Systems and methods designed to facilitate a robust and secure aerial network that supports surveillance and delivery operations of electric battery-powered drones. These operations can be conducted in both autonomous and operator-controlled modes. The integrated system utilizes individual drones and base stations, each functioning as nodes within the aerial network and maintaining continuous internet connectivity. The base stations are equipped to serve as recharge and battery swap points for the drones. Furthermore, the network interfaces with a proprietary, secure internet-based application and servers, which enable the coordination and collaboration of drones, autonomous recharging, and comprehensive data collection. This advanced technology has global operability, extending its reach beyond terrestrial boundaries to other celestial bodies, as long as an internet connection is available.

Systems and methods designed to facilitate a robust and secure aerial network that supports surveillance and delivery operations of electric battery-powered drones. These operations can be conducted in both autonomous and operator-controlled modes. The integrated system utilizes individual drones and base stations, each functioning as nodes within the aerial network and maintaining continuous internet connectivity. The base stations are equipped to serve as recharge and battery swap points for the drones. Furthermore, the network interfaces with a proprietary, secure internet-based application and servers, which enable the coordination and collaboration of drones, autonomous recharging, and comprehensive data collection. This advanced technology has global operability, extending its reach beyond terrestrial boundaries to other celestial bodies, as long as an internet connection is available.

Disclosed is a system for inspecting a structure without physically contacting the structure. The system includes a remotely controlled device that includes a sonar/ultrasound transceiver, a camera and a mapping module for generating geotags corresponding to the structure. The remotely controlled device optionally includes an infrared camera and a lidar. As the remotely controlled device moves along or around the perimeter of the structure, the system collects acoustic, lidar, infrared and photogrammetry data to create a virtual model of the structure. Geotagged acoustic, infrared and lidar data identifying faults in the structure is overlaid on the virtual model of the structure.

In one possible embodiment, an amphibious unmanned aerial vehicle is provided, which includes a fuselage comprised of a buoyant material. Separators within the fuselage form separate compartments within the fuselage. Mounts associated with the compartments for securing waterproof aircraft components within the fuselage. The compartments each have drainage openings in the fuselage extending from the interior of the fuselage to the exterior of the fuselage.

Indoor mapping and modular control for UAVs and other autonomous vehicles, and associated systems and methods. A representative unmanned aerial vehicle system includes a body, a propulsion system carried by the body, a sensor system carried by the body, and a controller carried at least in part by the body and operatively coupled to the propulsion system and the sensor system. The controller is programmed with instructions that, when executed, operate in a first autonomous mode and a second autonomous mode. In the first autonomous mode, the instructions autonomously direct the propulsion system to convey the body along a first route within an indoor environment. While the body travels along the first route, the instructions receive inputs from the sensor system corresponding to features of the indoor environment. The features are stored as part of a 3-D map. In the second autonomous mode, the instructions direct the propulsion system to convey the body along a second route within the indoor environment, based at least in part on the 3-D map, and direct performance of an operation on the second route.

Presently disclosed subject matter integrates a method of using thousands of semi-autonomous unmanned aerial vehicles, herein called drones, to deliver vastly superior amounts of fire retardant over substantially larger and variably-shaped drop patterns. Each drone is able to swap its own batteries with freshly charged batteries and each drone is able to refill its container with water or fire retardant. Once launched, a swarm of drones can perform repeated trips from the water/retardant source to the fire without human involvement other than the high-level tasking of where to drop the retardant. Once a general drop destination and drop pattern shape is designated, the swarm can transport retardant to that location, form itself into the desired drop shape, and deploy retardant. The drone body is designed to be modular so different components can be attached with ease and no special training or knowledge required.

A modular refueling system for an aircraft includes a modular bay recessed within the aircraft. The modular bay includes a modular bay interface. The modular refueling system includes a plurality of payload modules each having a respective function and a payload interface adapted to connect to at least a portion of the modular bay interface. The plurality of payload modules includes an aerial refueling module. The payload modules are interchangeably insertable into the modular bay to enable the modular bay to support the functions of the payload modules. The aerial refueling module is insertable into the modular bay to enable the aircraft to provide fuel to recipient aircraft during flight.

Various embodiments are directed to interconnectable tiles configured for operation in an aquatic environment or a near-zero/zero gravity environment. The interconnectable tiles are configured to interconnect relative to one another to form interconnected surfaces, and individual interconnectable tiles provide thrust, ballast, and/or buoyancy to the overall interconnected surface so as to move the interconnected surface in a desired configuration.

An unmanned aerial vehicle with deployable components (UAVDC) is disclosed. The UAVDC may comprise a fuselage, at least one wing, and at least one control surface. In some embodiments, the UAVDC may further comprise a propulsion means and/or a modular payload. The UAVDC may be configured in a plurality of arrangements. For example, in a compact arrangement, the UAVDC may comprise the at least one wing stowed against the fuselage and the at least one control surface stowed against the fuselage. In a deployed arrangement, the UAVDC may comprise the at least one wing deployed from the fuselage and the least one control surface deployed from the fuselage. In an expanded arrangement, the UAVDC may comprise the at least one wing telescoped to increase a wingspan of the deployed arrangement.

An aircraft system includes an aircraft fuselage having at least one coupling point that is configured to connect various mutually exchangeable drive module units detachably and load-transmittingly to the aircraft fuselage. The aircraft system further includes at least one first drive module unit that is detachably, load-transmittingly and with another drive module unit exchangeably attachable to the at least one coupling point to form a first aircraft comprising the aircraft fuselage and the first drive module unit and at least one second drive module unit that is detachably, load-transmittingly and with another drive module unit exchangeably attachable to the at least one coupling point to form a second aircraft comprising the aircraft fuselage and the second drive module unit. In some embodiments, the first aircraft is a rotary wing aircraft and the second aircraft is a fixed-wing aircraft or a convertiplane.