A virtual reality simulator is disclosed comprising a chassis configured to receive a cockpit. The cockpit is comprised of one or more control elements to operatively control a virtual reality simulation. A computing device receives input from the one or more control elements and provides a plurality of output signals to a motion system engaged with the chassis. The computing device is positioned within a foldable housing to operate as a heat sink.

An assessment and reporting system may utilize one or more scanning techniques to provide useful assessments and/or reports for structures and other objects. The scanning techniques may be performed in sequence and optionally used to further fine-tune each subsequent scan. The system may receive or determine a pitch of a surface of a structure or otherwise orthogonally align an optical axis of a camera with respect to a planar surface. An imaging system may capture perpendicular images of sample regions that have a defined area-squared.

A method and apparatus for training a user of an aircraft. Simulated controls for the aircraft are provided. A training scenario defines actions to be performed by the user with the simulated controls. An action indicator associated with at least one of the simulated controls is displayed based on the training scenario. Actions by the user with the simulated controls are detected. Operation of the aircraft is simulated based on the detected actions by the user with the simulated controls.

A night vision goggles aided flight simulator system (100) and method for simulating night flight operations. The system comprises a computer (5) programmed with flight simulator software to calculate a flight simulator image (A1,A2); a projection screen (1) configured to receive the flight simulator image (A1,A2); a light projector (2) configured to project the flight simulator image (A1,A2) onto the projection screen (1); and a view tracking device (3) configured to measure a viewing vector (V) of a night vision device (4). The system (100) is configured to mask the projected flight simulator image (A1,A2) as a function of the measured viewing vector (V).

Systems are disclosed relating to a mobile device mounted to a welding helmet such that a wearer of the welding helmet can see a display of the mobile device when wearing the welding helmet. In some examples, the mobile device is mounted such that a camera of the mobile device is unobscured and positioned at approximately eye level, facing the same way the wearer's eyes are facing. In some examples, the simulated training environment may be presented to the user via the display screen of the mobile device, using images captured by the camera of the mobile device, when the mobile device is so mounted to the welding helmet.

The present application relates to a simulation device of flight management system (FMS), comprising a navigable database and a performance database; a display portion; a horizontal section portion and a vertical section portion, wherein the horizontal section portion and vertical section portion provide horizontal route information and vertical route information of the route designated by a user through the navigable database and performance database; and wherein the display portion is mutually integrated with the horizontal section portion and vertical section portion.

An assessment and reporting system may utilize one or more scanning techniques to provide useful assessments and/or reports for structures and other objects. The scanning techniques may be performed in sequence and optionally used to further fine-tune each subsequent scan. The system may receive or determine a pitch of a surface of a structure or otherwise orthogonally align an optical axis of a camera with respect to a planar surface. An imaging system may capture perpendicular images of sample regions that have a defined area-squared.

An unmanned aerial vehicle (UAV) assessment and reporting system may utilize one or more scanning techniques to provide useful assessments and/or reports for structures and other objects. The scanning techniques may be performed in sequence and optionally used to further fine-tune each subsequent scan. The system may include shadow elimination, annotation, and/or reduction for the UAV itself and/or other objects. A UAV may receive or determine a pitch of roof of a structure or otherwise orthogonally align an optical axis of a camera with respect to a planar roof surface. An imaging system may capture perpendicular images of sample regions that have a defined area-squared.

Systems are disclosed relating to a mobile device mounted to a welding helmet such that a wearer of the welding helmet can see a display of the mobile device when wearing the welding helmet. In some examples, the mobile device is mounted such that a camera of the mobile device is unobscured and positioned at approximately eye level, facing the same way the wearer's eyes are facing. In some examples, the simulated training environment may be presented to the user via the display screen of the mobile device, using images captured by the camera of the mobile device, when the mobile device is so mounted to the welding helmet.

The present disclosure relates to a method (300) for displaying a perspective view of the surrounding of an aircraft (100) in an aircraft. The method comprises accessing (310) surrounding information from a database. The surrounding information is photo-based and three-dimensional. The method further comprises processing (320) the accessed surrounding information so that a perspective view of the surrounding of the aircraft is provided. The perspective view of the surrounding correlates to the position of the aircraft and is photo-based with spatially correlated photo-based textures. The method further comprises transmitting (360) the provided perspective view of the surrounding of the aircraft to a displaying unit so that it can be displayed in the aircraft. The present disclosure also relates to a system, an aircraft, a use, a computer program, and a computer program product.