OPTILOD: Optimal Beacon Placement for High-Accuracy Indoor Localization of Drones

Famili, Alireza; Stavrou, Angelos; Wang, Haining; Jung-Min,; Park, Hae‐Sim

doi:10.48550/arxiv.2201.10691

Cited by 2 publications

(2 citation statements)

References 15 publications

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“…Various internal and external factors come into play, impacting energy usage. For instance, flying into headwinds has been observed to resulted in lower power consumption, attributed to increased thrust generated during the transition from hovering to forward flight [20,21,22,23,24,25]. The weight and payload of UAVs emerge as crucial factors significantly affecting energy consumption [26,27].…”

Section: Analysis Of Power Loss During Flightmentioning

confidence: 99%

A Survey on Methods to Optimize Power Harvesting in Drones

Ismaeal Ahmed,

Abdelghani Ibrahim,

Ahmed. A

et al. 2024

GJRE

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This paper explores the challenges associated with limited battery capacity in drones and presents a comprehensive analysis of strategies to optimize energy harvesting and extend flight durations. Various energy generation methods, including piezoelectric and solar harvesting, are discussed, along with electrical circuit generation for wireless charging and communication-enabled energy delivery. The interdisciplinary nature of drone technology is highlighted, emphasizing the need for ongoing research in renewable energy models and innovative solutions like laser charging. The paper concludes with recommendations for further exploration and refinement of these strategies to enhance the future of UAVs.

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Section: Analysis Of Power Loss During Flightmentioning

confidence: 99%

A Survey on Methods to Optimize Power Harvesting in Drones

Ismaeal Ahmed,

Abdelghani Ibrahim,

Ahmed. A

et al. 2024

GJRE

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“…The utilisation of lithium polymer (LiPo) batteries is prevalent in micro drones, as these batteries possess a limited power capacity. Consequently, it becomes imperative to monitor and assess the specific power requirements of each individual micro drone [34].…”

Section: B Energy Conservationmentioning

confidence: 99%

Network Performance and Technological Feasibility of Unmanned Aerial Vehicles for Network Extension

Ali,

Albermany

2024

Jour. Kufa Math. Comp.

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The operational range of conventional and license-free radio-controlled drones is limited due to line-of-sight restrictions (LoS). There exists a definitive method for operating a drone. Consequently, in order to fly the drone beyond the visual line of sight (BVLoS), it is necessary to replace the drone's original wireless communications equipment with a device that requires a licence and is connected to a cellular network. Long-Term Evolution (LTE), a terrestrial communication technique, enables a drone to establish a real-time connection with a ground station. This connection serves the goals of command and control (C&C) as well as payload delivery. Nevertheless, it is important to note that the electromagnetic environment undergoes changes as altitude increases, which can potentially complicate the process of interfacing with drones over terrestrial cellular networks. The objective of this article is to develop a prototype control system for low-altitude microdrones using LTE technology. Additionally, it seeks to assess the feasibility and effectiveness of cellular connectivity for drones operating at various altitudes. This evaluation will be conducted by examining factors like as latency, handover, and signal strength. At a certain altitude, the received signal experiences a decrease in power level by 20 dBm and a degradation in signal quality by 10 dB. The data throughput of the downlink had a fall of 70%, while the latency exhibited an increase of 94 ms. Despite meeting the basic criteria for drone cellular connection, the existing LTE network necessitates enhancements in order to expand aerial coverage, mitigate interference, and minimise network latency.

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OPTILOD: Optimal Beacon Placement for High-Accuracy Indoor Localization of Drones

Cited by 2 publications

References 15 publications

A Survey on Methods to Optimize Power Harvesting in Drones

A Survey on Methods to Optimize Power Harvesting in Drones

Network Performance and Technological Feasibility of Unmanned Aerial Vehicles for Network Extension

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