pimoroni-pico/libraries/automation2040w
ZodiusInfuser 2516a06237 Doc improvements and added C++ doc 2022-07-20 16:12:37 +01:00
..
CMakeLists.txt Libraries and examples for Automation 2040 W (#418) 2022-07-01 07:05:37 +01:00
README.md Doc improvements and added C++ doc 2022-07-20 16:12:37 +01:00
automation.cmake Libraries and examples for Automation 2040 W (#418) 2022-07-01 07:05:37 +01:00
automation.cpp Libraries and examples for Automation 2040 W (#418) 2022-07-01 07:05:37 +01:00
automation.hpp Libraries and examples for Automation 2040 W (#418) 2022-07-01 07:05:37 +01:00

README.md

Automation 2040W C++

This library offers convenient functions for interacting with your new Pimoroni Automation 2040W, an all-in-one, Pico W powered industrial/automation controller with 2.4GHz wireless connectivity, relays and a plethora of inputs and outputs.

Table of Content

Automation 2040W Class

The Automation2040W class deals with the initialisation of each of the board's functions. To create one, first include the automation library and the namespace:

#include "automation.hpp"
using namespace automation;

Then define a new board variable:

Automation2040W board;

Finally, within your main() attempt to initialise the board:

int main() {
  stdio_init_all();

  // Attempt to initialise the board
  if(board.init()) {
    <Your code here>
  }
}

From here, all features of Automation 2040W can be accessed by calling functions on board. In addition, when using Qwiic / Stemma QT devices, the I2C channel to use can be accessed with board.i2c.

User Switches and LEDs

Automation 2040W has two handy switches onboard, with neighbouring LEDs, offering a tactile way to interact with your program and be notified of actions that need attention.

To read one of the switches, call .switch_pressed(sw), where sw is a value from 0 to NUM_SWITCHES - 1. This returns true when the specified switch is pressed, and false otherwise.

To set a switch's neighbouring LED, call .switch_led(sw, on) or .switch_led(sw, brightness), where switch is a value from 0 to NUM_SWITCHES - 1, on is either true or false, and brightness is a number from 0.0f to 100.0f.

To make it easier to use a specific switch or it's LED, the automation namespace contains these handy constants:

  • SWITCH_A = 0
  • SWITCH_B = 1

Connectivity LED

In addition to the Switch LEDs, Automation 2040W has a user-controllable connectivity LED near the top-right of the board.

To set this led, call .conn_led(on) or .conn_led(brightness), where on is either true or false,and brightness is either true, false, or a number from 0.0f to 100.0f.

Actuating the Relays

Three relays are featured on Automation 2040W. By default these are in a released state, which connects the terminal labelled NC to COM. By actuating them, a connection from NO to COM can be made instead.

A relay can be actuated by calling .actuate_relay(relay), or released by calling .release_relay(relay). Additionally the actuated state can be set by providing a boolean to the actuate parameter of .relay(relay, actuate).

The state of each relay can be read by calling .relay(relay). This returns true if the relay is actuated, and false if it is released. The actuation state is also reflected by LEDs that neighbour each relay.

For all these functions, relay is a value from 0 to NUM_RELAYS - 1. To control a specific relay, the automation namespace contains these handy constants:

  • RELAY_1 = 0
  • RELAY_2 = 1
  • RELAY_3 = 2

Setting the Outputs

Three sourcing outputs, capable of 2A+, are present on Automation 2040W.

An output can be controlled by calling .output(output, value), where output is a value from 0 to NUM_OUTPUTS - 1, and value is true or false.

The state of an output can be read by calling .output(output), where output is a value from 0 to NUM_OUTPUTS - 1. This returns true if the output is active, and false if it is inactive. The state is also reflected by LEDs that neighbour each output terminal.

To control a specific output, the automation namespace contains these handy constants:

  • OUTPUT_1 = 0
  • OUTPUT_2 = 1
  • OUTPUT_3 = 2

Reading the Inputs

Automation 2040W has four buffered digital inputs. These can be read by calling .read_input(input), where input is a value from 0 to NUM_INPUTS - 1.

To read a specific input, the automation namespace contains these handy constants:

  • INPUT_1 = 0
  • INPUT_2 = 1
  • INPUT_3 = 2
  • INPUT_4 = 3

Reading the ADCs

Automation 2040W has three analog inputs, capable of reading up to 40V. The voltage on these can be read by calling .read_adc(adc), where adc is a value from 0 to NUM_ADCS - 1.

To read a specific adc, the automation namespace contains these handy constants:

  • ADC_1 = 0
  • ADC_2 = 1
  • ADC_3 = 2

Extra GPIOs

On the left hand side of Automation 2040W are three GPIO pins. These are 3.3V logic only, and are connected to GP0, GP1, and GP2 of the Pico W. These pins can be referenced in code using 0, 1, and 2, or by one of these handy constants on the automation namespace:

  • GP0 = 0
  • GP1 = 1
  • GP2 = 2

There is also a NUM_GPIOS for times when any iteration needs to be performed.

Software Reset

If there is a need to put Automation 2040W back into a known safe-state, without resorting to the hardware reset switch, then .reset() can be called. This deactivates all outputs, releases all relays, and turns off all user-controllable LEDs.

Function Reference

Here is the complete list of functions available on the Automation2040W class:

Automation2040W();
bool init();
void conn_led(bool on);
void conn_led(float brightness);
bool switch_pressed(uint sw);
void switch_led(uint sw, bool on);
void switch_led(uint sw, float brightness);
bool relay(uint relay);
void relay(uint relay, bool actuate);
void actuate_relay(uint relay);
void release_relay(uint relay);
bool output(uint output);
void output(uint output, bool value);
bool read_input(uint input);
float read_adc(uint adc);
void reset();