A multi-laser bore-sighting riflescope system can receive a first laser beam having a first wavelength and a second laser beam having a second wavelength smaller than the first wavelength. The system can detect reflected light from the first laser beam. The system can calculate an initial range to a target. The system can determine a ballistics solution. The system can find a ballistics aimpoint. Further, the system can illuminate a display of a riflescope display assembly (RDA). The system can mark the ballistics aimpoint with an electronic reticle on the display. The system can redirect the first laser beam to the ballistics aimpoint. The system can redirect the second laser to the ballistics aimpoint. The system can detect secondary reflected laser light from the first laser beam. The system can calculate a secondary range to the target.

A point of aim shows where a weapon is aimed on a target. An electronic device determines an impact location on the target of a projectile fired from the weapon, determines a distance from the point of aim to the impact location, and moves the point of aim in order to sight the weapon to the target.

A human transported weapons system is comprised of a barrel, a targeting subsystem, a computational subsystem, positioning means, and, a firing subsystem. The barrel is movably mounted within a stock for propelling a projectile towards an area of sighting. The targeting subsystem identifies a chosen target in the area of sighting and locking onto the chosen target at a first time. The computational subsystem, responsive to the targeting subsystem, determines where the chosen target is, and determines where the projectile needs to be aimed to strike the chosen target at a firing time. The positioning means, adjusts the position of the barrel within the stock, responsive to the computational subsystem. The firing subsystem, activates firing at the firing time to propel the projectile through the barrel at the chosen target at the firing time. The locking onto the target can be either: responsive to target selection by the person; or, responsive to determining which of the targets in the area of sighting is a best shot of the available targets.

Systems, devices, and methods for determining a predicted impact point of a selected weapon and associated round based on stored ballistic information, provided elevation data, provided azimuth data, and provided position data.

A measurement and data integration system for the preparation of a firearm, to fire an accurate, precise shot, incorporating a tubular component containing two sensors to measure the speed of the projectile, further including a subsystem for the detection of the impact thereof and the measurement of the time of flight of the same, a subsystem for the measurement of the angles of inclination and cant; a calibration subsystem, a subsystem for communication with weather stations which consults and receives in real time the meteorological variables, as well as a microprocessor with a first operational programme that measures, requests, stores and manages all the aforementioned signals, and a second programme that includes an interface with the user.

A turret display device is used for rapidly zeroing a riflescope. The turrets on an improved riflescope provide a turret position signal. A display of the turret display device comprises turret display cross hairs displayed relative to a target icon. When the turret display device receives a turret position signal, turret display cross hairs move to show the relative movement as indicated by the received turret position signal. When a distance is processed by the turret display device, the turret display cross hairs move to show an aiming point relative to a target icon based on the current zero of the riflescope. The user zeroes the riflescope to any distance by turning the turrets until the turret display cross hairs are centered for the desired distance. In some embodiments the turret display device is integrated into a hand held rangefinder, smart phone, or riflescope. A riflescope having turrets which each provide a turret position signal.

The present invention relates to novel firearm design, manufacture, and use, and in particular a novel firing solution acquisition system designed to improve the fidelity of a firing solution generated from a ballistics calculator in order to improve accuracy and hit probability for rifles and other firing systems while also reducing collateral damage.

Automated systems and methods for collecting environmental data along a ballistic trajectory are disclosed. The systems and methods may comprise automatically estimating the ballistic trajectory of a projectile. The systems and methods may comprise automatically converting the ballistic trajectory into a ballistic flight path comprising a plurality of coordinates. The systems and methods may comprise electronically communicating the ballistic flight path to a guidance system of an Unmanned Aerial Vehicle (UAV). The guidance system may be configured to cause the UAV to navigate along the ballistic flight path. The systems and methods may comprise automatically collecting environmental data along the ballistic flight path.

Embodiments of a firearm device (15) and system employ enhanced optics that can be fixed to a firearm (20), wherein each optical unit is optimized for varying distances from the firearm. An image processor interleaves video streams from each optical unit to present the operator with a unified field of view. Object recognition functions executed by a processor integrated with the device can evaluate the individual video streams, applying object recognition applications to recognize and identify threats/targets within the effective range of each optical unit/image sensor, enabling, among other things, real-time, rapid target identification across multiple distances and prioritization.

An automated weapon system [preferably a human transported weapon] is comprised of a barrel, a targeting subsystem, a computational subsystem, a positioning subsystem, and, a firing subsystem. The barrel is utilized for propelling a fired munitions as aimed towards an area of sighting. The targeting subsystem identifies a chosen target in the area of sighting. The computational subsystem, responsive to the targeting subsystem, determines where the chosen target is and where the barrel needs to be aimed so that the munitions will strike the chosen target. The positioning subsystem adjusts the aim of the munitions responsive to the computational subsystem. The firing subsystem, fires the munitions at the chosen target responsive to the positioning subsystem. In one embodiment, the system is further comprised of an additional linked automated weapon having a separate barrel, separate munitions, a separate positioning subsystem, and a separate firing subsystem. The computational subsystem determines the positioning of the separate barrel to shoot the separate munitions to strike the chosen target. The additional linked automated weapon can be mounted on a stationary mount or mounted on a movable mount.