Development of Design Methodology for a Small Solar-Powered Unmanned Aerial Vehicle

Rajendran, Parvathy; Smith, Howard

doi:10.1155/2018/2820717

Cited by 20 publications

(11 citation statements)

References 16 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The propulsion system consists of an electric motor, controller, electronics, gearbox, and propeller. Based on the statistical analysis from Noth [5], the mass of the entire propulsion system is given by: m prop = k prop P level (13) where m prop and k prop are the mass and mass-to-power ratio of the propulsion system, respectively.…”

Section: Propulsion System Massmentioning

confidence: 99%

Design of Low Altitude Long Endurance Solar-Powered UAV Using Genetic Algorithm

Bakar

Liu

et al. 2021

Aerospace

View full text Add to dashboard Cite

This paper presents a novel framework for the design of a low altitude long endurance solar-powered UAV for multiple-day flight. The genetic algorithm is used to optimize wing airfoil using CST parameterization, along with wing, horizontal and vertical tail geometry. The mass estimation model presented in this paper is based on structural layout, design and available materials used in the fabrication of similar UAVs. This model also caters for additional weight due to the change in wing airfoil. The configuration is optimized for a user-defined static margin, thereby incorporating static stability in the optimization. Longitudinal and lateral control systems are developed for the optimized configuration using the inner–outer loop strategy with an LQR and PID controller, respectively. A six degree-of-freedom nonlinear simulation is performed for the validation of the proposed control scheme. The results of nonlinear simulations are in good agreement with static analysis, validating the complete design process.

show abstract

Section: Propulsion System Massmentioning

confidence: 99%

Design of Low Altitude Long Endurance Solar-Powered UAV Using Genetic Algorithm

Bakar

Liu

et al. 2021

Aerospace

View full text Add to dashboard Cite

show abstract

“…Alternatively, solar power panels can be installed for longer flight times as opposed to lithium batteries. In [135], a test was conducted, with a UAV weighing less than 4 kg, that achieve a nine-hour minimum flight time. As optimistic as this seems, the location, the date, as well as solar irradiation should be taken into account, as the experiment was performed during the summer in Cranfield, UK, and the flight time may reduce during other seasons or in other parts of the world.…”

Section: Power Consumption and Flight Timementioning

confidence: 99%

Ionizing Radiation Monitoring Technology at the Verge of Internet of Things

Ahmad

Rahim²,

Nordin

et al. 2021

Sensors

View full text Add to dashboard Cite

As nuclear technology evolves, and continues to be used in various fields since its discovery less than a century ago, radiation safety has become a major concern to humans and the environment. Radiation monitoring plays a significant role in preventive radiological nuclear detection in nuclear facilities, hospitals, or in any activities associated with radioactive materials by acting as a tool to measure the risk of being exposed to radiation while reaping its benefit. Apart from in occupational settings, radiation monitoring is required in emergency responses to radiation incidents as well as outdoor radiation zones. Several radiation sensors have been developed, ranging from as simple as a Geiger-Muller counter to bulkier radiation systems such as the High Purity Germanium detector, with different functionality for use in different settings, but the inability to provide real-time data makes radiation monitoring activities less effective. The deployment of manned vehicles equipped with these radiation sensors reduces the scope of radiation monitoring operations significantly, but the safety of radiation monitoring operators is still compromised. Recently, the Internet of Things (IoT) technology has been introduced to the world and offered solutions to these limitations. This review elucidates a systematic understanding of the fundamental usage of the Internet of Drones for radiation monitoring purposes. The extension of essential functional blocks in IoT can be expanded across radiation monitoring industries, presenting several emerging research opportunities and challenges. This article offers a comprehensive review of the evolutionary application of IoT technology in nuclear and radiation monitoring. Finally, the security of the nuclear industry is discussed.

show abstract

“…Hence they required a kind of power source which can feed them with power continuously. The utilization of solar power [52], [53] can be a prominent source of power for the UAVs. Fig.…”

Section: Power Source For Uavsmentioning

confidence: 99%

UAV Assisted 5G Het-Net: A Highly Supportive Technology for 5G NR Network Enhancement

Mahbub¹

2020

EAI Endorsed Trans IoT

View full text Add to dashboard Cite

Recently, unmanned aerial vehicles (UAVs) have grabbed impressive attention from industry and research network, because of the faster growth in a wide scope of applications. Especially, UAVs are being utilized to ensure a better solution to a dependable and costeffective wireless communication network from the sky. The adoption of UAVs has been considered as an alternative supplement of existing cellular networks, to accomplish better transmission efficiency with enhanced coverage and network capacity. This article has represented some wireless communication scenarios where UAVs can be utilized to ensure better coverage, enhancement of efficiency and capacity. After that, to establish the effectiveness of UAVs in wireless communication the paper has included several performance scenarios (path loss, attenuation, and data rate) after utilizing UAVs in the wireless network. Finally concluded with discussing several challenges for UAV assisted wireless networks and the scopes of further enhancement of such kind of networks. This article might be informative to those who are engaged in research regarding UAV assisted wireless communication.

show abstract

Development of Design Methodology for a Small Solar-Powered Unmanned Aerial Vehicle

Cited by 20 publications

References 16 publications

Design of Low Altitude Long Endurance Solar-Powered UAV Using Genetic Algorithm

Design of Low Altitude Long Endurance Solar-Powered UAV Using Genetic Algorithm

Ionizing Radiation Monitoring Technology at the Verge of Internet of Things

UAV Assisted 5G Het-Net: A Highly Supportive Technology for 5G NR Network Enhancement

Contact Info

Product

Resources

About