Drones with propulsions systems supported in a housing are provided where the orientation of the housing is independent from the orientation of the propulsion system. Drones are provided where a propulsion system is rotatable about a first axis and a second axis that is perpendicular to the first axis, permitting the propulsion system to assume substantially any position with a sphere. Drones are provided where a bladeless inner tube is rotatable about a first axis and a second axis that is perpendicular to the first axis, permitting the inner tube to assume substantially any position within a sphere. Drone systems are provided with connectable unit drones. An unmanned land vehicle is provided having a wheel assembly that is rotatable about a first axis and a second axis that is perpendicular to the first axis, permitting the wheel assembly to assume substantially any position with a sphere.

A lighter-than-air airship has an exoskeleton constructed of spokes and hubs to create a set of connected hexagrams comprised of isosceles triangles wherein the spokes flex and vary in length to produce the slope of said airship's surface. In one embodiment, the exoskeleton connects to a nose cone that includes a cockpit cabin for controlling the airship's operation from a single location that can be physically separated from the exoskeleton in response to catastrophic events and for autonomous and/or remotely piloted operation. An improved means is also provided for landing and unloading cargo, and through use of unmanned aerial vehicles in another embodiment, the airship is configured for remote pickup, transport, delivery and return of payloads such as packages. In yet another embodiment, the airship provides a communications platform for beam form transmission and satellite signal relay, including in combination with the foregoing disclosed attributes.

A remotely controlled multirotor aircraft having a frame that includes a first and a second peripheral portions, to which at least one first and one second motor can be respectively coupled, and a central portion including a first end and a second end, to which the first peripheral portion and the second peripheral portion are respectively coupled, so that the first peripheral portion develops in a plane that is different from that in which the second peripheral portion develops; furthermore, the central portion also includes a coupling mechanism allowing the coupling between the central portion and a mobile device having video acquisition ability.

A system and a method of detecting and notifying of an occurrence of an overboard passenger on a vessel are used to automatically and immediately track and locate the overboard passenger as soon as the passenger has fallen overboard. In order to accomplish this, the method uses at least one tracking beacon and at least one central computing device. The central computing device is mounted onto a water-faring vessel to passively track the status and location of the tracking beacon so that the central computing device can automatically locate the tracking beacon once an overboard occurrence is detected. The tracking beacon utilizes spatial-positioning and orientation data and water submersion data to transmit an emergency alert when the passenger wearing the tracking beacon falls overboard from the water-faring vessel. Once the emergency alert is received, the central computing device executes a rescue response to expedite the rescue of the overboard passenger.

Modern farming is currently being done by powerful ground equipment or aircraft that weigh several tons and treat uniformly tens of hectares per hour. Automated farming can use small, agile, lightweight, energy-efficient automated robotic equipment that flies to do the same job, even able to farm on a plant-by-plant basis, allowing for new ways of farming. A hybrid airship-drone has both passive lift provided by a gas balloon and active lift provided by propellers. A hybrid airship-drone may be cheaper, more stable in flight, and require less maintenance than other aerial vehicles such as quadrocopters. However, hybrid airship-drones may also be larger in size and have more inertia that needs to be overcome for starting, stopping and turning.

A system for an unmanned aerial vehicle can include an altitude control system 320, which further includes a compressor assembly 400, a valve assembly 500, and an electronics control assembly 600. The compressor assembly may include a compressor housing 410 that includes a compressor inlet 402, an outlet 202, and a cavity 414 extending therethrough and joining the inlet to the outlet. A diffuser 408 may be coupled to the compressor housing. A motor housing 407 may be disposed within the central cavity at the inlet of the compressor housing, and a compressor motor 406 may be disposed within the motor housing. An impeller 412 disposed within the compressor housing may be coupled to a driveshaft 444 for rotation therewith. The valve assembly may be coupled to an opening 416 of the compressor inlet. The valve head 502 may be configured to move into and away from the inlet opening so as to change a size of the circumferential area of the inlet opening.

Aspects described herein relate to an apparatus, system, and method for the airborne launch of inflatable, lighter-than-air devices from aircraft. In some instances, a container comprising a drag parachute and a main parachute assembly may be deployed from an aircraft. Drag forces on the container may cause the drag parachute to be expelled from the container. Drag forces on the drag parachute may cause the main parachute assembly to be expelled from the container. The main parachute assembly may include a canopy with an opening and a release channel connecting the opening with the container. The container may further include a balloon inflation mechanism, which may be used to inflate one or more balloon envelopes. The one or more balloon envelopes, after being inflated, may be configured to be released from the container, traverse the release channel, and exit the main parachute assembly through the opening.

The embodiment described herein is a hybrid balloon-multicopter invention. In a similar manner to a multicopter, it incorporates anticlockwise and clockwise rotating rotors to support maneuverability in three dimensional space. However, unlike a multicopter, maneuverability is augmented by the lift force generated by a balloon filled with a lighter than air gas. Furthermore, to support extended day and night operation, one embodiment of the invention includes photovoltaic cells to convert solar energy to electric energy recharging a battery.

Systems and methods are disclosed for controlling a vehicle by generating a multi-dimensional model of a vehicle operating in a 3D environment; determining a hand control gesture as captured by a plurality of cameras or sensors in the vehicle, wherein a sequence of finger, palm or hand movements represents a vehicle control request; determining vehicle control options based on the model, a current state of the vehicle and the environment of the vehicle; and controlling the vehicle to operate based on the model and the 3D environment.

Provided is a balloon-launching apparatus capable of reducing an increase in the size of the apparatus when a large number of housing sections for housing observation balloons are provided. A balloon-launching apparatus 1 includes a plurality of housing sections 41 each formed in a box shape having an opening 321 that opens in an upper part thereof and configured to house a balloon 21, the housing section 41 launching the balloon 21 from the opening 321. The plurality of housing sections 41 are arranged in a matrix shape. Due to the matrix arrangement of the housing sections 41, the balloon-launching apparatus 1 can reduce the creation of dead space even when a large number of the housing sections 41 are disposed and can thus reduce an increase in the size of the balloon-launching apparatus 1.