Abstract: A system for facilitating provisioning of a virtual experience is disclosed. The system may include a communication device configured for receiving at least one first sensor data from at least one first sensor of a first vehicle and at least one second sensor data from at least one second sensor of a second vehicle. Further, the communication device may be configured for transmitting at least one first presentation data to at least one first presentation device and at least one second presentation data to at least one second presentation device. Further, the at least one presentation device may be configured for presenting the at least one first presentation data and the at least one second presentation data. Further, the system may include a processing device configured for generating the at least one first presentation data and the at least one second presentation data.

Abstract: Systems, methods, and computer products according to the principles of the present inventions may involve a training system for a pilot of an aircraft. The training system may include an aircraft sensor system affixed to the aircraft adapted to provide a location of the aircraft, including an altitude of the aircraft, speed of the aircraft, and directional attitude of the aircraft. It may further include a helmet position sensor system adapted to determine a location of a helmet within a cockpit of the aircraft and a viewing direction of a pilot wearing the helmet. The helmet may include a see-through computer display through which the pilot sees an environment outside of the aircraft with computer content overlaying the environment to create an augmented reality view of the environment for the pilot.

Abstract: Systems, methods, and computer products according to the principles of the present inventions may involve a training system for a pilot of an aircraft. The training system may include an aircraft sensor system affixed to the aircraft adapted to provide a location of the aircraft, including an altitude of the aircraft, speed of the aircraft, and directional attitude of the aircraft. It may further include a helmet position sensor system adapted to determine a location of a helmet within a cockpit of the aircraft and a viewing direction of a pilot wearing the helmet. The helmet may include a see-through computer display through which the pilot sees an environment outside of the aircraft with computer content overlaying the environment to create an augmented reality view of the environment for the pilot.

Abstract: Aspects of the present inventions relate to eye imaging system for head worn computer display systems. In embodiments, a camera and infrared light source are positioned behind a backlighting system and directed to image a user's eye through the optical path used for the display.

Abstract: Aspects of the present inventions relate to regulation of display brightness for head worn computer display systems. In embodiments, a display's maximum brightness may be regulated by monitoring pupil size.

Abstract: A method, includes saving in-flight data from an aircraft during a simulated training exercise, wherein the in-flight data includes geospatial locations of the aircraft, positional attitudes of the aircraft, and head positions of a pilot operating the aircraft, saving simulation data relating to a simulated virtual object presented to the pilot as augmented reality content in-flight, wherein the virtual object was programmed to interact with the aircraft during the simulated training exercise and representing the in-flight data from the aircraft and the simulation data relating to the simulated virtual object as a replay of the simulated training exercise.

Abstract: Aspects of the present inventions relate to back lighting systems for computer displays. Embodiments involve using a laser, expanded and holographic surfaces to generate a plane of light configured to illuminate an LCD display.

Abstract: A system includes an event camera mounted in a cockpit of an aircraft, a pre-mapped data set representing the cockpit and a processor adapted to determine a location and a position of a head-mountable device comprising one or more visual markers based, at least in part, on data from the event camera and the pre-mapped data set, wherein the data from the event camera comprises at least one image comprising a portion of the cockpit represented by the pre-mapped data set and one or more of the visual markers.

Abstract: Systems, methods, and computer products according to the principles of the present inventions may involve a training system for a pilot of an aircraft. The training system may include an aircraft sensor system affixed to the aircraft adapted to provide a location of the aircraft, including an altitude of the aircraft, speed of the aircraft, and directional attitude of the aircraft. It may further include a helmet position sensor system adapted to determine a location of a helmet within a cockpit of the aircraft and a viewing direction of a pilot wearing the helmet. The helmet may include a see-through computer display through which the pilot sees an environment outside of the aircraft with computer content overlaying the environment to create an augmented reality view of the environment for the pilot.

Abstract: Systems, methods, and computer products according to the principles of the present inventions may involve a training system for a pilot of an aircraft. The training system may include an aircraft sensor system affixed to the aircraft adapted to provide a location of the aircraft, including an altitude of the aircraft, speed of the aircraft, and directional attitude of the aircraft. It may further include a helmet position sensor system adapted to determine a location of a helmet within a cockpit of the aircraft and a viewing direction of a pilot wearing the helmet. The helmet may include a see-through computer display through which the pilot sees an environment outside of the aircraft with computer content overlaying the environment to create an augmented reality view of the environment for the pilot.

Abstract: A method, includes transmitting data for presenting an augmented reality image of a virtual aircraft positioned at a geospatial location to a pilot operating a real vehicle, wherein the virtual aircraft is presented through a head mounted see-through optical system, transmitting an instruction to present a target lock indication to the pilot, receiving an indication that the pilot has initiated launch of a weapon from the vehicle's weapons system, wherein the indication of launch initiation is communicated to the simulation computer system and the simulation computer system generates a launched weapon, transmitting data for presenting an augmented reality image to the pilot representing the launched weapon and transmitting data for presenting an augmented reality image graphically illustrated as an explosion based at least in part on an estimated intersection of the virtual weapon and virtual aircraft by the simulation computing system.

