Abstract
Climate change is driving new solutions to manage water more efficiently. Such solutions involve the development of smart irrigation systems where Internet of Things (IoT) nodes are deployed throughout large areas. In addition, in the mentioned areas, wireless communications can be difficult due to the presence of obstacles and metallic objects that block electromagnetic wave propagation totally or partially. This article details the development of a smart irrigation system able to cover large urban areas thanks to the use of Low-Power Wide-Area Network (LPWAN) sensor nodes based on LoRa and LoRaWAN. IoT nodes collect soil temperature/moisture and air temperature data, and control water supply autonomously, either by making use of fog computing gateways or by relying on remote commands sent from a cloud. Since the selection of IoT node and gateway locations is essential to have good connectivity and to reduce energy consumption, this article uses an in-house 3D-ray launching radio-planning tool to determine the best locations in real scenarios. Specifically, this paper provides details on the modeling of a university campus, which includes elements like buildings, roads, green areas, or vehicles. In such a scenario, simulations and empirical measurements were performed for two different testbeds: a LoRaWAN testbed that operates at 868 MHz and a testbed based on LoRa with 433 MHz transceivers. All the measurements agree with the simulation results, showing the impact of shadowing effects and material features (e.g., permittivity, conductivity) in the electromagnetic propagation of near-ground and underground LoRaWAN communications. Higher RF power levels are observed for 433 MHz due to the higher transmitted power level and the lower radio propagation losses, and even in the worst gateway location, the received power level is higher than the sensitivity threshold (−148 dBm). Regarding water consumption, the provided estimations indicate that the proposed smart irrigation system is able to reduce roughly 23% of the amount of used water just by considering weather forecasts. The obtained results provide useful guidelines for future smart irrigation developers and show the radio planning tool accuracy, which allows for optimizing the sensor network topology and the overall performance of the network in terms of coverage, cost, and energy consumption.
Highlights
The lack of water and water-stressed areas are becoming serious problems to many places around the world
The outdoor locations were chosen by considering aspects such as ease of installation and the existence of line of sight with respect to most of the deployed Internet of Things (IoT) nodes and to the surrounding buildings
The gateway indoor location was selected to be inside one specific building due to its challenging outside enclosure, which is covered by an external metal mesh that acts as a sort of Faraday cage, blocking electromagnetic waves partially
Summary
The lack of water and water-stressed areas are becoming serious problems to many places around the world. According to the United Nations (UN), by 2025, water scarcity will affect 1.8 billion people and two thirds of the population will live under water-stressed conditions [1]. Water demand is expected to grow 50% by 2050 due to the increase in the number of people living in urban areas. Drought is expected to have a widespread short and long-term impact on the everyday life of many people. The present article deals with the latter by designing, implementing, and validating empirically a smart irrigation system that can be deployed in urban and suburban scenarios
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
