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PlantWater/README.md
Stephen Minakian 5fd11369cc Added MQTT
2025-07-17 20:41:25 -06:00

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# ESP32-S3 Plant Watering System
An automated plant watering system built with ESP32-S3, featuring MQTT communication, OTA updates, and remote monitoring/control capabilities.
## Current Project Status
### ✅ Completed Features
- **WiFi Manager**: Auto-connect with NVS credential storage
- **OTA Updates**: Web-based firmware updates via HTTP server
- **MQTT Client**: Full MQTT integration with NVS credential storage
- Auto-reconnection
- Last Will and Testament (LWT)
- Command subscription
- Sensor data publishing
### 🚧 In Progress
- Motor control (TB6612FNG driver)
- Moisture sensor reading
- Automation logic
### 📋 TODO
- Web dashboard
- Home Assistant integration
- Multiple zone support
## Hardware
- **MCU**: ESP32-S3-MINI-1
- **Motor Driver**: TB6612FNG (for 2 water pumps)
- **Sensors**: 2x Capacitive soil moisture sensors
- **Power**: 12V supply for pumps, 3.3V for logic
## Software Architecture
### MQTT Topics
| Topic | Direction | Description | Example |
|-------|-----------|-------------|---------|
| `plant_watering/status` | Publish | System online/offline status | "online" |
| `plant_watering/moisture/1` | Publish | Moisture sensor 1 reading (%) | "45" |
| `plant_watering/moisture/2` | Publish | Moisture sensor 2 reading (%) | "62" |
| `plant_watering/pump/1/set` | Subscribe | Pump 1 control command | "on"/"off" |
| `plant_watering/pump/2/set` | Subscribe | Pump 2 control command | "on"/"off" |
| `plant_watering/pump/1/state` | Publish | Pump 1 current state | "on"/"off" |
| `plant_watering/pump/2/state` | Publish | Pump 2 current state | "on"/"off" |
| `plant_watering/config` | Subscribe | Configuration updates | JSON config |
## Configuration
### WiFi Settings (menuconfig)
```
CONFIG_WIFI_SSID="Your_SSID"
CONFIG_WIFI_PASSWORD="Your_Password"
```
### MQTT Settings (menuconfig)
```
CONFIG_MQTT_BROKER_URL="mqtt://192.168.1.100:1883"
CONFIG_MQTT_USERNAME="plantwater"
CONFIG_MQTT_PASSWORD="your_password"
```
### Plant Watering Settings (menuconfig)
```
CONFIG_MOISTURE_THRESHOLD_LOW=30 # Start watering below this %
CONFIG_MOISTURE_THRESHOLD_HIGH=70 # Stop watering at this %
CONFIG_WATERING_MAX_DURATION_MS=30000 # Max pump runtime (30s)
CONFIG_WATERING_MIN_INTERVAL_MS=300000 # Min time between watering (5min)
```
## Building and Flashing
### Using Docker (Recommended)
#### Configure the project
```bash
docker run --user $(id -u):$(id -g) --rm -v $PWD:/project -w /project -it espressif/idf:latest idf.py menuconfig
```
#### Build
```bash
docker run --user $(id -u):$(id -g) --rm -v $PWD:/project -w /project -it espressif/idf:latest idf.py build
```
#### Flash via USB
```bash
docker run --privileged --rm -v $PWD:/project -w /project --device=/dev/ttyACM0 -it espressif/idf:latest idf.py flash -p /dev/ttyACM0
```
#### Monitor serial output
```bash
docker run --privileged --rm -v $PWD:/project -w /project --device=/dev/ttyACM0 -it espressif/idf:latest idf.py monitor -p /dev/ttyACM0
```
#### Flash and monitor in one command
```bash
docker run --privileged --rm -v $PWD:/project -w /project --device=/dev/ttyACM0 -it espressif/idf:latest idf.py flash monitor -p /dev/ttyACM0
```
Note: Replace `/dev/ttyACM0` with your actual device port (could be `/dev/ttyUSB0`, `/dev/ttyACM1`, etc.)
