A docking port is for an unmanned aerial vehicle being a rotorcraft, said docking port having at least one primary coil. The docking port has a primary coil housing formed with a funnel shaped indentation adapted to receive a complementary frustoconical shaped external surface of a secondary coil housing positioned on a landing gear of the rotorcraft, and the primary coil is formed to follow closely a funnel shaped indentation surface. The rotorcraft is charged wirelessly by the primary coil in the primary coil housing and a secondary coil in the secondary coil housing. The invention further concerns the landing gear and a system comprising the docking port and the landing gear. A method for docking the unmanned aerial vehicle on the docking port by use of a magnetic homing field is described.

The present disclosure is generally directed to an integrated charging and data transfer station for an electric vehicle. The integrated station includes a charger to transfer electricity to the electric vehicle. A data transfer system of the integrated station includes a fiber optic system to connect the electric vehicle to a network. Optionally, the integrated station can include a roof with a landing station for an unmanned aerial vehicle.

A reconfigurable system capable of autonomously exchanging material from unmanned vehicles of various types and sizes. The system comprises an environmental enclosure, a landing area, a universal mechanical system to load and unload material from the unmanned vehicle, and a central processor that manages the aforementioned tasks. The landing area may comprise a one or more visible or non-visible markers/emitters capable of generating composite images to assist in landing the unmanned vehicle upon the reconfigurable, autonomous system.

Solar powered lamp posts are described. One post includes one or more solar panel assemblies located in an inverted pyramid cavity. The solar panel assemblies are configured to generate energy, for example, by collecting sun light. One or more drone charging stations are also provided which can charge a drone using the energy generated. The post also feature one or more light emitters powered by the energy generated. The post may also include a pyramid structure which supports the solar panel assemblies and the drone charging stations. The pyramid structure can include the solar panel assemblies on outward facing sides and open up to expose the drone charging stations. The solar panel assemblies may include a broom panel array. The array has a multiple power generating panels and a socket which secures each of the power generating panels in a radial direction from a central focal point.

A drone charging station configured to receive at least one drone, the docking station including an elongated docking shaft sized to engage with the at least one drone, the docking shaft having a drone entrance end and a drone exit end opposite the drone entrance end; and a drone guiding thread helically disposed along the elongated docking shaft, the drone guiding thread configured to engage with a corresponding guiding region on the at least one drone to allow the at least drone to move along the drone guiding thread from the drone entrance end to the drone exit end.

Methods and associated systems for autonomous package delivery utilize a UAS/UAV, an infrared positioning senor, and a docking station integrated with a package delivery vehicle. The UAS/UAV accepts a package for delivery from the docking station on the delivery vehicle and uploads the delivery destination. The UAS/UAV autonomously launches from its docked position on the delivery vehicle. The UAS/UAV autonomously flies to the delivery destination by means of GPS navigation. The UAS/UAV is guided in final delivery by means of a human supervised live video feed from the UAS/UAV. The UAS/UAV is assisted in the descent and delivery of the parcel by precision sensors and if necessary by means of remote human control. The UAS/UAV autonomously returns to the delivery vehicle by means of GPS navigation and precision sensors. The UAS/UAV autonomously docks with the delivery vehicle for recharging and preparation for the next delivery sequence.

Ground support equipment for powering an aircraft on the ground, the ground support equipment including: a solid state converter configured to power an aircraft on the ground from an airport power source having a pre-determined maximum power, and a battery charging unit configured to charge an external battery from the airport power source. The solid state converter is configured to measure an instantaneous power drawn by the aircraft. The solid state converter is configured to generate, for controlling the battery charging unit, a control signal indicative of a maximum power available for the battery charging unit based on the difference between the pre-determined maximum power of the airport power source and the instantaneous power drawn by the aircraft.

This invention is directed to antenna for wireless charging systems configured and operable to create strong electromagnetic near fields in a designated volume and by that to improve the coupling between a transmitting antenna and a receiving antenna of a wireless charging system, which improves the efficiency level of the electromagnetic energy transfer between said transmitting and receiving antennas of a wireless charging system, the antenna comprising a conductive material shaped to form two or more revolutions, each revolution adjacent to the previous revolution, wherein each of said revolution having a geometric shape. The antenna is further comprising a ground plane, wherein said formed conductive material is adapted to confine the electromagnetic near field distribution into a charging zone relative to the ground plane.

Systems and methods for facilitating climate control for aerial vehicles are provided. A system includes a climate control infrastructure with devices configured to facilitate climate control operations for aircraft at an aerial facility. The system obtains data associated with a multi-modal transportation service, and aerial vehicles and facilities for providing the service. The vehicle data can include thermal parameters associated with an aerial vehicle that indicate a temperature for aerial components such as a power source, a cabin, or hardware components within the cabin. The system can determine a climate control configuration for a climate control infrastructure of an aerial facility at which the aerial vehicle is located based on the obtained data. The climate control configuration can identify a desired temperature for a component of the aerial vehicle. The system can generate and communicate command signals for controlling the climate control infrastructure to implement the climate control configuration.

An unmanned aerial vehicle includes a main body, a propulsion assembly including a rotary blade and a motor to rotate the rotary blade about a rotation axis, the propulsion assembly being attached to the main body, a rechargeable battery to supply electric power to the propulsion assembly, a leg portion connected to the main body on a lower side of the main body in a vertical direction, and a power receiving coil to provide non-contact power feeding, the power receiving coil being electrically connected to the battery and being provided in the leg portion.