A flight stick cockpit simulator ground station system is provided. The system includes a base. The system also includes a yoke control module connected to the base. Further, the system includes a yaw control module connected to the base. Additionally, the system includes a throttle control module connected to the base. The system also includes a manipulator module for an aerial TUC transmitter for remote controlled aircraft connected to the base and configured to receive inputs from the yoke control module, the yaw control module, and the throttle control module and structured to mechanically control the aerial R/C transmitter without the need for electrical or computerized mechanisms.

A flight stick cockpit simulator ground station system is provided. The system includes a base. The system also includes a yoke control module connected to the base. Further, the system includes a yaw control module connected to the base. Additionally, the system includes a throttle control module connected to the base. The system also includes a manipulator module for an aerial TUC transmitter for remote controlled aircraft connected to the base and configured to receive inputs from the yoke control module, the yaw control module, and the throttle control module and structured to mechanically control the aerial R/C transmitter without the need for electrical or computerized mechanisms.

A system for simulating a vehicle may include a designing tool for configured for a vehicle simulation and a simulation tool for controlling simulation characteristics of the vehicle. A method for simulating an object may include displaying a map of a region, displaying a plurality of actions operative on a simulated object, and performing a selected action.

A system for simulating a vehicle may include a designing tool for configured for a vehicle simulation and a simulation tool for controlling simulation characteristics of the vehicle. A method for simulating an object may include displaying a map of a region, displaying a plurality of actions operative on a simulated object, and performing a selected action.

A flight stick cockpit simulator ground station system is provided. The system includes a base. The system also includes a yoke control module connected to the base. Further, the system includes a yaw control module connected to the base. Additionally, the system includes a throttle control module connected to the base. The system also includes a manipulator module for an aerial TUC transmitter for remote controlled aircraft connected to the base and configured to receive inputs from the yoke control module, the yaw control module, and the throttle control module and structured to mechanically control the aerial R/C transmitter without the need for electrical or computerized mechanisms.

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.

Provided is a flight simulation system for an unmanned aerial vehicle capable of performing pilot training of the unmanned aerial vehicle in an environment closer to a real environment. The flight simulation system for an unmanned aerial vehicle includes: an operation data acquisition unit configured to acquire operation data of a virtual unmanned aerial vehicle performed by a trainee; a simulator unit configured to calculate, based on geospatial data of a real space and the operation data, a current position of the virtual unmanned aerial vehicle in the real space; and a display unit configured to generate an image of the virtual unmanned aerial vehicle so that the virtual unmanned aerial vehicle is visually recognizable at the current position in the real space, and to output the generated image to the trainee.

A gimbal on-board a vehicle includes a receiver and a gimbal control system. The receiver is configured to receive a gimbal mode signal indicative of user selection of a gimbal mode from a plurality of gimbal modes. Each gimbal mode of the plurality of gimbal modes causes one or more axes of the gimbal to be stabilized with respect to an environment of the vehicle. The gimbal control system is configured to receive gimbal control data indicative of an attitude of the gimbal, receive position data of the vehicle indicative of a location or an attitude of the vehicle, and generate simulated gimbal response data indicative of a simulated attitude of the gimbal based on (1) the gimbal mode signal, (2) the gimbal control data, and (3) the position data of the vehicle.

A gimbal on-board a vehicle includes a receiver and a gimbal control system. The receiver is configured to receive a gimbal mode signal indicative of user selection of a gimbal mode from a plurality of gimbal modes. Each gimbal mode of the plurality of gimbal modes causes one or more axes of the gimbal to be stabilized with respect to an environment of the vehicle. The gimbal control system is configured to receive gimbal control data indicative of an attitude of the gimbal, receive position data of the vehicle indicative of a location or an attitude of the vehicle, and generate simulated gimbal response data indicative of a simulated attitude of the gimbal based on (1) the gimbal mode signal, (2) the gimbal control data, and (3) the position data of the vehicle.