A scope mount and mounting system is disclosed. An example scope mount includes at least one ring mount to receive a scope body. The ring mount has an upper ring and a lower ring. The example scope mount also includes mating interface surfaces between the upper ring and the lower ring. In an example, the mating interface surfaces are cracked. In another example, the mating interface surfaces are precision machined. The example scope mount also includes a pliable insert having a spherical outer body to fit within the ring mount and secure the scope body between the upper ring and the lower ring while accommodating misalignment of the scope body within the ring mount. The example scope mount also includes a rail lock to secure the ring mount in both axis on a rail of a firearm.

A tactical-gear rail-mounting system apparatus and method utilizing the Picatinny-rail standard, allowing precise aligned removable mounting of a variety of tactical gear such as telescopic sights, night vision devices, reflex sights, laser aiming modules, rangefinders, tactical lights, cameras, fore-grips, bipods, and bayonets, in field-interchangeable configurations, to small-arms rifles and pistols and to non-firearm tactical gear, by providing a greater amount of mounting area and a variety of mounting-surface orientations.

The present specification discloses a sight mount used to attach or otherwise secure an optical sight to a firearm as well as methods of modifying a firearm to receive a sight mount disclosed herein.

Implementations of an optical sight mounting system are provided. An example optical sight mounting system comprises an optical sight having a base that can be secured to a pistol slide having an adapter interface. The base of the optical sight is configured so that it can be rotated into position within the adapter interface. In this way, the optical sight can be mounted on a pistol and used to aim. Another example optical sight mounting system comprises an optical sight having a base that can be secured to an adapter interface of an optical sight mount. The base of the optical sight is configured so that it can be rotated into position within the adapter interface. The optical sight mount is configured to releasable engage a mounting interface of a firearm (e.g., a MIL-STD-1913 rail). In this way, the optical sight can be positioned on a firearm (e.g., a rifle) and used to aim.

Systems, devices, and methods, wherein a device is attachable to a firearm and includes a pressure sensor configured to sense pressure generated from the firearm and provide a corresponding signal, a weapon movement sensor configured to sense at least one movement of the firearm and provide a corresponding signal, at least one processor; and memory including computer instructions, the computer instructions configured to, when executed by the at least one processor, cause the at least one processor to determine an event of the firearm based on the corresponding signal provided by the pressure sensor and the corresponding signal provided by the weapon movement sensor. Systems that include the device may record event data and transmit the event data to various user systems for situational awareness, record keeping, training, and other organizational or legal-process purposes.

The present invention relates to implementing recoil activated video recording through a digital imaging system, wherein the video recording is initiated as the digital imaging system detects a firing event from a smart weapon scope device. The digital imaging system captures the video recording sequence, wherein the sequence captures the video at the specific instance when the firing event is detected, for a specific period of time before the firing event is detected, and for a specific period of time after the firing event is detected.

The present invention relates to implementing recoil activated video recording through a digital imaging system, wherein the video recording is initiated as the digital imaging system detects a firing event from a smart weapon scope device. The digital imaging system captures the video recording sequence, wherein the sequence captures the video at the specific instance when the firing event is detected, for a specific period of time before the firing event is detected, and for a specific period of time after the firing event is detected.

A targeting system for visualizing a target includes a targeting assembly having a main body mountable to a weapon and a rail-locking member selectively mountable to the main body. The main body supports at least one of a visual assembly, a power assembly, and a transmission assembly. Communicating with the targeting assembly is a viewing assembly.

A light mountable on a handgun may comprise: a light module including one or more light sources, a cavity for a source of electrical power, a switch, a circuit for energizing the light sources; and an outer housing having complementary parts configured to enclose the light module and a part of the handgun. The outer light housing may include an access cover that is openable when the light is mounted on a handgun, for placing and removing the source of electrical power. Light sources may include an illumination source and an aiming source. A lighting circuit includes a controllable electronic device in series with a power terminal of a controller, wherein operation of the switch causes the controller to maintain the electronic device conductive, whereby the controller then remains powered; and wherein the controller responds to a subsequent operation of the switch to render the electronic device nonconductive, whereby the controller is then unpowered even when electrical power is received.

A system for predicting exterior ballistics has first and second bullet detectors operable to detect the passage of a bullet, the first and second bullet detectors being spaced apart by a selected detector spacing distance, the first and second bullet detector each being connected to a common time signal facility that generates a time signal, the first bullet detector being operable to generate a first time of passage based on the time signal, the second bullet detector being operable to generate a second time of passage based on the time signal, the first bullet detector being operable to measure a first bullet velocity, a controller in communication with the first and second bullet detectors, and the controller operable based on the difference between the first time and the second time, and based on the first bullet velocity to calculate a ballistic characteristic for the bullet.