A system for assisting one's vision while aiming a firearm, includes a scope (but may also not include a scope) that is operable to capture light from an object downfield, and an optical collar that is operable to divert some or all of the light captured, and generate an image of the object. The scope has a first end and a second end. The first end captures light from the object located downfield from the first end, and looking through the second end, one receives the light captured by the first end, and generates an image of the object from the captured light. The optical collar includes a camera operable to generate an image from light that the camera receives, a beam-splitter optically aligned with the second end of the scope and operable to reflect a portion of the light captured by the scope's first end toward the camera, and a display operable to show the image generated by the camera from the light that the camera receives.

Embodiments of the present disclosure relate to recording devices coupled to guns that are configured to record events. In an embodiment, a gun-mounted recording device comprises: a sensor configured to: sense the gun is in use; and send an activation signal to a recording device in response to sensing the gun is in use. Further, the recording device is communicatively coupled to the sensor, wherein the recording device is configured to: transition from a lower-power state to a higher-power state in response to receiving the activation signal, wherein the recording device records wherein the higher-power state; and record at least one aspect of the gun's environment in response to transitioning from the lower-power state to the higher-power state.

Embodiments of the present disclosure relate to recording devices coupled to guns that are configured to record events. In an embodiment, a gun-mounted recording device comprises: a sensor configured to: sense the gun is in use; and send an activation signal to a recording device in response to sensing the gun is in use. Further, the recording device is communicatively coupled to the sensor, wherein the recording device is configured to: transition from a lower-power state to a higher-power state in response to receiving the activation signal, wherein the recording device records wherein the higher-power state; and record at least one aspect of the gun's environment in response to transitioning from the lower-power state to the higher-power state.

A peripheral device that is used with a mixed reality system that is thrown by the user of the mixed reality system and captures scene and mapping data of the area the peripheral is thrown into. Upon capturing the scene and mapping data, the peripheral transmits the data (in some embodiments, including processed results of evaluation of the data) to the mixed reality system. The mixed reality system displays a visual representation of the scene and mapping data on a near eye display. In some embodiments, the visual representation appears in real space enabling an effect where the user of the mixed reality system can see through walls or other obstructions. In some embodiments, the peripheral is configured to detonate upon the satisfaction of a variable set of conditions.

The present disclosure relates to systems and methods for live fire gaming wherein the system includes a camera, coupled to a server, for capturing images of a target onto which projectiles are being shot by a shooting device, a processing algorithm, implemented through the server, for identifying each single incremental change to the target associated with an initial and subsequent impact points of projectiles shot onto the target, each identification using only one captured image from the camera for each impact point, and a user-interface touch screen display, coupled to the server, for displaying and interfacing with one or more of: a representation of the target showing the impact points, marketing material, firearm safety information, and firearm training instructions.

An electronic system for a firearm includes a power source, one or more electrical conductors electrically connected to receive power from the power source, and a plurality of electronic devices. Each electronic device has an electrical input configured to receive power from the one or more electrical conductors to power the electronic device. A communication device is configured for data communication across the one or more electrical conductors. A method of communicating between electronic devices connected to a firearm includes powering a plurality of electronic devices connected to a firearm from a power source through one or more electrical conductors, and communicating data between the plurality of electronic devices across the one or more electrical conductors.

An electronic system for a firearm includes a power source, one or more electrical conductors electrically connected to receive power from the power source, and a plurality of electronic devices. Each electronic device has an electrical input configured to receive power from the one or more electrical conductors to power the electronic device. A communication device is configured for data communication across the one or more electrical conductors. A method of communicating between electronic devices connected to a firearm includes powering a plurality of electronic devices connected to a firearm from a power source through one or more electrical conductors, and communicating data between the plurality of electronic devices across the one or more electrical conductors.

A peripheral device that is used with a mixed reality system that is thrown by the user of the mixed reality system and captures scene and mapping data of the area the peripheral is thrown into. Upon capturing the scene and mapping data, the peripheral transmits the data (in some embodiments, including processed results of evaluation of the data) to the mixed reality system. The mixed reality system displays a visual representation of the scene and mapping data on a near eye display. In some embodiments, the visual representation appears in real space enabling an effect where the user of the mixed reality system can see through walls or other obstructions. In some embodiments, the peripheral is configured to detonate upon the satisfaction of a variable set of conditions.

A method for calculating a position of a dart pin attached to a dart board divided into a plurality of segments in an apparatus for calculating a position of a dart pin is provided. The method includes obtaining a plurality of optical data from a plurality of optical devices corresponding to at least one of a plurality of holes formed in each segment and installed on the rear surface of the dart board; and calculating a position of a dart pin attached to the dart board using the plurality of optical data.

A device to capture data and video through a weapon's iron sight during live fire, wherein the iron sight has a rear aperture assembly and is able to adjust iron sight elevation. The device includes a beam splitter assembly, a camera, and camera body with a printed circuit board assembly with sensors and a controller, image sensor, device controller and an adjustment arm. The adjustment arm is mountable on the side of the iron sight assembly such that the camera body can be adjusted to the weapon line of sight in a horizontal/windage direction. The beamsplitter assembly splits the light and images to the image sensor and to the shooter's eye without disrupting the shooter's view of a target. The image sensor captures video of the image sent from the beamsplitter assembly. The device controller collects data from all the sensors and sends the data and video to a computer.