Disclosed is a video processing system including multiple unmanned aerial vehicles (UAVs) configured to capture a video of a fire site, wherein each UAV has a control unit including an input layer and a first hidden layer (hidden layer 1) and a central server connected to the multiple UAVs by wireless communication, wherein the central server includes multiple hidden layers and an output layer. The video processing system performs a learning process to determine whether a fire has occurred using a feature map in which an original video is difficult to recognize and personal information is protected. Thus, it is possible to fundamentally prevent the exposure and infringement of personal information.

A method of tracking a movement of a target by an unmanned aerial vehicle (UAV), the method includes receiving, from a mobile terminal collocating with the target, absolute location coordinate data of the target, acquiring, by a camera of the UAV, image data of the target, determining, based on the absolute location coordinate data and the image data of the target, 3D location coordinate data of the target with respect to the UAV, and controlling, based on the 3D location coordinate data of the target with respect to the UAV, at least one of a direction or a speed of the movement of the UAV, to maintain a constant relative 3D position of the UAV with respect to the target.

A technique for operating unmanned aerial vehicles (UAVs) in a terminal area from which the UAVs are staged includes charging a plurality of the UAVs on charging pads disposed in a staging array at the terminal area. Merchant facilities for preparing packages for delivery by the UAVs are disposed about a periphery of the staging array. The UAVs are relocated under their own propulsion from interior charging pads to peripheral loading pads of the staging array as the peripheral loading pads become available and the UAVs are deemed sufficiently charged and ready for delivery missions.

A UAV having a manual gimbal including a camera, and a flight mode selector configured to select both a flight mode and manually establish a camera position as a function of the selected fight mode. A controller responds to a position of the gimbal or selector to establish the flight mode. The flight mode is selected from several available modes, for example, a horizontal flight mode, a 45-degree flight mode, and a vertical (aerial) flight mode. The flight mode selector is mechanically coupled to the gimbal and establishes a pitch angle of the gimbal, and thus the camera angle attached to the gimbal.

Embodiments of the present invention relate to a method for generating search information of an unmanned aerial vehicle (UAV) and a UAV. The method includes: controlling a gimbal camera apparatus of the UAV to perform surround shooting to obtain character image information when the UAV is in an input locked state; matching the character image information with internal image information of the UAV; and generating the search information of the UAV according to a matching result. Therefore, a user can find the UAV in time according to the search information. In this way, theft is prevented, reducing the user loss.

An aerial vehicle comprises one or more sensors to environmental data, a communication system to receive control inputs from a user, two or more actuators, with each actuator coupled to a rotary wing. The aerial vehicle also comprises a controller to determine a mode of the aerial vehicle based on the environmental data and the control inputs, each mode indicating a set of flight characteristics for the aerial vehicle, generate a gain value based on the mode, the gain value, when used to modify power signals transmitted to actuators of the aerial vehicle, causes the aerial vehicle to conform within the indicated flight characteristics of the determined mode, generate an output signal modified by the gain value based on the input signal, and transmit a power signal based on the output signal to each actuator of the aerial vehicle.

A method for image generation, preferably including: generating a set of mission parameters for a UAV mission of the UAV associated with aerial scanning of a region of interest; controlling the UAV to perform the mission; generating an image subassembly corresponding to the mission; and/or rendering the image subassembly at a display.

A method for automated assignment of a staging pad to an unmanned aerial vehicle (UAV) includes: launching the UAV from a launch location; tracking a drift of the UAV from the launch location; determining a subsequent position of the UAV after the launching based upon geofiducial navigation; calculating an estimated position of the launch location by offsetting the subsequent position by the drift; attempting to match the estimated position to an available staging pad of a plurality of staging pads; and assigning the UAV to the available staging pad when the estimated position successfully matches to the available staging pad.

Methods, systems, and apparatus, including computer programs encoded on a computer storage medium, are described for implementing an unmanned aerial vehicle or drone with ducted fans. The drone includes a housing having a first surface and multiple ducts that each extend from the first surface to a second surface of the housing. The first surface is substantially flat. A respective fan assembly is installed in each of the ducts. The drone includes an internal cavity at a location intermediate two respective ducts and circuitry positioned in the internal cavity. The circuitry is operable to generate control signals used to operate the respective fan assemblies.

The invention relates to a motorized flying craft (10) for measuring the contour of a plurality of regions of interest (12a, 12b, 12c) of a surface of a predetermined object (9) to be inspected, said flying craft (10) comprising a carrier frame (20) and motorized means (11, 13) for lifting and moving said carrier frame (20). The flying craft is characterized in that it further comprises an apparatus (14) for three-dimensional measurement of a region of interest (12a, 12b, 12c) targeted by said apparatus (14), and a management system (34, 35) of said craft configured to be able to switch said craft from a navigation mode, in which the craft can be moved from one region of interest to a subsequent region of interest, to a stabilized mode, in which said motorized lifting and movement means (11, 13) are controlled so as to be able to keep at least one kinematic parameter of said craft constant, making it possible to minimize the vibration of said craft, and in which said measurement apparatus (14) can acquire a three-dimensional measurement of a region of interest.