Awesome
Pi-IO
A proof of concept to demonstrate that it's feasible to implement a Raspberry Pi IO Plugin for Johnny-Five using Linux-IO.
Tested on a Raspberry Pi 4 Model B with Node.js v16.0.0. Should function with Node.js v10 or higher.
Installation
Step 1 - Install the pigpio C library
The pigpio C library is a prerequisite for pi-io.
Run the following command to determine which version of the pigpio C library is installed:
pigpiod -v
For the Raspberry Pi Zero, 1, 2 and 3 V41 or higher of the pigpio C library is required. For the Raspberry Pi 4 V69 or higher is required.
If the pigpio C library is not installed or if the installed version is too old, the latest version can be installed with the following commands:
sudo apt-get update
sudo apt-get install pigpio
Alternative installation instructions for the pigpio C library can be found here.
Warning: The pigpio C library contains a number of utilities. One of these utilities is pigpiod which launches the pigpio C library as a daemon. This utility should not be used as the pi-io uses the pigpio C library directly.
Step 2 - Install the pi-io Node.js package
npm install pi-io
Johnny-Five Features Supported
Feature | Support |
---|---|
Analog Read | no |
Digital Read | yes |
Digital Write | yes |
PWM | yes |
Servo | yes |
I2C | yes |
One Wire | no |
Stepper | no |
Serial/UART | no |
DAC | no |
Ping | yes <sup>*)</sup> |
*) Ping was tested with three HC-SR04 proximity sensors with varying degrees of success. One sensor functioned as expected. The second didn't timeout as it should but it's was possible to workaround the issue with software. The third sensor didn't function. The issues may be related to the fact that a single pin is used for both trigger and echo.
To workaround these issues a controller was implemented that allows separate pins to be used for trigger and echo. The same three HC-SR04 proximity sensors functioned well with this controller.
Supported Pins
Pin ID | Supported Modes | Comments |
---|---|---|
P1-3 or GPIO2 | INPUT, OUTPUT, PWM, SERVO | Alternatively I2C SDA1 |
P1-5 or GPIO3 | INPUT, OUTPUT, PWM, SERVO | Alternatively I2C SCL1 |
P1-7 or GPIO4 | INPUT, OUTPUT, PWM, SERVO | |
P1-8 or GPIO14 | INPUT, OUTPUT, PWM, SERVO | |
P1-10 or GPIO15 | INPUT, OUTPUT, PWM, SERVO | |
P1-11 or GPIO17 | INPUT, OUTPUT, PWM, SERVO | |
P1-12 or GPIO18 | INPUT, OUTPUT, PWM, SERVO | |
P1-13 or GPIO27 | INPUT, OUTPUT, PWM, SERVO | |
P1-15 or GPIO22 | INPUT, OUTPUT, PWM, SERVO | |
P1-16 or GPIO23 | INPUT, OUTPUT, PWM, SERVO | |
P1-18 or GPIO24 | INPUT, OUTPUT, PWM, SERVO | |
P1-19 or GPIO10 | INPUT, OUTPUT, PWM, SERVO | |
P1-21 or GPIO9 | INPUT, OUTPUT, PWM, SERVO | |
P1-22 or GPIO25 | INPUT, OUTPUT, PWM, SERVO | |
P1-23 or GPIO11 | INPUT, OUTPUT, PWM, SERVO | |
P1-24 or GPIO8 | INPUT, OUTPUT, PWM, SERVO | |
P1-26 or GPIO7 | INPUT, OUTPUT, PWM, SERVO | |
P1-29 or GPIO5 | INPUT, OUTPUT, PWM, SERVO | |
P1-31 or GPIO6 | INPUT, OUTPUT, PWM, SERVO | |
P1-32 or GPIO12 | INPUT, OUTPUT, PWM, SERVO | |
P1-33 or GPIO13 | INPUT, OUTPUT, PWM, SERVO | |
P1-35 or GPIO19 | INPUT, OUTPUT, PWM, SERVO | |
P1-36 or GPIO16 | INPUT, OUTPUT, PWM, SERVO | |
P1-37 or GPIO26 | INPUT, OUTPUT, PWM, SERVO | |
P1-38 or GPIO20 | INPUT, OUTPUT, PWM, SERVO | |
P1-40 or GPIO21 | INPUT, OUTPUT, PWM, SERVO | |
LED0 | OUTPUT | Built-in LED |
Usage
Pluse an LED connected to GPIO17
<img src="https://raw.githubusercontent.com/fivdi/pi-io/master/doc/led.png">var five = require('johnny-five');
var PiIO = require('pi-io');
var board = new five.Board({
io: new PiIO()
});
board.on('ready', function() {
var led = new five.Led('GPIO17');
led.pulse(1000);
});
Rotate a continuous servo connected to GPIO27 clockwise
<img src="https://raw.githubusercontent.com/fivdi/pi-io/master/doc/continuous-servo.png">var five = require('johnny-five');
var PiIO = require('pi-io');
var board = new five.Board({
io: new PiIO()
});
board.on('ready', function() {
var servo = new five.Servo({
pin: 'GPIO27',
type: "continuous"
});
servo.cw(0.8);
});
Measure proximity with a HC-SR04 using separate pins for trigger and echo
<img src="https://raw.githubusercontent.com/fivdi/pi-io/master/doc/hc-sr04-two-pin.png">var five = require('johnny-five');
var PiIO = require('pi-io');
var board = new five.Board({
io: new PiIO()
});
board.on('ready', function() {
var proximity = new five.Proximity({
controller: PiIO.HCSR04, // Custom controller
triggerPin: 'GPIO23',
echoPin: 'GPIO24'
});
proximity.on("change", function() {
console.log("cm: ", this.cm);
});
});
Measure proximity with a HC-SR04 connected to GPIO25
Note that this circuit uses a single pin for trigger and echo. Whether or not this functions correctly appears to be highly dependent on the particular HC-SR04 sensor being used. The circuit shown above that uses separate pins for trigger and echo is far more reliable.
<img src="https://raw.githubusercontent.com/fivdi/pi-io/master/doc/hc-sr04.png">var five = require('johnny-five');
var PiIO = require('pi-io');
var board = new five.Board({
io: new PiIO()
});
board.on('ready', function() {
var proximity = new five.Proximity({
controller: 'HCSR04',
pin: 'GPIO25'
});
proximity.on("data", function() {
console.log("cm: ", this.cm);
});
});
Examples
Additional examples can be found in the example directory.