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LumiESP

LumiESP is a project utilizing an ESP32 microcontroller to control an LED strip via MQTT. It is designed for easy customization and extension, enabling the creation of custom modes and settings. The included Makefile streamlines PlatformIO commands for building, uploading, and monitoring the code.

lumiesp-flash lumiesp-rainbow lumiesp-snake lumiesp-unicorn

Example modes: Flash, Rainbow, Snake, and Unicorn

Note: This project is in active development and may have bugs or incomplete features. Please report any issues you encounter.

What are the ESP32 and what is MQTT?

The ESP32 is a powerful, low-cost microcontroller with integrated Wi-Fi and Bluetooth, making it perfect for IoT (Internet of Things) applications. It enables devices to connect to the internet and interact wirelessly. MQTT (Message Queuing Telemetry Transport) is a lightweight protocol designed for reliable messaging between devices, especially in low-bandwidth or resource-constrained environments. It allows efficient, real-time communication by transmitting messages between devices over a network, making it an ideal choice for IoT systems.

lumiesp-hardware-6_new.jpg

Features

  • Control LED strips with the ESP32 via MQTT (supports LED types like WS2812, WS2812B, WS2813, etc.)
  • Customizable settings for WiFi, MQTT, device, and LED strip configurations (see the Configuration section)
  • Simplified build, upload, and monitoring with PlatformIO commands
  • Compatible with the IoT MQTT Panel app for easy LED strip control using a pre-configured panel
  • Ability to define and implement custom modes for LED strips (see the Custom Modes section)
  • Supports the a Ultrasonic sensor (HC-SR04) to control the LED strip with gestures (see the Ultrasonic Sensor Configuration section)
  • I hope a good documentation and a good code structure

Requirements

  • An ESP32 microcontroller (e.g., ESP32 Dev Module)
  • A compatible LED strip (e.g., WS2812, WS2812B, WS2813)
  • PlatformIO installed on your system, or use the provided nix-shell
  • MQTT broker (e.g., Mosquitto)

Some recommended tools and software:

Installation

1. Install PlatformIO

PlatformIO is a cross-platform code builder and an easy way to manage embedded software environments. Follow the official installation guide to set it up.

Note: NixOS users can use the included shell.nix to enter a shell with PlatformIO pre-installed.

2. Clone the Repository

Clone the LumiESP project to your local machine:

git clone https://github.com/friedjof/lumiESP.git
cd LumiESP

3. Configure the Project

Before using LumiESP, ensure the following key settings in config/config.h are properly configured:

WiFi Configuration

  • WIFI_SSID: Your WiFi network name.
  • WIFI_PASSWORD: Your WiFi password.

MQTT Configuration

  • MQTT_BROKER: Address of your MQTT broker.
  • MQTT_PORT: Typically set to 1883.
  • MQTT_USERNAME: MQTT broker username.
  • MQTT_PASSWORD: MQTT broker password.
  • MQTT_CLIENT_ID: Unique client ID for the ESP32, critical for distinguishing your device on the network and avoiding conflicts if multiple devices are connected.

Device Configuration

  • DEVICE_NAME: Unique name for your device (used in MQTT topics and communication). Ensure it’s unique if you have multiple devices to prevent overlap or topic collisions.
  • DEVICE_LOCATION: Optional, e.g., "Living Room".

LED Configuration

  • LED_TYPE: Type of LED strip (e.g., WS2812).
  • LED_PIN: GPIO pin connected to the strip.
  • LED_NUM_LEDS: Number of LEDs in the strip.

Make sure these settings are tailored to your setup for proper operation of LumiESP. A unique device name and MQTT client ID are crucial for seamless communication, especially in setups with multiple devices.

Ultrasonic Sensor Configuration

  • ULTRASONIC: set to true to enable the Ultrasonic sensor support (default: false).
  • TRIGGER_PIN: GPIO pin connected to the Ultrasonic sensor trigger (default: 22).
  • ECHO_PIN: GPIO pin connected to the Ultrasonic sensor echo (default: 23).

Read the comments in the config/config.h file for more information on each setting.

Note: Currently, you can only control the brightness of the StaticMode if it is enabled. Other modes are not yet supported.

4. Build, Upload, and Monitor

Use the Makefile to simplify PlatformIO commands. Edit variables in the Makefile as needed.

Note: Copy config/config.h-template to config/config.h and add your details, or use setup.py (python setup.py or make setup).

Variables

  • PORT: ESP32 serial port (e.g., /dev/ttyUSB0).
  • BOARD: ESP32 board type (e.g., esp32dev).
  • SPEED: Baud rate for the serial monitor (e.g., 115200).

5. Control the LED Strip via MQTT with the IoT MQTT Panel App

It takes some time to configure a good panel for controlling the LED strip. Therefore, I have used the IoT MQTT Panel app to control the LED strip. The app is easy to use and allows you to customize the panel according to your needs. You can see some screenshots of the panel below and a tutorial on how to load the panel.json configuration file.

iot-mqtt-panel_modes-and-static iot-mqtt-panel_snake iot-mqtt-panel_flash iot-mqtt-panel_rainbow iot-mqtt-panel_unicorn

This panel allows you to control the LED strip using MQTT messages. You can set the color, brightness, and mode of the LED strip using the app. If you would like to use the samen panel, you can download the app from the Google Play Store and load this panel.json configuration file.

