A heliport docking system provides automated transport, fueling, maintenance, and logistical management of VTOLs. The heliport docking system can include a plurality of helipads that can be autonomously transported from area-to-area to assist in the logistics of heliport management and control. The helipad system can include a surface on which a VTOL can land and a controller that can perform functions related to routing, maintenance, object detection, and transport, among others. The helipad system can releasably secure the VTOL to the helipad and transport the VTOL to different areas of the heliport system. The helipad system can also fuel the VTOL by providing, electricity, combustible fuel, or other suitable energy source, and perform a maintenance check of the VTOL and create maintenance crew of any VTOL irregularities.

A public transportation system combines a unique combination of components that includes interoperable electric-powered vehicles, facilities, hardware and software having specifications, standards, processes, capabilities, nomenclature, and concepts of operations that together include a concerted, comprehensive, multi-modal, future system for moving people and goods that is herein named Quiet Urban Air Delivery (QUAD) and in which uniquely-capable, ultra-quiet, one to six-seat, electrically-powered, autonomous aircraft (SkyQarts) fly sub-193 kilometer trips on precise trajectories with negligible control latency and perform extremely short take-offs and landings (ESTOL) with curved traffic patterns at a highly-distributed network of very small, airports (“SkyNests”) that themselves have standardized compatible facilities that interoperate with SkyQarts as well as with versatile, autonomous electric-powered payload carts (EPCs) and robotic delivery carts (RDCs) to provide safe, fast, on-demand, community-acceptable, environmentally friendly, high-capacity, affordable door-to-door delivery of both passengers and cargo across urban, suburban and rural settings across the globe.

A public transportation system combines a unique combination of components that includes interoperable electric-powered vehicles, facilities, hardware and software having specifications, standards, processes, capabilities, nomenclature, and concepts of operations that together include a concerted, comprehensive, multi-modal, future system for moving people and goods that is herein named Quiet Urban Air Delivery (QUAD) and in which uniquely-capable, ultra-quiet, one to six-seat, electrically-powered, autonomous aircraft (SkyQarts) fly sub-193 kilometer trips on precise trajectories with negligible control latency and perform extremely short take-offs and landings (ESTOL) with curved traffic patterns at a highly-distributed network of very small, airports (“SkyNests”) that themselves have standardized compatible facilities that interoperate with SkyQarts as well as with versatile, autonomous electric-powered payload carts (EPCs) and robotic delivery carts (RDCs) to provide safe, fast, on-demand, community-acceptable, environmentally friendly, high-capacity, affordable door-to-door delivery of both passengers and cargo across urban, suburban and rural settings across the globe.

The invention relates to a hybrid drone for transporting or delivering objects 124, comprising at least one first wing 102 having an airfoil, at least one first and one second longitudinal drive unit 104, wherein the first longitudinal drive unit 104 and the second longitudinal drive unit 104 are arranged on the at least one wing 102, an object-holding device 110 formed on an upper side or on an underside between the first and second longitudinal drive units 104 and for holding an object 124, and a regulating unit formed for regulating the hybrid drone, in particular the drive units, based on control signals. The hybrid drone further comprises at least one first high drive unit 105, wherein the first high drive unit 105 is aligned or is pivotally alignable such that a thrust force that can be generated by means of the high drive unit 105 acts substantially orthogonally to the longitudinal direction 106 and substantially parallel to a vertical axis 116 of the hybrid drone, and the first high drive unit 105 is arranged with a defined lever distance relative to the center of gravity of the hybrid drone, and wherein a pitch angle of the hybrid drone in the flight state is adjustable by means of the first high drive unit 105. In addition, at least one holding element is provided, which is associated with the underside in a front region of the hybrid drone, wherein the holding element is configured for releasably arranging, in particular for hooking, the hybrid drone on a top-ending vertical receiving structure.

A method for sheltering a balloon, a blimp, or airship. The method includes obtaining a first guideway by detachably attaching a first plurality of detachable rings to a first side of an outer surface of the balloon, placing a first rope into the first guideway by passing the first rope through the first plurality of detachable rings, attaching a first end of the first rope to a first point of a blanket, and pulling the blanket over the balloon by pulling a second end of the first rope in a first direction pulling the blanket over the balloon by pulling a second end of the first rope in a first direction.

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.

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.

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.

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.

The present disclosure describes various systems and methods configured to: launch a fixed-wing aircraft from a moving object into free, wing-borne flight using a multicopter; retrieve the multicopter after fixed-wing aircraft launch using a retrieval winch; retrieve the fixed-wing aircraft from free, wing-borne flight back onto the moving object using the multicopter; and retrieve the multicopter after fixed-wing aircraft retrieval using the retrieval winch.