A method includes, in response to a determination that one or more authenticated delivery locations includes a first delivery location, identifying, using an unmanned aerial vehicle registry, one or more unmanned aerial vehicles based on at least one unmanned aerial vehicle characteristic associated with a medication delivery request. The method also includes determining, for each unmanned aerial vehicle of the one or more unmanned aerial vehicles, an availability status, selecting an unmanned aerial vehicle based on at least a corresponding availability status and at least one selection criteria, and instructing the unmanned aerial vehicle to transport the medication package from a starting location to the first delivery location.

The present technology relates to a movement assistance device and a movement assistance method capable of safely guiding a user.

A movement assistance device includes a drive control unit configured to control a drive unit to apply, to a user, an assisting force that is a resultant force of a virtual force that is a force for stabilizing a posture of the user and a guiding force that is a force for guiding the user. The present technology can be applied to, for example, a movement assistance system using a drone.

A flight vehicle with a more basic structure and safety measures according to the invention comprises a main body part; a propulsion part provided with one or more propulsion means; a connection part connecting the main body part and the propulsion part in a displaceable manner within a predetermined range; and a wing part provided on at least one of the main body part or the propulsion part. With such a configuration, a flight vehicle with a more basic structure and safety measures can be provided.

The flying conveyor device includes a drone and a conveying module. The drone includes a frame body and a plurality of aeronautic units. The frame body defines a frame hole. The aeronautic units are connected to and are spaced apart angularly around the frame body. The conveying module is connected to the drone, and includes a conveying duct connected to the frame body and having a top duct open end connected to the frame body and spatially communicated with the frame hole, a bottom duct open end lower than the top duct open end, and a slide channel extending from the top duct open end to the bottom duct open end. When the drone ascends, the frame body pulls the top duct open end upward to a high level, and a descending movement is allowed through the frame hole and the slide channel.

A remote health care apparatus is disclosed that incorporates a drone device and a health kit. The drone device includes one or more communication devices, and the drone device is capable of two-way auditory and visual communication. The health kit is capable of being transported by the drone device and can be detached from the drone device. In one embodiment, the health kit contains one or more medical devices selected from the group consisting of biometric measuring devices, specimen collection devices and lab testing tools.

The flying conveyor device includes a drone and a conveying module. The drone includes a frame body and a plurality of aeronautic units. The frame body defines a frame hole. The aeronautic units are connected to and are spaced apart angularly around the frame body. The conveying module is connected to the drone, and includes a conveying duct connected to the frame body and having a top duct open end connected to the frame body and spatially communicated with the frame hole, a bottom duct open end lower than the top duct open end, and a slide channel extending from the top duct open end to the bottom duct open end. When the drone ascends, the frame body pulls the top duct open end upward to a high level, and a descending movement is allowed through the frame hole and the slide channel.