The present invention provides a new system that allows a safer operation of a moving object. The present invention provides a moving object operation system (1) including: a moving object (11); a plurality of operation signal transmitters (12A, 12B) for the moving object; and a synchronization unit (13). The moving object (11) includes: a signal receipt unit (111) that receives operation signals from the operation signal transmitters (12A, 12B). The operation signal transmitters (12A, 12B) include signal transmission units (121A, 121B) that transmit the operation signals to the moving object (11), respectively. The synchronization unit (13) is a unit that synchronizes the operation signal transmitters (12A, 12B).

A remote training apparatus for a drone flight in a mixed reality includes: a processor; and a memory, wherein the memory stores program instructions executable by the processor to generate a virtual flight space using arrangement information of one or more anchors and tags arranged in a physical space for the flight of the drone, and receive and register a flight training scenario generated in the virtual flight space from a second computer belonging to a remote expert group that remotely communicates with a first computer belonging to a drone operator group, wherein the flight training scenario includes one or more virtual obstacles and one or more flight instruction commands, and at least some of the flight instruction commands are mapped to the one or more virtual obstacles, and receive one or more annotations generated by the remote expert group from the second computer to transmit the annotations to the first computer.

A remote training apparatus for a drone flight in a mixed reality includes: a processor; and a memory, wherein the memory stores program instructions executable by the processor to generate a virtual flight space using arrangement information of one or more anchors and tags arranged in a physical space for the flight of the drone, and receive and register a flight training scenario generated in the virtual flight space from a second computer belonging to a remote expert group that remotely communicates with a first computer belonging to a drone operator group, wherein the flight training scenario includes one or more virtual obstacles and one or more flight instruction commands, and at least some of the flight instruction commands are mapped to the one or more virtual obstacles, and receive one or more annotations generated by the remote expert group from the second computer to transmit the annotations to the first computer.

The presently disclosed subject matter includes a Ux V system simulator. According to some examples synthetic images are display on the display device, the synthetic images showing an artificial representation of an environment in which operation of a Ux V is being simulated, the images are shown as if viewed from a vantage point of an imaging payload located onboard the Ux V; the images are processed to extract thereform values of one or more graphic image parameters; responsive to a command issued with respect to the synthetic images, the extracted values are compared with respective predefined reference values; A simulation of the issued command is executed only if the comparison between the extracted values and respective reference values complies with at least one predefined condition, thereby increasing similarity between the operation of the simulator and the operation of the real UAV system being simulated.

The presently disclosed subject matter includes a Ux V system simulator. According to some examples synthetic images are display on the display device, the synthetic images showing an artificial representation of an environment in which operation of a Ux V is being simulated, the images are shown as if viewed from a vantage point of an imaging payload located onboard the Ux V; the images are processed to extract thereform values of one or more graphic image parameters; responsive to a command issued with respect to the synthetic images, the extracted values are compared with respective predefined reference values; A simulation of the issued command is executed only if the comparison between the extracted values and respective reference values complies with at least one predefined condition, thereby increasing similarity between the operation of the simulator and the operation of the real UAV system being simulated.

A method and device used to improve flying education, and reduce pilot student hazard when passing from simulators to the real aircraft, by introducing an intermediary stage where a simulator and a model radio-controlled aircraft with similar features as original is used in a system with many participants, an instructor, flight monitors, command center, mission control, audience located remotely and taking part in the same action via internet telecommunication. The simulator is used to measure biometric parameters of the pilots, certify them, and also for gaming, having fail-safe procedures embedded. System contains a flight-monitoring network, using both goniometry and radar devices, placed on surface and airborne, using these devices as signal repeaters for extensions of communication. The system may be used in missions dangerous to human crews, and by the complexity of simulation it improves the flying, as well as to improve the piloting of RC aircrafts.

A method and device used to improve flying education, and reduce pilot student hazard when passing from simulators to the real aircraft, by introducing an intermediary stage where a simulator and a model radio-controlled aircraft with similar features as original is used in a system with many participants, an instructor, flight monitors, command center, mission control, audience located remotely and taking part in the same action via internet telecommunication. The simulator is used to measure biometric parameters of the pilots, certify them, and also for gaming, having fail-safe procedures embedded. System contains a flight-monitoring network, using both goniometry and radar devices, placed on surface and airborne, using these devices as signal repeaters for extensions of communication. The system may be used in missions dangerous to human crews, and by the complexity of simulation it improves the flying, as well as to improve the piloting of RC aircrafts.

A control method for UAV flight training includes steps of: obtaining a geographic coordinate range of an actual no-fly zone and geographic coordinates of a current takeoff point of the UAV; comparing the geographic coordinates of the current takeoff point of the UAV with the geographic coordinate range of the actual no-fly zone, so as to determine whether the UAV is in a fly zone or not; controlling the UAV to fly along a preset virtual flight route if the UAV is in a fly zone, wherein a preset virtual obstacle is arranged in the preset virtual flight route; obtaining attitude information and geographic coordinates of the UAV during flight; determining a distance between the UAV and the preset virtual obstacle; and determining whether to adjust a flight position of the UAV according to the distance, morphological information of the preset virtual obstacle and the attitude information of the UAV.

Systems, devices and methods are provided for training a user to control a gimbal in an environment. The systems and methods provide a simulation environment to control a gimbal in a virtual environment. The virtual environment closely resembles a real control environment. A controller may be used to transmit simulation commands and receive simulated data for visual display.

Systems, devices and methods are provided for training a user to control a gimbal in an environment. The systems and methods provide a simulation environment to control a gimbal in a virtual environment. The virtual environment closely resembles a real control environment. A controller may be used to transmit simulation commands and receive simulated data for visual display.