Abstract: A method, includes receiving training exercise data representative of interactions between at least a real aircraft and a virtually presented aircraft that participated in a simulated training exercise, wherein the exercise data is selected from the group consisting of tracked geospatial locations of the real aircraft, tracked geospatial locations of the virtual aircraft, tracked geospatial locations of a launched virtual missile from the real aircraft, a target lock indicating that a weapons system of the real vehicle had a weapons target lock on the virtual aircraft, an indication that the pilot-initiated launch of a weapon from the vehicle's weapons system and an indication of an explosion based at least in part on an estimated intersection of the virtual weapon and virtual aircraft by the simulation computing system and presenting the training exercise data as a three-dimensional battlefield that adapted to be paused and played.

Abstract: An augmented reality system includes a geospatial location system adapted to identify a current location of a vehicle, a plurality of vehicle condition sensors adapted to identify the vehicle's positional attitude, direction of motion, and speed within an environment at the current location, a helmet position sensor system adapted to determine a location of a helmet within the vehicle and a viewing direction of a pilot wearing the helmet the helmet comprising a see-through computer display through which the pilot is enabled to see an environment outside of the vehicle with computer content overlaying the environment to create an augmented reality view of the environment for the pilot, a data storage module adapted to store the data from the geospatial location system, plurality of vehicle condition sensors and the helmet position sensor with a time of acquisition of each respective type of data and a processor adapted to present geospatially located augmented reality content to the helmet based, at least in p

Abstract: Systems, methods, and computer products according to the principles of the present inventions may involve a training system for a pilot of an aircraft. The training system may include an aircraft sensor system affixed to the aircraft adapted to provide a location of the aircraft, including an altitude of the aircraft, speed of the aircraft, and directional attitude of the aircraft. It may further include a helmet position sensor system adapted to determine a location of a helmet within a cockpit of the aircraft and a viewing direction of a pilot wearing the helmet. The helmet may include a see-through computer display through which the pilot sees an environment outside of the aircraft with computer content overlaying the environment to create an augmented reality view of the environment for the pilot.

Abstract: Systems, methods, and computer products according to the principles of the present inventions may involve a training system for a pilot of an aircraft. The training system may include an aircraft sensor system affixed to the aircraft adapted to provide a location of the aircraft, including an altitude of the aircraft, speed of the aircraft, and directional attitude of the aircraft. It may further include a helmet position sensor system adapted to determine a location of a helmet within a cockpit of the aircraft and a viewing direction of a pilot wearing the helmet. The helmet may include a see-through computer display through which the pilot sees an environment outside of the aircraft with computer content overlaying the environment to create an augmented reality view of the environment for the pilot.

Abstract: Systems, methods, and computer products according to the principles of the present inventions may involve a training system for a pilot of an aircraft. The training system may include an aircraft sensor system affixed to the aircraft adapted to provide a location of the aircraft, including an altitude of the aircraft, speed of the aircraft, and directional attitude of the aircraft. It may further include a helmet position sensor system adapted to determine a location of a helmet within a cockpit of the aircraft and a viewing direction of a pilot wearing the helmet. The helmet may include a see-through computer display through which the pilot sees an environment outside of the aircraft with computer content overlaying the environment to create an augmented reality view of the environment for the pilot.

Abstract: A system, includes a memory in communication with a processor, the memory storing instructions that when executed by the processor cause the processor to receive a first location of a real vehicle, receive an updated location of the real vehicle, compute, utilizing at least the first location and the updated location, a future location of the real vehicle at a predetermined time in the future and output data to a display device adapted to display to a user of the display device at the predetermined time a mixed reality representation of an environment surrounding the real vehicle as viewed from the future location.

Abstract: A system, including a memory in communication with a processor, the memory storing instructions that when executed by the processor cause the processor to create and store a geospatial virtual environment comprising a plurality of entities each having one or more location attributes and corresponding time attributes wherein at least one of the plurality of entities is a virtual asset and wherein at least one of the plurality of entities represents a real vehicle having a defined location within a physical space having spatial coordinates that are mapped to the virtual environment, receive an updated location of the real vehicle, map the received location of the real vehicle to the geospatial virtual environment, update the entity of the geospatial virtual environment corresponding to the real vehicle with the mapped received location and output data comprising a portion of the geospatial virtual environment to a display device adapted to display to an operator of the real vehicle a mixed reality representatio

Abstract: A computer system including a memory in communication with a processor, the memory storing instructions that when executed by the processor cause the processor to maintain a virtual environment, manage a virtual asset within the virtual environment, map a geospatial position of a real vehicle into a position within the virtual environment representative of the geospatial position. determine a measurement between the position of the real vehicle in the virtual environment to the virtual asset and communicate content representative of the virtual asset to a mixed reality optical system configured for an operator of the real vehicle, wherein the content is presented at a time and position based, at least in part, on the measurement.

Abstract: A computer system, includes a memory in communication with a processor, the memory storing instructions that when executed by the processor cause the processor to maintain a virtual environment, manage a virtual asset within the virtual environment, map a geospatial position of a real vehicle into a position within the virtual environment representative of the geospatial position and determine a measurement between the position of the real vehicle in the virtual environment to the virtual asset, wherein one or more attributes of the virtual asset are controlled by a user playing a game comprising the virtual environment and wherein the user controls the virtual asset with respect to a virtual representation of the real vehicle.