Wireless Communications for Internet of Farming: An Early 5G Measurement Study

Damsgaard, Sebastian Bro; Marcano, Néstor J. Hernández; Nørremark, Michael; Jacobsen, Rune Hylsberg; Rodríguez, Inés González; Mogensen, Preben

doi:10.1109/access.2022.3211096

Cited by 10 publications

(6 citation statements)

References 32 publications

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“…Drone-to-Cloud (D2C) communication is dependent on the internet connectivity provided in the inspection area and its characteristics. Mobile networks with 5G are suitable candidates to provide this access with effective data rates in rural areas of up to 100 Mbps [36]. Table 2 motivates the technology choices for different types of communication and their compliance to key requirements.…”

Section: Communication Servicesmentioning

confidence: 99%

Design of an Autonomous Cooperative Drone Swarm for Inspections of Safety Critical Infrastructure

et al. 2023

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Inspection of critical infrastructure with drones is experiencing an increasing uptake in the industry driven by a demand for reduced cost, time, and risk for inspectors. Early deployments of drone inspection services involve manual drone operations with a pilot and do not obtain the technological benefits concerning autonomy, coordination, and cooperation. In this paper, we study the design needed to handle the complexity of an Unmanned Aerial System (UAS) to support autonomous inspection of safety-critical infrastructure. We apply a constructive research approach to link innovation needs with concepts, designs, and validations that include simulation and demonstration of key design parts. Our design approach addresses the complexity of the UAS and provides a selection of technology components for drone and ground control hardware and software including algorithms for autonomous operation and interaction with cloud services. The paper presents a drone perception system with accelerated onboard computing, communication technologies of the UAS, as well as algorithms for swarm membership, formation flying, object detection, and fault detection with artificial intelligence. We find that the design of a cooperative drone swarm and its integration into a custom-built UAS for infrastructure inspection is highly feasible given the current state of the art in electronic components, software, and communication technology.

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Section: Communication Servicesmentioning

confidence: 99%

Design of an Autonomous Cooperative Drone Swarm for Inspections of Safety Critical Infrastructure

et al. 2023

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“…This technology covers a range of radio frequencies, spanning from 2.4 to 60 GHz, and precisely defines the structure of data packets [23], [33]. WiFi is widely adopted across a spectrum of devices, primarily due to its coverage range, typically 3-7 km, with a large transmitting antenna and its potential to achieve information transfer speeds of up to 700 Mbps [109], [110].…”

Section: ) Wifimentioning

confidence: 99%

Internet of Things and Wireless Sensor Networks for Smart Agriculture Applications: A Survey

Mowla,

Shah

et al. 2023

IEEE Access

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The increasing food scarcity necessitates sustainable agriculture achieved through automation to meet the growing demand. Integrating the Internet of Things (IoT) and Wireless Sensor Networks (WSNs) is crucial in enhancing food production across various agricultural domains, encompassing irrigation, soil moisture monitoring, fertilizer optimization and control, early-stage pest and crop disease management, and energy conservation. Wireless application protocols such as ZigBee, WiFi, SigFox, and LoRaWAN are commonly employed to collect real-time data for monitoring purposes. Embracing advanced technology is imperative to ensure efficient annual production. Therefore, this study emphasizes a comprehensive, futureoriented approach, delving into IoT-WSNs, wireless network protocols, and their applications in agriculture since 2019. It thoroughly discusses the overview of IoT and WSNs, encompassing their architectures and summarization of network protocols. Furthermore, the study addresses recent issues and challenges related to IoT-WSNs and proposes mitigation strategies. It provides clear recommendations for the future, emphasizing the integration of advanced technology aiming to contribute to the future development of smart agriculture systems. INDEX TERMSInternet of things, wireless sensor networks, wireless network protocols, smart agriculture applications.

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“…Furthermore, the tracking motors of the Starlink antenna were disabled to avoid tracking while moving, since connection would be lost every time the antenna would be tracking for the optimal serving satellite. This is not a drawback for our measurement purpose, as the focus is put on agricultural and farming use cases, which typically happen at low speeds as well [9]. It is also worth mentioning that, at the time of measuring, the north of Denmark is mostly covered by orbits passing over the north of Germany, so the density of the orbit is still not fully optimized.…”

Section: Measurement Campaign a Measurement Scenario And Measurement ...mentioning

confidence: 99%

“…We focus on smart agriculture use cases to set a latency reference for evaluating performance. In [9], the authors provide a list of relevant agricultural applications where latency is a critical aspect. Examples such as vehicle platooning for joint operation, remote control of machinery, or real-time data exchange between machinery and data center, prove the need for low latency services (between 10 and 100 ms) with reliability values between 10 −2 and 10 −5 .…”

Section: Introductionmentioning

confidence: 99%

Connecting Rural Areas: an Empirical Assessment of 5G Terrestrial-LEO Satellite Multi-Connectivity

López,

Damsgaard,

Rodríguez

et al. 2023

2023 IEEE 97th Vehicular Technology Conference (VTC2023-Spring)

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The digital transformation accomplished in recent years in the agricultural, farming, forestry, and transport industries has led to a series of emerging connectivity-based use cases that demand ubiquitous coverage. In such a scenario, Non-Terrestrial Networks (NTN), and their integration with Terrestrial Networks (TN), will play a key role to achieve global and seamless connectivity. This paper evaluates the current service provided by cellular terrestrial networks in rural areas and proposes and investigates a multi-connectivity solution for the use of TN and NTN to improve such service. Experimental data was gathered along a route covering more than 250 km in a rural area, using two multi-band cellular modems connected over public 5G non-standalone (NSA) cellular networks from two different operators and a SpaceX Starlink User Terminal (UT) connected to the Starlink Low Earth Orbit (LEO) satellite network. The multi-connectivity solution that we propose can be easily implemented, and results show that having an additional link to a satellite network avoids service degradation due to a lack of cellular coverage in up to 20 % of the route. The proposed solution also allows achieving round-trip latency targets of 100 ms with 99.99% reliability.

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Wireless Communications for Internet of Farming: An Early 5G Measurement Study

Cited by 10 publications

References 32 publications

Design of an Autonomous Cooperative Drone Swarm for Inspections of Safety Critical Infrastructure

Design of an Autonomous Cooperative Drone Swarm for Inspections of Safety Critical Infrastructure

Internet of Things and Wireless Sensor Networks for Smart Agriculture Applications: A Survey

Connecting Rural Areas: an Empirical Assessment of 5G Terrestrial-LEO Satellite Multi-Connectivity

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