A method and a system for establishing a route of an unmanned aerial vehicle are provided. The method includes identifying an object from surface scanning data and shaping a space, which facilitates autonomous flight, as a layer, collecting surface image data for a flight path from the shaped layer, and analyzing a change in image resolution according to a distance from the object through the collected surface image data and extracting an altitude value on a flight route.

A task processing method includes obtaining a task data loading request; and searching for target task data in a task database according to the task data loading request, where the task database stores task data corresponding to one or more tasks, and the target task data includes a coordinate of a waypoint of a target route of a target task. The method further includes controlling a movable object to reproduce the target task corresponding to the target task data. Controlling the movable object to reproduce the target task includes controlling the movable object to move according to the target route corresponding to the target task data.

An airborne coordinate measuring machine (CMM) includes a noncontact 3D scanner constructed to obtain measurement data of an object under scrutiny and a drone aircraft mechanically coupled to the 3D scanner and constructed to traverse a flight path that is specific to the object under scrutiny.

A computerized system and method for managing a fleet of Unmanned Aerial Systems (UAS) collaboratively performing a mission. The system receives mission requirements comprising mission goals, area of operation, characteristics of each UAS and calculates data acquisition points in the area of operation according to mission goals, sensor types and constraints. It then calculates a flight plan for each UAS. Once flying in the field, the system verifies for each UAS at predetermined intervals during flight the UAS' aerial location at that time and compares the UAS aerial location to the expected aerial location according to flight plan in that time. If necessary, adjustments are made to the flight plan of one or more UAS. Other considerations for flight adjustments are battery power level, mission goal accomplishments, signal quality and more.

To enable a route that satisfies a request of a user who operates an unmanned aerial vehicle to be presented in a style according to a predetermined format, the present invention involves: acquiring departure location information indicating the departure location of an unmanned aerial vehicle and destination location information indicating the destination location thereof; generating a plurality of candidate routes from the departure location to destination location of the unmanned aerial vehicle; executing processing for outputting route information indicating candidate routes that satisfy a predetermined condition among the plurality of generated candidate routes; and outputting the route information in a style that enables output of the routes, which are indicated by the candidate routes that satisfy the predetermined condition, according to the predetermined format.

Systems, devices, and methods for receiving, by a processor having addressable memory, data representing a geographical area for imaging by one or more sensors of an aerial vehicle; determining one or more straight-line segments covering the geographical area; determining one or more waypoints located at an end of each determined straight-line segment, where each waypoint comprises a geographical location, an altitude, and a direction of travel; determining one or more turnarounds connecting each of the straight-line segments, where each turnaround comprises one or more connecting segments; and generating, by the processor, a flight plan for the aerial vehicle comprising: the determined one or more straight-line segments and the determined one or more turnarounds connecting each straight-line segment.

A system for determining a flight plan based on internet connectivity includes at least one processor coupled with a non-transitory processor-readable medium storing processor-executable code for causing the at least one processor to receive internet connectivity data for a plurality of airspace regions, where the internet connectivity data is indicative of an internet connectivity characteristic; and determine a flight plan for an aircraft through at least one region of the plurality of airspace regions based on the internet connectivity characteristic.

An interactive record keeping system includes a display system, a user input device, an input-output interface and a controller. The controller is configured to receive user input data indicative of a user display preference and a known waypoint location from the user input device, receive aircraft data indicative of a current aircraft operating parameter and receive environmental data indicative of a current environmental condition, both correlating with the known waypoint location. The controller is further configured to calculate an aircraft performance parameter based on the received aircraft data; generate display data based on the calculated aircraft performance parameter, the received environmental data, and the user display preference; provide the display data to the display system; and store the calculated aircraft performance parameter and the environmental data in a memory.

A registration authority (RA) server registers unmanned aerial vehicles (UAVs) and their owners/operators (O/O). A UAV is maintained in a flight lock state until a flight plan request from the O/O is approved by the RA, which sends an key-signed approval to unlock the UAV's flight lock. The RA server evaluates a UAV's proposed flight plan based on the attributes of the O/O and UAV, the location and time of the requested flight plan, and a set of flight rules and exclusion zones that are developed in view of privacy assurance, security assurance, flight safety assurance, and ground safety assurance. The flight plan key-signed approval supplied to the UAV by the RA server specifies an inclusion zone that corresponds to a flight plan trajectory to be followed. Once in flight, the UAV maintains real-time knowledge of its position and time to ensure its flight remains within the approved inclusion zone.

Systems and methods are disclosed for generating a digital flight path within complex mission boundaries. In particular, in one or more embodiments, systems and methods generate flight legs that traverse a target site within mission boundaries. Moreover, one or more embodiments include systems and methods that utilize linking algorithms to connect the generated flight legs into a flight path. Moreover, one or more embodiments include systems and methods that generate a mission plan based on the flight path. In one or more embodiments, the generated mission plan enables a UAV to traverse a flight area within mission boundaries and capture aerial images with regard to the target site.