ioe.get_interrupt():
count = ioe.read_rotary_encoder(1)
ioe.clear_interrupt()
Note: in order to track overflows you will need to ensure this interrupt code can run fast enough to catch them. In most cases - ie: a person turning a dial with a 24 step resolution - even 1-second intervals are fine, but for decoding a motor you will want to sample much faster. For example a motor running at 20k RPM with a 12 step resolution would need to be sampled around 31 times a second or approximately every 30ms.
Super IO Changes
On the Super IO Expander, encoder counting has been increased to 16 bit to remove the note above of requiring that motor encoders be read every 30ms to avoid an overflow. An overflow will still occur but now from 32767 to -32768 in one direction, and from -32768 to 32767 in the other.
Configuring Interrupts
IO Expander has an interrupt register to indicate a variety of state changes. On its own this interrupt register isn't much more useful than polling, but IO Expander can also generate an interrupt on its INT pin - connected to BCM 4 via Breakout Garden HAT - which you can then monitor with your GPIO library of choice.
By default the interrupt output pin is not used, but you can enable it on setup like so:
import ioexpander
ioe = ioexpander.IOE(interrupt_pin=4)
In this instance 4
corresponds to BCM4
on the Raspberry Pi. Specifying an interrupt pin will enable interrupt output on the IO Expander and set up RPi.GPIO
.
Alternatively you can handle the interrupt how you see fit by initialising the library and enabling the interrupt output manually:
import ioexpander
ioe = ioexpander.IOE()
ioe.enable_interrupt_out()
In either case the current state of the interrupt register (and pin) can be read by running:
ioe.get_interrupt()
And cleared with:
ioe.clear_interrupt()
If you're using the IO Expander library to handle interrupts then you can bind a handler to the interrupt event:
import ioexpander
ioe = ioexpander.IOE(interrupt_pin=4)
def callback(channel):
# Handle interrupt here
ioe.clear_interrupt()
ioe.on_interrupt(callback)
Function Reference
Here is the complete list of functions common to both the IOE
and SuperIOE
classes:
i2c_read8(reg)
i2c_read12(reg_l, reg_h)
i2c_read16(reg_l, reg_h)
i2c_write8(reg, value)
i2c_write16(reg_l, reg_h, value)
get_pin(pin)
setup_switch_counter(pin, mode=IN_PU)
read_switch_counter(pin)
clear_switch_counter(pin)
setup_rotary_encoder(channel, pin_a, pin_b, pin_c=None, count_microsteps=False)
read_rotary_encoder(channel)
clear_rotary_encoder(channel)
set_bits(reg, bits)
set_bit(reg, bit)
clr_bits(reg, bits)
clr_bit(reg, bit)
get_bit(reg, bit)
change_bit(reg, bit, state)
enable_interrupt_out(pin_swap=False)
disable_interrupt_out()
get_interrupt()
clear_interrupt()
set_pin_interrupt(pin, enabled)
on_interrupt(callback)
set_i2c_addr(i2c_addr)
set_adc_vref(vref)
get_adc_vref()
enable_adc()
disable_adc()
get_chip_id()
get_version()
reset()
get_pwm_module(pin)
pwm_load(pwm_module=0, wait_for_load=True)
pwm_loading(pwm_module=0)
pwm_clear(pwm_module=0, wait_for_clear=True)
pwm_clearing(pwm_module=0)
set_pwm_control(divider, pwm_module=0)
set_pwm_period(value, pwm_module=0, load=True, wait_for_load=True)
set_pwm_frequency(frequency, pwm_module=0, load=True, wait_for_load=True)
get_mode(pin)
set_mode(pin, mode, schmitt_trigger=False, invert=False)
input(pin, adc_timeout=1)
output(pin, value, load=True, wait_for_load=True)
get_pwm_regs(pin)
get_alt_pwm_regs(pin)
get_pin_regs(pin)
switch_pwm_to_alt(pin)
Here is the initialiser for the IOE
class:
IOE(i2c_addr=None, interrupt_timeout=1.0, interrupt_pin=None, interrupt_pull_up=False, gpio=None, smbus_id=1, skip_chip_id_check=False, perform_reset=False)
Here is the initialise and additional functions for the SuperIOE
class:
SuperIOE(i2c_addr=None, interrupt_timeout=1.0, interrupt_pin=None, interrupt_pull_up=False, gpio=None, smbus_id=1, skip_chip_id_check=False, perform_reset=False, is_super_io=True)
activate_watchdog()
deactivate_Watchdog()
is_watchdog_active()
reset_watchdog_counter()
watchdog_timeout_occurred()
clear_watchdog_timeout()
set_watchdog_control(divider)
i2c_multi_read(reg_base, count)
read_rotary_encoders(start_channel, end_channel)
Constants Reference
Here is the list of constants on the pimoroni-ioexpander
module:
Pin Mode Constants
IN
=PIN_MODE_IN
IN_PULL_UP
=PIN_MODE_PU
IN_PU
=PIN_MODE_PU
OUT
=PIN_MODE_PP
PWM
=PIN_MODE_PWM
ADC
=PIN_MODE_ADC
State Constants
HIGH
=1
LOW
=0
PWM Constants
CLOCK_FREQ
=24000000
MAX_PERIOD
=(1 << 16) - 1
MAX_DIVIDER
=(1 << 7)
Changelog
1.0.1
- Fix bug in SuperIOE constructor (add i2c bus number)
1.0.0
- Add dependency on smbus2
- Add support for alternate i2c bus number
- Port to hatch/pyproject.toml
0.0.5
- Improved readme and documentation
- Linting fixes
0.0.4
- Add support for bigger nuvoton chip
- Add wrappers for controlling motors, servos, and encoders
0.0.3
- Add support for 7-bit switch/pulse counters
0.0.2
- Call read/write in a single i2c_rdwr to maintain thread safety
0.0.1
- Initial Release
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