An automatic association system for automating an association of a plurality of devices in a battlefield simulation system. A network polling mode of each of the plurality of devices is initiated. At least one other of the plurality of devices is detected. A movement of the device and the at least one other of the plurality of devices is correlated. A device profile associated with the device is correlated with a movement over time profile of a platform. The device and the at least one other of the plurality of devices are determined to be on the platform based on the movement and the correlation of the device profile with the movement over time profile. The device is authenticated based on the determination and a personal area network between the device and the at least one other of the plurality of devices is established based on the authentication.

A sight frame assembly for a weapon simulator includes one or more connection arms. The connection arms are for slidably coupling the sight frame assembly to the weapon simulator. The connection arms include a passageway for slidably receiving a guide rod that is attached to a sight frame assembly mounting point on the weapon simulator. A spring is positioned in proximity to the guide rod. The sight frame assembly is disposed in a first position along a longitudinal axis of the weapon simulator when the spring is in an uncompressed state, and the sight frame assembly is disposed in a second position along the longitudinal axis of the weapon simulator when the spring is in a compressed state.

Training device (1) with a laser-assisted weapon comprising a central unit (2), at least one receiving unit (8), a laser unit (9) and at least one person-worn pad (9) that can be energized with stimulation current (43), the laser unit (9) of a first training person (11) being arranged on a first weapon (27) and emitting a laser signal (28) in the direction of a receiving unit (8) of a second training person (12), wherein, when the laser signal (28) is detected by the receiving unit (8), this is evaluated as a hit by the central unit (2), and the central unit (2) sends at least one current pulse to the at least one pad (13), wherein, when a hit is detected, the pad (13) delivers a wave-like varying stimulation current (43), which causes muscular contraction pain in the training person.

A Full-Body Inverse Kinematic (FBIK) module for use in tracking a user in a virtual reality (VR) environment. The FBIK module has an enclosure containing a power source, a plurality of active tags with lights for use by a motion tracking system to track the user, and a controller that flashes the lights in distinct patters to identify the user of the FBIK module.

Systems and methods for training firefighters and other first responders are provided. The systems include a plurality of sensors configured to detect at least one ambient condition, such as, temperature; a receiver configured to receive the electric signals from the plurality of sensors; and a digital storage device operatively connected to the receiver and adapted to store the electrical signals corresponding to the detected ambient conditions. The data detected by the sensors can be retrieved for later review, analysis, and training. The systems may include at least one video recorder and/or at least one infrared image recorder each configured to detect images that can be stored for later retrieval and a synchronizing device adapted to synchronize the sensor data with the recorded images for later review. Methods of implementing the systems and portable cases enclosing the system are also provided.

A flight emulation system receives global positioning system (GPS) data into one or more EGIs (embedded GPS/inertial navigation system (INS)) or GPS receivers from a GPS emulator. The GPS data are based on a pre-defined flight trajectory plan of an aircraft. The system calculates real-time positional, orientational, and inertial emulation data using outputs of the EGIs or GPS receivers and platform-specific, flight dynamics data, and then transmits the real-time positional, orientational, and inertial emulation data to one or more subsystems associated with the aircraft for use by operations of the one or more subsystems.

A combat training system for carrying out and monitoring at least one shooting practice and combat scenarios, comprising: at least two components, with a first component being a firearm and a second component being a target object; a device for sensing position information of each of the at least two components; device for sensing spatial orientation information at least for the at least one firearm of the at least two components; and an information processor, in which position information of the at least two components and the orientation information of the at least one firearm is processed and transformed into at least result information. The at least two components each have a clock, which are time-synchronized with each other and each generate coded time signals with a component identifier which individualizes the respective component, and an event sensor is provided on each of the at least two components.

Method and server for supporting generation of scenarios for testing autonomous driving and/or advanced driver assistance system, AD/ADAS, functionality for real world vehicles. A server (101; 500) provides (301) a virtual environment (200) simulating an environment relevant for operation of vehicles having said AD/ADAS functionality and in which is operating: fully computer controlled movable virtual objects (230a-c), human controlled movable virtual objects (220a-c) and at least one virtual AD/ADAS vehicle (210) operating according to said AD/ADAS functionality. The server (101; 500) allows devices (101-103) to remotely connect to the server (105; 500) and users of said devices (101-103) to, via user interfaces of the devices (101-103), control said human controlled movable virtual objects (220a-c), respectively, in the virtual environment (200), and thereby cause generation of scenarios that said at least one virtual AD/ADAS vehicle (210) is subjected to.

Method and system for dynamically modifying visual rendering of a visual element in a computer generated environment from an interactive computer simulation is provided. Pre-defined visual characteristics are associated with the visual element. A tangible instrument module is used to provide one or more commands for controlling a simulated vehicle of the interactive computer simulation. At the interactive computer simulation station, dynamically affecting the visual element is performed by enhancing at least one of a visual contouring of the visual element and one or more pre-identified distinctive visual characteristics of the visual element. Tailoring parameters determined considering at least one of an identity of the trainee in the interactive computer simulation station and an identifier of the visual element are considering when dynamically affecting the visual element in real-time during execution of the interactive computer simulation prior to rendering the visual element for display.

Systems and methods for training firefighters and other first responders are provided. The systems include a plurality of sensors configured to detect at least one ambient condition, such as, temperature; a receiver configured to receive the electric signals from the plurality of sensors; and a digital storage device operatively connected to the receiver and adapted to store the electrical signals corresponding to the detected ambient conditions. The data detected by the sensors can be retrieved for later review, analysis, and training. The systems may include at least one video recorder and/or at least one infrared image recorder each configured to detect images that can be stored for later retrieval and a synchronizing device adapted to synchronize the sensor data with the recorded images for later review. Methods of implementing the systems and portable cases enclosing the system are also provided.