A Tutorial on Agricultural IoT: Fundamental Concepts, Architectures, Routing, and Optimization

Effah, Emmanuel; Thiaré, Ousmane; Wyglinski, Alexander M.

doi:10.3390/iot4030014

Cited by 4 publications

(1 citation statement)

References 115 publications

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“…The communication unit, depending on the routing architecture of the WSN, can be cell phones (e.g., 4G/5G/LTE/NB-IoT), low-power (e.g., long-range, Bluetooth low energy, SIGFOX ® V2, Zigbee ® 3), Lo-RaWAN, WiFi, or another suitable communication technology. Finally, the WSN can be directly energized with the electricity line or battery-powered with/without the support of energy harvesting techniques, such as photovoltaic cells or piezoelectric transductors [7][8][9][10][11][12][13][14][15].…”

Section: Introductionmentioning

confidence: 99%

Implementation of a Wireless Sensor Network for Environmental Measurements

Woo-García,

Pérez-Vista,

Sánchez-Vidal

et al. 2024

Technologies

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Nowadays, the need to monitor different physical variables is constantly increasing and can be used in different applications, from humidity monitoring to disease detection in living beings, using a local or wireless sensor network (WSN). The Internet of Things has become a valuable approach to climate monitoring, daily parcel monitoring, early disease detection, crop plant counting, and risk assessment. Herein, an autonomous energy wireless sensor network for monitoring environmental variables is proposed. The network’s tree topology configuration, which involves master and slave modules, is managed by microcontrollers embedded with sensors, constituting a key part of the WSN architecture. The system’s slave modules are equipped with sensors for temperature, humidity, gas, and light detection, along with a photovoltaic cell to energize the system, and a WiFi module for data transmission. The receiver incorporates a user interface and the necessary computing components for efficient data handling. In an open-field configuration, the transceiver range of the proposed system reaches up to 750 m per module. The advantages of this approach are its scalability, energy efficiency, and the system’s ability to provide real-time environmental monitoring over a large area, which is particularly beneficial for applications in precision agriculture and environmental management.

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Section: Introductionmentioning

confidence: 99%

Implementation of a Wireless Sensor Network for Environmental Measurements

Woo-García,

Pérez-Vista,

Sánchez-Vidal

et al. 2024

Technologies

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A review of novel materials for nano-photocatalytic and optoelectronic applications: Recent perspectives, water splitting and environmental remediation

Njema,

Kibet

2024

Progress in Engineering Science

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Hardware Evaluation of Cluster-Based Agricultural IoT Network

Effah,

Thiare,

Wyglinski

2024

IEEE Access

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In this paper, we present a real-world hardware evaluation of a robust, affordable, locationindependent, simple, and infrastructure-less cluster-based agricultural Internet of Things (CA-IoT) network based on a commercial off-the-shelf (COTS) Bluetooth Low-Energy (BLE) communication technique and Raspberry Pi module 3 B + (RPI 3 B +) to address global food insecurity caused by climate change and increasing global population via precision farming and greenhouses. Using an engineering design approach, an initial centralized agricultural IoT hardware test-bed was implemented with the aid of BLE, RPi 3 B +, DHT22, STEMMA soil moisture sensors, UM25 meters, and LoPy /low-power Wi-Fi modules, among other devices. This test-bed was adapted and modified after the proposed cluster-based architecture to evaluate the performance of CA-IoT networks. This study provides holistic account of our location-independent CA-IoT solution covering the design and deployment experiences that can serve as a reference document to the agricultural Internet of Things (Agri-IoT) community. Additionally, the proposed solution performed satisfactorily when tested under indoor and outdoor (on-farm) environmental conditions in the USA and Senegal. Unlike existing Agri-IoT test-beds, a sample performance evaluation showed that our contextrelevant CA-IoT technology is simple to deploy and manage by inexperienced users and is energy-efficient, location-independent, robust, and task-and size-scalable to provide a rich set of measurements for both educational and commercial purposes.

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A Tutorial on Agricultural IoT: Fundamental Concepts, Architectures, Routing, and Optimization

Cited by 4 publications

References 115 publications

Implementation of a Wireless Sensor Network for Environmental Measurements

Implementation of a Wireless Sensor Network for Environmental Measurements

A review of novel materials for nano-photocatalytic and optoelectronic applications: Recent perspectives, water splitting and environmental remediation

Hardware Evaluation of Cluster-Based Agricultural IoT Network

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