An imaging device captured images of a scene that includes at least one shooter. Each shooter of the at least one shooter operates an associated firearm to discharge one or more projectile. A positioning mechanism positions an infrared filter in and out of a path between the imaging device and the scene. A processing system processes images of the scene when the infrared filter is positioned in the path to detect projectile discharges in response to each shooter of the at least one shooter firing the associated firearm. The processing system processes images of the scene captured when the infrared filter is positioned out of the path to identify, for each detected projectile discharge, a shooter of the at least one shooter that is associated with the detected projectile discharge.

A highly portable system includes the necessary logic and analysis to provide immediate feedback and corrective instruction for any suitable motion. In particular, the system includes a capability for tracking individual shooter performance in a more comprehensive way, in order to provide an organized and methodical feedback to the shooter for the purpose of data-supported improvement, as well as the opportunity to improve marksmanship using dry-fire techniques, when a shooting range is unavailable and/or to reduce ammunition consumption.

A system has at least one processor, a control subsystem, and an end unit with at least one image sensor. The control subsystem switches operation of the system between first and second modes. In the first mode, an image sensor captures a visible light image of a scene, and a processor analyzes the visible light image to identify a target in the scene and extract target spatial information. In the second mode, an image sensor captures a series of IR images of the scene, and a processor analyzes the IR images to identify firearm projectile strikes on the target based on the extracted spatial information and comparisons between the IR images. In certain embodiments, the same image sensor is used for visible light and IR image, and an IR filter is selectively positioned in an optical path from the scene to the image sensor according to the mode of operation.

The disclosure relates to a viewing optic. In one embodiment, the disclosure relates to a viewing optic having an integrated display system. In one embodiment, the disclosure relates to a viewing optic having an integrated display system for generating images that are projected into the first focal plane of an optical system.

The disclosure relates to a viewing optic. In one embodiment, the disclosure relates to a viewing optic having an integrated display system. In one embodiment, the disclosure relates to a viewing optic having an integrated display system for generating images that are projected into the first focal plane of an optical system.

The disclousre relates to a viewing optic. In one embodiment, the disclosure relates to a viewing optic having an integrated display system. In one embodiment, the disclosure relates to a viewing optic having an integrated display system for generating images that are projected into the first focal plane of an optical system.

A firearm training device can include a firearm frame that has a barrel with a camera disposed at a distal end of the barrel, a grip attached to the barrel, and a trigger in proximity to the grip. The trigger can be configured to toggle an electronic switch. The firearm frame can also include a controller communicatively coupled to the camera and the electronic switch. The controller can be configured to collect an image frame or video segment, via the camera, when the electronic switch is toggled, and generate a composite image or video including the image frame or video segment and a strike indicator overlaid onto the image frame or video segment, whereby the composite image or video demonstrates where a firearm strike would have occurred. In other embodiments, the firearm training device is configured as an attachment for a firearm (e.g., a live firearm or mock firearm).

A device receives an initial velocity of a projectile, determines a barrel position and a barrel orientation of a barrel, determines a target position, a target velocity and a projected target trajectory in relation to the barrel position and barrel orientation, determines a lead position in front of the projected target trajectory of an interception of the projectile at the target and presents the lead position to a user device.

The disclosure relates to a viewing optic. In one embodiment, the disclosure relates to a viewing optic having an integrated display system. In one embodiment, the disclosure relates to a viewing optic having an integrated display system for generating images that are projected into the first focal plane of an optical system.

A system has at least one processor, a control subsystem, and an end unit with at least one image sensor. The control subsystem switches operation of the system between first and second modes. In the first mode, an image sensor captures a visible light image of a scene, and a processor analyzes the visible light image to identify a target in the scene and extract target spatial information. In the second mode, an image sensor captures a series of IR images of the scene, and a processor analyzes the IR images to identify firearm projectile strikes on the target based on the extracted spatial information and comparisons between the IR images. In certain embodiments, the same image sensor is used for visible light and IR image, and an IR filter is selectively positioned in an optical path from the scene to the image sensor according to the mode of operation.