To load the panel.json configuration file, follow these steps:

  1. Open the IoT MQTT Panel app on your device
  2. Create a new connection to your MQTT broker
  3. Click on the three dots of the created connection
  4. Select the "share" option
  5. Configure a mqtt topic and click "subscribe and wait"
  6. Open the "MQTT Explorer" on your desktop
  7. Copy the JSON configuration from the panel.json file
  8. Publish the JSON configuration to the topic you have configured in the app

Development Environment

You can run a mosquitto MQTT broker locally on your machine for testing. To run the MQTT broker using Docker, follow these steps:

Note: Make sure you have Docker installed on your system and you are in the root directory of this project.

Setup the username and password for the MQTT broker (replace <username> with your desired username e.g., esp):

docker run -it -v ./mosquitto/config:/mosquitto/config eclipse-mosquitto mosquitto_passwd -c /mosquitto/config/password.txt <username>

Start the MQTT broker

docker compose up -d

The Makefile provides the following commands:

Configure the Makefile variables to match your setup:

  • PORT: The serial port of the ESP32.
  • BOARD: The ESP32 board type.
  • SPEED: The baud rate for the serial monitor.
  • PLATFORMIO: The path to the PlatformIO executable.

The Makefile provides the following commands:

  • Build the project: make build
  • Upload the code to the ESP32: make upload
  • Monitor the serial output: make monitor
  • Clean the build files: make clean
  • Setup the repository: make setup
  • Clean, build, flash, and open the serial monitor: make flash
  • print the help message: make help

MQTT Topics

LumiESP
├── LumiEsp     // this defines the system topic
│   ├── sub
│   │   ├── status     // the system status
│   │   ├── datetime   // the current date and time
│   │   ├── log        // the log message
│   │   ├── level      // the log level
│   │   └── mode       // the current mode
│   └── pub
│       └── mode       // set the new mode
├── StaticMode  // this is a basic mode that sets the LED strip to a static color
│   ├── sub
│   │   ├── brightness // the current brightness
│   │   └── hex        // the current color in hex format
│   └── pub
│       ├── brightness // set the new brightness
│       └── hex        // set the new color in hex format
…

The system topic is used to handle system-related information, such as the current mode, status updates, and log messages, using the publish/subscribe (pub/sub) pattern. When a change, like a new color or brightness, is set, the ESP32 publishes the updated values back to the sub topic to confirm the changes. This ensures that any subscribers to the sub topics receive the latest values and can track the current system status.

Hint: You can see more topics in this MQTT Explorer screenshot

Define Your Own Custom Modes

Note: You need basic knowledge of C++ (Abstract Classes, Inheritance, and Function Binding) to define custom modes.

You can define your own custom modes by following steps:

  1. Create a new folder, such as ModeCustom, in the lib/ directory.
  2. Inside this folder, create a header file named CustomMode.h and a source file named CustomMode.cpp.
  3. Implement the CustomMode class in these files, using the AbstractMode class as the base class.

CustomMode.h

// #ifndef is a preprocessor directive that checks if the token has been defined earlier in the file or in an included file
#ifndef CUSTOMMODE_H
#define CUSTOMMODE_H

#include <functional>
#include "AbstractMode.h"

class CustomMode : public AbstractMode {
private:
    // Internal properties for managing color and brightness
    String customColor = "#424242";  // Default color
    String newCustomColor = this->customColor;
    byte customBrightness = 255;  // Default brightness
    byte newCustomBrightness = this->customBrightness;

    // Callback method called when a new color is set via MQTT
    void customColorCallback(const String &color);
    // Callback method called when a new brightness is set via MQTT
    void customBrightnessCallback(const byte &brightness);

    // Functions to publish updated values back to MQTT to confirm changes
    std::function<void(String payload)> pushCustomColor = nullptr;
    std::function<void(String payload)> pushCustomBrightness = nullptr;

    // Helper methods to detect changes in color or brightness
    bool isNewCustomColor();
    bool isNewCustomBrightness();

public:
    CustomMode(ControllerService* controllerService);

    // Setup method called once when the mode is initialized
    void customSetup() override;

    // Loop method called in every iteration; 'steps' is a counter for every mode in this project
    void customLoop(unsigned long long steps) override;
};

#endif

CustomMode.cpp

// Include the header file of the custom mode
#include "CustomMode.h"

// Constructor implementation of the custom mode
// Calls the base class "AbstractMode" constructor with the "controllerService" parameter
CustomMode::CustomMode(ControllerService* controllerService) : AbstractMode(controllerService) {
    // Parameters for classifying the mode; provide basic info about the mode and author
    this->modeTitle = "Custom Mode";
    this->modeDescription = "This is a custom mode that sets the LED strip to a custom color and brightness.";
    this->modeInternalName = "CustomMode"; // Unique name to identify the mode
    this->modeAuthor = "<Your Name>";      // Add your name or username
    this->modeContact = "<Your Email or other contact information (optional)>";
    this->modeVersion = "1.0.0";           // Define a version number
    this->modeLicense = "MIT";             // Define your chosen license
}

void CustomMode::customSetup() {
    // Called once when the mode is initialized
    // Define MQTT topics to push and subscribe to

