# A Self-Powered, Real-Time, LoRaWAN IoT-Based Soil Health Monitoring System

S. R.Jino Ramson, Walter D. Leon-Salas, Zachary Brecheisen, Erika J. Foster, Cliff T. Johnston, Darrell G. Schulze, Timothy Filley, Rahim Rahimi, Martin Juan Carlos Villalta Soto, Juan A.Lopa Bolivar, Mauricio Postigo Malaga

Resultado de la investigación: Contribución a una revistaArtículorevisión exhaustiva

## Resumen

Typical soil health assessment requires intensive field sampling and laboratory analysis. Although this approach yields accurate results, it can be costly and labor intensive and not suitable for continuous tracking of soil properties. Advances in soil sensor and wireless technologies are poised to replace physical sampling and offline measurement with in-field monitoring. This article reports the development, deployment, and validation of an Internet-of-Things (IoT) system for continuous monitoring of soil health. The end nodes of the proposed system, called soil health monitoring units (SHMUs), are solar powered and can be installed on a field for extended periods of time. Each SHMU transmits soil temperature, moisture, electrical conductivity, carbon dioxide (CO2), and geolocation data wirelessly using long-range wide-area network (LoRaWAN) radio technology. Data are received by a LoRaWAN gateway, which uploads it to a server for long-term storage and analysis. Users can view acquired data through a Web-based dashboard. The following significant experiments were carried out to validate the developed system: 1) a network consisting of eight SHMUs was deployed at an agricultural field site for several weeks and soil health metrics were analyzed using the soil health dashboard; 2) the flexibility of the system was demonstrated by the addition of an extra CO2 sensor allowing an additional variable directly linked to soil health to be recorded; 3) a wireless communication range of 3422 m was estimated at a transmission power of 10 dBm by deploying the developed system on a large field; 4) the average current consumption of a SHMU (including its associated sensors) was estimated to be 13 mA, at this rate, the onboard Li-ion battery is able to sustain a SHMU for several days; and 5) a 7 cm $\times6.5$ cm solar panel was able to fully charge the onboard battery in 14 days while supplying power to the SHMU.

Idioma original Inglés 9344804 9278-9293 16 IEEE Internet of Things Journal 8 11 https://doi.org/10.1109/JIOT.2021.3056586 Publicada - 1 jun. 2021