### Using Local ESP-IDF Installation
```bash
# Configure the project
idf.py menuconfig
# Build
idf.py build
# Flash via USB
idf.py -p /dev/ttyUSB0 flash monitor
```
### OTA Updates
1. Connect to the same network as the ESP32
2. Navigate to `http://<ESP32_IP>/`
3. Upload the `build/PlantWater.bin` file
4. Device will automatically restart with new firmware
## Testing with MQTT
### Monitor All Topics
```bash
# Using Docker
docker run -it --rm --network mqtt-broker_mqtt-network eclipse-mosquitto:2.0.22 \
mosquitto_sub -h mosquitto -u monitor -P password -t "plant_watering/#" -v
# Using local mosquitto
mosquitto_sub -h 192.168.1.100 -u monitor -P password -t "plant_watering/#" -v
```
### Control Pumps
```bash
# Turn Pump 1 ON
docker run -it --rm --network mqtt-broker_mqtt-network eclipse-mosquitto:2.0.22 \
mosquitto_pub -h mosquitto -u home-server -P password -t "plant_watering/pump/1/set" -m "on"
# Turn Pump 1 OFF
docker run -it --rm --network mqtt-broker_mqtt-network eclipse-mosquitto:2.0.22 \
mosquitto_pub -h mosquitto -u home-server -P password -t "plant_watering/pump/1/set" -m "off"
# Turn Pump 2 ON
docker run -it --rm --network mqtt-broker_mqtt-network eclipse-mosquitto:2.0.22 \
mosquitto_pub -h mosquitto -u home-server -P password -t "plant_watering/pump/2/set" -m "on"
# Turn Pump 2 OFF
docker run -it --rm --network mqtt-broker_mqtt-network eclipse-mosquitto:2.0.22 \
mosquitto_pub -h mosquitto -u home-server -P password -t "plant_watering/pump/2/set" -m "off"
```
### Local mosquitto commands (if installed)
```bash
# Subscribe to all topics
mosquitto_sub -h 192.168.1.100 -u monitor -P password -t "plant_watering/#" -v
# Control pumps
mosquitto_pub -h 192.168.1.100 -u home-server -P password -t "plant_watering/pump/1/set" -m "on"
mosquitto_pub -h 192.168.1.100 -u home-server -P password -t "plant_watering/pump/1/set" -m "off"
```
## Current Behavior
When the system is running:
1. **On boot**: Connects to WiFi, then MQTT broker
2. **Status**: Publishes "online" to `plant_watering/status`
3. **Sensors**: Publishes simulated moisture readings every 10 seconds
4. **Commands**: Responds to pump on/off commands
5. **Feedback**: Publishes pump state changes to state topics
6. **Disconnect**: LWT publishes "offline" to status topic
## Project Structure
```
main/
├── CMakeLists.txt # Build configuration
├── Kconfig.projbuild # menuconfig options
├── main.c # Main application
├── wifi_manager.c/h # WiFi connection management
├── ota_server.c/h # OTA update server
├── plant_mqtt.c/h # MQTT client implementation
├── led_strip.c/h # RGB LED control (from template)
├── motor_control.c/h # (TODO) Pump motor control
└── moisture_sensor.c/h # (TODO) Sensor reading
```
## Credential Management
Both WiFi and MQTT credentials are stored in NVS (Non-Volatile Storage):
- **First boot**: Uses menuconfig defaults and saves to NVS
- **Subsequent boots**: Loads from NVS
- **OTA updates**: Preserves NVS (credentials survive updates)
To update credentials after deployment:
1. Change in menuconfig
2. Add temporary force-update code
3. Build and OTA update
4. Remove temporary code and update again
Or erase flash completely: `idf.py erase-flash`
## Version History
- **v2.0.0-mqtt**: Added MQTT client with NVS storage
- **v1.0.1**: Initial OTA-enabled template
- **v1.0.0**: Basic LED blink example
## Troubleshooting
### MQTT Connection Issues
- Check broker is running: `docker ps`
- Verify credentials match broker configuration
- Ensure ESP32 and broker are on same network
- Check firewall rules for port 1883
### WiFi Connection Issues
- Verify SSID has no trailing spaces
- Check password is correct
- Ensure 2.4GHz network (ESP32 doesn't support 5GHz)
- Try erasing flash and reflashing
### OTA Update Issues
- Ensure device is connected to network
- Check partition table has OTA partitions
- Verify firmware size fits in OTA partition
- Try accessing `http://<ESP32_IP>/test` to verify server
## Next Development Steps
1. **Motor Control Module**
- PWM speed control
- Safety timeouts
- Current monitoring
2. **Moisture Sensor Module**
- ADC calibration
- Averaging/filtering
- Percentage conversion
3. **Automation Logic**
- Threshold-based watering
- Time-based schedules
- Prevent overwatering
4. **Enhanced Features**
- Web dashboard
- Historical data logging
- Multi-zone support
- Weather API integration
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