A system for inspecting an aircraft includes a drone, a base station, and a controller. The drone includes one or more cameras. The base station has a storage compartment configured to store the autonomous drone therein. The controller has a processor and a memory. The memory has instructions stored thereon, which when executed by the processor, cause the base station to drive to a first predetermined location relative to the aircraft, and cause the drone to fly from the storage compartment of the base station to a first predetermined position relative to the aircraft so that the drone can record image data of at least portions of the aircraft with the one or more cameras.

In some embodiments, an apparatus, comprises an unmanned vehicle configured to be disposed with a vehicle and a processor operatively coupled to the unmanned vehicle. The processor is configured to receive a first signal indicating a stop of the vehicle without a user request and a second signal indicating a location of the vehicle. The processor is configured to determine, based on the location of the vehicle, a target location in a pre-defined area surrounding the vehicle. The processor is configured to send a third signal to the unmanned vehicle to instruct the unmanned vehicle to move to the target location to alert other vehicles via a warning regarding occurrence of the stop.

A drone docking/landing system includes: a docking portion having a shape of any one of a polygonal pyramid, a truncated polygonal pyramid, a cone, and a truncated cone and being capable of docking a drone; and a landing portion mounted at a lower portion of the drone, having a lower portion that is open, into which the docking portion is inserted, and having an empty inner space, wherein the landing portion has a shape of any one of a polygonal pyramid, a truncated polygonal pyramid, a cone, and a truncated cone, wherein the shape corresponds to the shape of the docking portion so that the docking portion is inserted into the landing portion.

Obtaining location data in a novel way is considered to be a part of this invention. An exemplary method for doing so includes identifying first positioning information for a data delivery vehicle based at least in part on a plurality of positioning signals received at the data delivery vehicle from a set of satellites of a global navigation satellite system (GNSS). The example method comprises obtaining relative position information associated with a position vector from the data delivery vehicle to a remote vehicle, the remote vehicle being unable to receive the plurality of positioning signals from the set of satellites. The example method comprises determining second positioning information for the remote vehicle based at least in part on the first positioning information and the relative position information. The example method comprises transmitting the second positioning information to the remote vehicle.

A system comprising a computer programmed to identify a connected location of a vehicle at which a user device is connected to a first network and a disconnected location of the vehicle at which the user device is disconnected from the first network. Upon further determining that the user device has not connected to a second network within a first predetermined time, the computer is further programmed to activate an aerial drone container to an open position.

The invention relates to an emergency support robot for polar UAVs, belonging to the technical field of emergency support robots for polar UAVs. The technical problem to be solved is to improve the structure of the existing emergency support robots for polar UAVs. The technical scheme adopted is as follows: the robot is of a car body structure; a support table is arranged on the upper side of the chassis of the car body; a traveling mechanism is arranged on both sides of the chassis of the car body; the two sides of the support table are hinged with a pair of casings through hinged buckles and push rods; the casings are also provided with a wind power plant; the support table is provided with a launching guide rail.

Methods and systems for autonomous item delivery and/or pick up are provided. IN some aspects, a mothership travels along an item route. One or more autonomous delivery vehicles may be dispatched from the mothership as the mothership progresses along the route. Each of the autonomous delivery vehicles may deliver and/or pick-up one or more items at one or more item locations. In addition, as the mothership progresses along its route, it may also stop to facilitate the manual delivery and/or pick-up of additional items via a human operator. Upon completing their delivery and/or pick up tasks, the autonomous delivery vehicles return to the mothership, either at the point at which they dispatched from the mothership, or at a different location along the item delivery route.

A storage case, including, at least one door which is moveable between a first position in which the door is closed and a second position in which the door is opened; a platform, which can support an aerial vehicle; and a mechanical connection means which is connected between the platform and the at least one door, wherein the mechanical connection means is configured such that as the door is moved from its first position to its second position the platform is simultaneously elevated; and as the door is moved from its second position to its first position the platform is simultaneously lowered; and a controller configured to control the mechanical connection means. There is further provided a corresponding method of deploying an aerial vehicle; a corresponding method of storing an aerial vehicle; an assembly including the storage case and an aerial vehicle; and a vehicle including the storage case.

A storage case, including, at least one door which is moveable between a first position in which the door is closed and a second position in which the door is opened; a platform, which can support an aerial vehicle; and a mechanical connection means which is connected between the platform and the at least one door, wherein the mechanical connection means is configured such that as the door is moved from its first position to its second position the platform is simultaneously elevated; and as the door is moved from its second position to its first position the platform is simultaneously lowered; and a controller configured to control the mechanical connection means. There is further provided a corresponding method of deploying an aerial vehicle; a corresponding method of storing an aerial vehicle; an assembly including the storage case and an aerial vehicle; and a vehicle including the storage case.

In one embodiment, a wing for an unmanned aerial vehicle is described. The unmanned aerial vehicle includes a first body of the wing with a first end proximate a body of the vehicle. A second end is opposite the first end. A first joint is on the first end of the first main body of the wing. The joint rotatably couples the wing to the vehicle. A second joint is on the second end of the vehicle. A second body of the wing is rotatably coupled to the first body via the second joint.