A security camera and weapon system. The system comprises a camera for capturing images of an area and a display screen for displaying those images. A weapon is co-located with the camera and controllable by a user to fire a projectile. The weapon comprises primer contacts in contact with a projectile primer which is in contact with a propellant. The user controls application of a voltage to the primer contacts, thereby igniting the primer and the propellant and firing the projectile from a weapon barrel. The weapon is aimed and fired by the user from a system controller based on images captured by the camera and presented on the display screen, the images are overlaid with projectile aiming indicia.

The present disclosure provides a mounting assembly for a primary firearm, which may include a non-recoil reducing cradle pivotably coupled to a carriage configured to mount a selectively removable shield assembly. The mounting assembly includes a quick release pintle adaptor locking mechanism, which aids in the rapid mounting and dismounting of a secondary firearm to the mounting assembly.

A human transported weapon system is comprised of an automated targeting subsystem, a sensing subsystem, a decision subsystem, and, a firing subsystem. The automated targeting subsystem identifies and provides for selection of a selected target in a field of view of a target area of the human transported weapon system. The sensing subsystem tracks location of the selected target. The decision subsystem locates where the selected target is at a firing time, responsive to the sensing subsystem. The firing subsystem fires a munition at the firing time towards the selected target responsive to the decision subsystem. In one embodiment, the human transported weapon system is linked to communicate with at least one external weapon subsystem having separate munitions and ability for firing said separate munitions. The decision subsystem determines which one of the human transported weapon system and the external weapon subsystem has a best shot to strike the selected target if fired, and provides for firing of the munition from whichever one of the human transported weapon system and the external weapons subsystem has the best shot to strike the selected target if fired.

An automated weapon system is comprised of a human transported weapon comprising a barrel and munitions; sensing means; targeting means; computational logic for determining where to aim the human transported weapon; aim computational logic; firing activation means; and, firing means. The munitions can be aimed towards a targeting area to be propelled through the barrel. The sensing means senses which of up to a plurality of targets are within firing range of the automated weapon system. The targeting means selects a selected target from the targets in the targeting area that are within the firing range, responsive to the sensing. The computational logic determines where to aim the human transported weapon so that the munitions will hit the selected target if fired at a firing time. The aim computational logic adjusts the aim of the munitions through the human transported weapon, to compensate as needed for where the selected target is at the firing time, responsive to the determining where to aim. The firing activation means initiating firing of the munitions at the firing time. The firing means fires the munitions responsive to the adjusting the aim and the initiating firing.

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.

A human transported weapons system is comprised of processing logic and a barrel movably mounted within a stock. The barrel is movable for positioning and propelling a projectile. The system is comprised of a targeting subsystem (aiming towards an area of sighting); means for locking onto at least one target in the area of sighting as a chosen target responsive to the processing logic; means for determining where the projectile needs to be aimed to strike the chosen target responsive to the processing logic; means for computing a difference between where the projectile needs to be aimed to strike the chosen target at a firing time and where the barrel is aimed at the firing time, responsive to the processing logic; means for adjusting the position of the barrel within the stock, responsive to the computing the difference [note: barrel is adjusted within the stock of the weapon responsive to determining where the projectile needs to be aimed at the firing time to strike the chosen target and where the barrel is aimed at the firing time]; and, a firing subsystem, firing the projectile at firing time so to propel the projectile through the barrel at the chosen target.

A weapons system is comprised of a a human transported weapons subsystem, and a drone weapons subsystem. The human transported weapons subsystem is comprised of a targeting subsystem providing for selection of a selected target, a computational subsystem, and a communications subsystem. The drone weapons subsystem has munitions with positioning and firing capability thereupon, and has communications with the human transported weapons subsystem. The targeting subsystem utilizes communications with the drone weapons subsystem; and, the computational subsystem determines where the drone weapons subsystem is and where the selected target is and where the drone weapons subsystem needs to be located in order for the drone weapons subsystem to aim the munitions to strike the selected target. The human transported weapons subsystem communicates to the drone weapons subsystem to provide information on aim of the munitions from the drone weapons subsystem and communicates to provide activating positioning of the drone weapons subsystem and firing of the munitions from the drone weapons subsystem, responsive to the computational subsystem. The drone weapons subsystem, responsive to communications from the human transported weapons subsystem, fires the munitions from the drone weapons subsystem aimed at the selected target.

An automated weapon system is comprised of a plurality of weapon subsystems; a targeting subsystem; a sensing subsystem; a decision subsystem; a device selection subsystem; and, trigger activation logic. The plurality of weapon subsystems each capable of firing a munition therefrom towards a respective selected target at a respective firing time. The targeting subsystem has a field of view in a target area and provides for identifying at least one said target in the field of view as a selected target. The sensing subsystem provides sensing of the selected target and tracking of location of the selected target through environment in the target area. The decision subsystem, determines where the selected target is located at a firing time responsive to the sensing subsystem. The device selection subsystem determines which of the plurality of weapon subsystems is the selected weapon subsystem in a best position for having munitions fired therefrom to strike the selected target. The trigger activation logic initiates firing of the munitions from the selected weapon subsystem at the firing time, so that the munition will hit the selected target.

An automated weapons system is comprised of a human transported weapon for use by a person, a targeting subsystem identifying a chosen target in the area of sighting, an external drone subsystem with a sensing subsystem that communicates to the targeting subsystem, a computational subsystem, positioning means and a firing subsystem. The human transported weapon is for use by a person. It is comprised of a barrel utilized for propelling a fired munitions to aim towards an area of sighting. The targeting subsystem identifies a chosen target in the area of sighting. The external drone subsystem communicates to the targeting subsystem. The external drone subsystem is located remotely to the human transported weapon, and provides communications between the external drone subsystem and the human transported weapon. The computational subsystem, is responsive to the targeting subsystem, for determining where the chosen target is, and then determines where to aim the munitions so that the munitions will strike the chosen target. The positioning means, adjusts the aim of the munitions responsive to the computational subsystem. The firing subsystem fires the munitions at a firing time, at the chosen target, responsive to the positioning means.

An automated human transported weapon system is comprised of a computational unit, barrel, targeting logic, processing logic, positioning apparatus, and, a firing subsystem. The barrel fires a munitions as aimed within a defined range and within a field of view. The targeting logic identifies up to a plurality of identified targets from within the defined range and within the defined field of view. The processing logic selects a selected target from the identified targets. The positioning apparatus adjusts the aim of the weapon so that the munitions will hit the selected target when fired at a firing time. The firing subsystem fires the munitions through the barrel at the firing time as aimed. There can be a plurality of types of said identified targets that can be identified within the defined ranged and within the field of view of aim of view of the human transported weapon. The processing logic further identifies one said type of target as an identified type of target, from within the identified targets.