Implications of longitude and latitude on the size of solar-powered UAV

“…As defined in a previous study [16], the parameters (see Figure 1) include aerodynamics, performance, stability and control, mass estimation, solar irradiance amount, mission profile, and electric propulsion systems [18]. Aerodynamics analysis determines the amount of lift and drag required for the UAV to fly, which are affected by the maximum take-off weight (WTOmax), working density (ρ), flying velocity (V), Oswald efficiency (ε), wing areas (S), span (b), and aspect ratio (AR) of the wing.…”

“…In a solar-powered UAV, the solar module will supply power to the UAV, and the excess energy will be used to charge the battery for night operations [16]. A solar-powered UAV requires a large wing for solar module placement, which will directly increase the total weight of the UAV.…”

“…The total platform weight management, ratio of the solar module to the wing area, and solar module power are crucial factors to achieve a lightweight UAV that contributes to long flight endurance [16,17]. Hence, the power obtained from the solar module, which then charges the battery pack, must produce the required power, Prequired (see Equation (5)) to sustain a level flight.…”

“…As defined in a previous study [16], the parameters (see Figure 1) include aerodynamics, performance, stability and control, mass estimation, solar irradiance amount, mission profile, and electric propulsion systems [18]. Solar Impulse 1 is the largest solar-powered UAV built, with a wingspan of 63.4 m and a maximum take-off weight of 1600 kg.…”

“…The SI density varies widely [16,17] because every city has different climate conditions; thus, the optimal sizing of solar-powered UAVs also differs because of the number of required solar cells along the wingspan to supply the required power during the flight. No specific optimization design for solar-powered UAVs suitable for continuous flying at various SI intensity environments has been reported.…”

Perpetual Solar-Powered Flight across Regions around the World for a Year-Long Operation

“…As defined in a previous study [16], the parameters (see Figure 1) include aerodynamics, performance, stability and control, mass estimation, solar irradiance amount, mission profile, and electric propulsion systems [18]. Aerodynamics analysis determines the amount of lift and drag required for the UAV to fly, which are affected by the maximum take-off weight (WTOmax), working density (ρ), flying velocity (V), Oswald efficiency (ε), wing areas (S), span (b), and aspect ratio (AR) of the wing.…”

“…In a solar-powered UAV, the solar module will supply power to the UAV, and the excess energy will be used to charge the battery for night operations [16]. A solar-powered UAV requires a large wing for solar module placement, which will directly increase the total weight of the UAV.…”

“…The total platform weight management, ratio of the solar module to the wing area, and solar module power are crucial factors to achieve a lightweight UAV that contributes to long flight endurance [16,17]. Hence, the power obtained from the solar module, which then charges the battery pack, must produce the required power, Prequired (see Equation (5)) to sustain a level flight.…”

“…As defined in a previous study [16], the parameters (see Figure 1) include aerodynamics, performance, stability and control, mass estimation, solar irradiance amount, mission profile, and electric propulsion systems [18]. Solar Impulse 1 is the largest solar-powered UAV built, with a wingspan of 63.4 m and a maximum take-off weight of 1600 kg.…”

“…The SI density varies widely [16,17] because every city has different climate conditions; thus, the optimal sizing of solar-powered UAVs also differs because of the number of required solar cells along the wingspan to supply the required power during the flight. No specific optimization design for solar-powered UAVs suitable for continuous flying at various SI intensity environments has been reported.…”

Perpetual Solar-Powered Flight across Regions around the World for a Year-Long Operation

Photovoltaic, thermoelectric and electromagnetic generation technologies applied in power systems for mobile unmanned systems

The Selective Zero Emission Power Systems Between NaBH4-Based Fuel Cells and Solar Cells for UAVs