A system and method for simulating lead of a target includes a network, a simulation administrator and a user device connected to the network, a database connected to the simulation administrator, and a set of position trackers positioned at a simulator site. The user device includes a virtual or augmented reality unit and a computer connected to the network. A target may be simulated or may be a real-world object. The target and the user are tracked to generate a phantom target and a phantom halo. The phantom target and the phantom halo are displayed on the virtual or augmented reality unit at a lead distance and a drop distance from the target.

A system and method for simulating lead of a target includes a network, a simulation administrator and a user device connected to the network, a database connected to the simulation administrator, and a set of position trackers positioned at a simulator site. The user device includes a virtual or augmented reality unit and a computer connected to the network. A target may be simulated or may be a real-world object. The target and the user are tracked to generate a phantom target and a phantom halo. The phantom target and the phantom halo are displayed on the virtual or augmented reality unit at a lead distance and a drop distance from the target.

A method includes providing a visual representation of a targeting environment to a display of a rifle scope, where the visual representation includes a target and a reticle. The method further includes receiving a trigger pull signal at a processor coupled to the display, determining an impact location of a virtual shot in response to receiving the trigger pull signal, and dynamically adjusting the target within the visual representation in response to determining the impact location.

A system trains usage of a firearm and includes an end unit, a processing subsystem, and a control subsystem remotely located from the end unit. The end unit includes an image sensor that is positioned against a target that has a bar code. The image sensor defines a field of view of a scene that includes the target, and the bar code stores encoded information that defines a target coverage zone. The system selectively operates in a first mode and a second mode according to input from the control subsystem. In the first mode the end unit scans the bar code to extract the target coverage zone. In the second mode the image sensor captures a series of images of the target coverage zone, and the processing subsystem analyzes regions of the captured series of images to determine a strike, by a projectile of the firearm, on the target.

The present invention comprises a transmitter unit having at least one infrared (IR) transmitter, a target screen, a plurality of photodiode sensors disposed in a spaced apart relationship about the target screen, and receiver circuitry connecting the photodiode sensors together. The transmitter unit continuously emits an IR signal, which is detected by the photodiode sensors. The receiver circuitry then triangulate the position of the transmitter unit by calculating the differential distances between each of the photodiode sensors and the transmitter unit. The receiver circuitry is able to dynamically update the position of the transmitter unit because the transmitter unit continuously emits an IR signal. The transmitter unit is able to simulate a shot in a number of different ways, including updating the packet update rate or altering the data packet preamble. No return signal is necessary for the transmitter unit to confirm the shot.

A system trains usage of a firearm and includes an end unit, a processing subsystem, and a control subsystem remotely located from the end unit. The end unit includes an image sensor that is positioned against a target that has a bar code. The image sensor defines a field of view of a scene that includes the target, and the bar code stores encoded information that defines a target coverage zone. The system selectively operates in a first mode and a second mode according to input from the control subsystem. In the first mode the end unit scans the bar code to extract the target coverage zone. In the second mode the image sensor captures a series of images of the target coverage zone, and the processing subsystem analyzes regions of the captured series of images to determine a strike, by a projectile of the firearm, on the target.

Firearm simulator targets and firearm simulation systems are disclosed. A firearm simulator target includes a processor, a memory module, a plurality of light emitting diodes, and machine readable instructions stored in the memory module. When executed by the processor, the machine readable instructions cause the firearm simulator target to illuminate a target pattern subset of the plurality of light emitting diodes such that the target pattern subset of the plurality of light emitting diodes are illuminated to display a target pattern. The target pattern subset of the plurality of light emitting diodes that are illuminated includes a first light emitting diode. When executed by the processor, the machine readable instructions further cause the firearm simulator target to receive a signal from the first light emitting diode, and determine a target hit location at the first light emitting diode based on the signal received from the first light emitting diode.

A disruptor device simulation system is described. Embodiments of the of the simulation system include a disruptor device, one or more training cartridges, and a simulator system. The disruptor device can be loaded with training cartridges and implemented in a training scenario. The training cartridges can include a pair of infrared lasers and an infrared emitter. The simulator system can alter the training scenario based detecting pulses of light generated by the lasers and signals from the infrared emitter. In one embodiment, the simulator system can be adapted to determine when a trigger of the disruptor device is pulled and when an arc switch of the disruptor device is pressed. The simulator system can include a sensor adapted to detect the pulses of light generated by the pair of lasers. The simulator system can further include a receiver adapted to detect signals generated by the emitter.

A system to advance human performance in sighting, tracking, recognizing, and reacting to (collectively engaging) moving and stationary objects, for example, advancing skill in engaging targets with a firearm. The system provides conditioning using non-ballistic firearm engagement. Components include software and hardware that provide target and non-target image stimuli that can be manually or automatically generated as stationary or moving stimuli and trainee engagement using a firearm adapted with a transmitter for non-ballistic target engagement. The system includes a database including a plurality of training scenarios, each training scenario including a sequence of stimuli, the sequence of stimuli including targets for the trainee to sight, track, and recognize; a display for the presentation of the sequence of stimuli; and a data processor generating the presentation of the sequence of stimuli on the display, providing an operator interface, and providing performance reporting.

A disruptor device simulation system is described. Embodiments of the of the simulation system include a disruptor device, one or more training cartridges, and a simulator system. The disruptor device can be loaded with training cartridges and implemented in a training scenario. The training cartridges can include a pair of infrared lasers and an infrared emitter. The simulator system can alter the training scenario based detecting pulses of light generated by the lasers and signals from the infrared emitter. In one embodiment, the simulator system can be adapted to determine when a trigger of the disruptor device is pulled and when an arc switch of the disruptor device is pressed. The simulator system can include a sensor adapted to detect the pulses of light generated by the pair of lasers. The simulator system can further include a receiver adapted to detect signals generated by the emitter.