    // Note: "controllerService" manages other services and is accessed via "AbstractMode"
    // Refer to the "Services and Classes" section diagram for more details

    // Topic for color: "<DeviceName>/<ModeInternalName>/sub/customcolor" and "<DeviceName>/<ModeInternalName>/pub/customcolor"
    // Uses parameters like modeInternalName, topicName, defaultValue, payloadType, and callback
    this->pushCustomColor = this->controllerService->subscribeModeTopic(
        this->modeInternalName, "customcolor", this->customColor.c_str(), payload_e::COLOR,
        std::function<void(String)>(std::bind(&CustomMode::customColorCallback, this, std::placeholders::_1)));
    
    // Topic for brightness: "<DeviceName>/<ModeInternalName>/sub/custombrightness" and "<DeviceName>/<ModeInternalName>/pub/custombrightness"
    // Uses parameters including boundaries (min, max)
    this->pushCustomBrightness = this->controllerService->subscribeModeTopic(
        this->modeInternalName, "custombrightness", this->customBrightness, boundaries_t{0, 255},
        payload_e::BYTE, std::function<void(String)>(std::bind(&CustomMode::customBrightnessCallback, this, std::placeholders::_1)));
}

void CustomMode::customLoop(unsigned long long steps) {
    // Called in every loop iteration; defines the mode's behavior

    // Check if it's the first run after activation using "isFirstRun()" from "AbstractMode"
    if (this->isFirstRun()) {
        // Update the LED strip from the state of the last mode
        this->controllerService->setHexColor(this->customColor);
        this->controllerService->setBrightness(this->customBrightness);
        this->controllerService->confirmLedConfig(); // Confirm new configuration
    }

    // Use conditions to handle new configurations set via MQTT; this reduces loop execution time
    if (this->isNewCustomColor()) {
        this->customColor = this->newCustomColor;
        this->controllerService->setHexColor(this->customColor);
        this->controllerService->confirmLedConfig();
    }

    if (this->isNewCustomBrightness()) {
        this->customBrightness = this->newCustomBrightness;
        this->controllerService->setBrightness(this->customBrightness);
        this->controllerService->confirmLedConfig();
    }

    // Use the "steps" parameter for animations or implement a custom counter for updates
}

// Called when a new color is set via MQTT
void CustomMode::customColorCallback(const String &color) {
    this->newCustomColor = color;                // Store the new color

    if (this->pushCustomColor != nullptr) {
        this->pushCustomColor(this->newCustomColor); // Acknowledge the change to the MQTT broker if the callback is set
    }
}

// Called when a new brightness is set via MQTT
void CustomMode::customBrightnessCallback(const byte &brightness) {
    this->newCustomBrightness = brightness;                // Store the new brightness
    
    if (this->pushCustomBrightness != nullptr) {
        this->pushCustomBrightness(this->newCustomBrightness); // Acknowledge the change to the MQTT broker if the callback is set
    }
}

// Checks if the color has changed
bool CustomMode::isNewCustomColor() {
    return this->customColor != this->newCustomColor;
}

// Checks if the brightness has changed
bool CustomMode::isNewCustomBrightness() {
    return this->customBrightness != this->newCustomBrightness;
}
  1. Include the New Mode in the main.cpp File:
//

// Include custom modes
#include "CustomMode.h"
//

// Main setup method of the ESP32
void setup() {
    //
    // ----> SETUP YOUR MODE HERE <----
    // Define your custom modes here
    AbstractMode* customMode = new CustomMode(&controllerService);
    //

    // Setup modes
    // Calls the "setup" method of the "AbstractMode" class followed by "customSetup"
    customMode->setup();
    //
    // <---- SETUP YOUR MODE HERE ---->

    //
}

//
  1. Build, upload, and monitor the code using the Makefile commands (see above).

I'd love to see the custom modes you create—feel free to share them via a pull request!

Services and classes

  • ClockService: Provides timekeeping functionality (including NTP synchronization).
  • LoggingService: Logs messages to the serial monitor and MQTT.
  • MQTTService: Handles MQTT communication with the broker.
  • LedService: Controls the LED strip using PWM signals.
  • ControllerService: Manages tasks and schedules for the ESP32.

Services Overview

Troubleshooting

  • Make sure the correct port is selected in the Makefile.
  • Ensure PlatformIO is installed correctly by checking the installation instructions linked above (see Installation).
  • Check if the DEVICE_NAME are unique if you have multiple devices (see the Configuration section).
  • Check if the DEVICE_CLIENT_ID is unique for each device (see the Configuration section).
  • Verify that the MQTT broker is running and accessible from the ESP32.

Note: If you encounter any issues, please open an issue on the GitHub repository and I hope I can help you.

Acknowledgements

  • PlatformIO for providing a versatile environment for embedded development.
  • MQTT protocol for enabling efficient communication between devices.

Author

Looking forward to seeing your name here soon.