This is a WiFi Soil Monitor reference design based on ESP32-S3 microcontroller for WiFi connectivity, a Type-C USB for power
#referenceDesign #simple-embedded #espressif #template #reference-design
This is a LoRa soil monitor Reference Design. It uses a STM32L031G6U6S microcontroller and a RFM95W-915S2 LoRa transceiver, integrated with sensor interfacing and LED indicators. Communication occurs via USART and SPI. The system is powered using a battery.
#referenceDesign #simple-embedded #stm #template #reference-design
Autonomous irrigation system for up to 4 individual pots. It has an integrated humidity, pressure and temperature sensor, as well as 4 ports for soil moisture sensors. #esp32 #iot #matter
This is a WiFi Soil Monitor reference design based on ESP32-S3 microcontroller for WiFi connectivity, a Type-C USB for power
#referenceDesign #simple-embedded #espressif #template #reference-design
This is a LoRa soil monitor Reference Design. It uses a STM32L031G6U6S microcontroller and a RFM95W-915S2 LoRa transceiver, integrated with sensor interfacing and LED indicators. Communication occurs via USART and SPI. The system is powered using a battery.
#referenceDesign #simple-embedded #stm #template #reference-design
This is a capacitive soil sensor - we use the built-in capacitive touch measurement system built into the ATSAMD10 chip, which will give you a reading ranging from about 200 (very dry) to 2000 (very wet).
This is a LoRa soil monitor Reference Design. It uses a STM32L031G6U6S microcontroller and a RFM95W-915S2 LoRa transceiver, integrated with sensor interfacing and LED indicators. Communication occurs via USART and SPI. The system is powered using a battery.
#referenceDesign #simple-embedded #stm #template #reference-design
This is a LoRa soil monitor Reference Design. It uses a STM32L031G6U6S microcontroller and a RFM95W-915S2 LoRa transceiver, integrated with sensor interfacing and LED indicators. Communication occurs via USART and SPI. The system is powered using a battery.
#referenceDesign #simple-embedded #stm #template #reference-design
designing a plant watering system that automates the watering process using a timer-based setting. The system is designed to ensure that plants receive the correct amount of water at regular intervals, helping to maintain optimal soil moisture levels.
This project combines one soil sensor (resistive or capacetive), one 5V pump in a water tank and a floating switch to detect the water level. Depending on the soil measurment and the configured nominal value the pump can be controlled while the floating switch prevents the pump from running dry. All configurations can be controlled via MQTT.
Autonomous irrigation system for up to 4 individual pots. It has an integrated humidity, pressure and temperature sensor, as well as 4 ports for soil moisture sensors. #esp32 #iot #matter
Project Title: Plant Monitoring and Irrigation System
Overview:
This system is based on the ESP32-S3 and is designed to manage irrigation for a multi-floor building.
Key Features:
Multi-Floor Operation:
The system controls three separate floors.
Each floor's irrigation can be managed independently.
Irrigation and Pump Control:
Each floor uses a solenoid valve to regulate water flow.
The solenoid valves are operated via MOSFETs.
A relay engages an AC water pump when a MOSFET triggers a solenoid valve.
Hardware Interconnects:
Screw Terminal connectors are added for connecting the solenoid valves and the motor pump.
A DC Jack is included to supply power to the system.
User Interface & Connectivity:
Two JST connectors are provided for integrating an OLED display, a rotary encoder, and a pushbutton.
Future enhancements may include the addition of soil moisture sensors.
Remote Control:
The system is designed for future integration with Blynk IoT.
Blynk IoT will offer both manual control and timer-based irrigation modes for each floor.
