A human transported weapon system is comprised of an automated targeting subsystem, a sensing subsystem, munitions storage, munitions determining logic for determining which of the types of munition are available, munitions selecting logic, sensor logic, target logic, a decision subsystem, trigger activation logic, aim adjustment logic; and a firing subsystem. The automated targeting subsystem identifies and provides for selection of a selected target in a field of view of the human transported weapon system. The sensing subsystem tracks location of the available targets in the field of view of the human transported weapon system. The munitions storage provides storage for up to a plurality of types of munitions and has at least one of the types of munitions available to select from. The munitions determining logic determines which of the types of munition are available. The munitions selecting logic chooses a selected munition from the types of munitions available. The sensor logic gathers target data from sensors, and recognizes type of target from analyzing the target data. The target logic chooses a selected target based on the type of the selected munition chosen. The decision subsystem locates where the target is at a firing time responsive to the sensor logic.

A weapon-mounted Fire Control System (FCS) for a handheld weapon includes an imaging sensor and a processing system configured to operate in two modes. In a first mode, for handheld operation of the weapon, the processing system tracks a target, determines an aim-region with which the weapon should be aligned for firing in order to strike the target, and generates an output to facilitate accurate firing of the weapon towards the aim region. The output may indicate the aim region on a display, and/or may control a firing control mechanism. In a second mode, when the weapon is on an adjustable weapon support, the processor tracks a target, determines an aim-region, and generates output signals for controlling operation of at least one actuator of the adjustable weapon support in order to align the weapon with the aim region.

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.

The present application provides a remote-controlled gun, comprising a gun base, a gun body, an angle adjustment device, a camera, and a remote controller, wherein the angle adjustment device is connected with the gun body and the gun base, and configured for adjusting a pitch shooting angle of the gun body with respect to the gun base in a vertical plane and a left and right swing angle of the gun body with respect to the gun base in a horizontal plane; the camera is configured for monitoring a shooting target and a front sight of the gun body; the remote controller is connected with the camera and configured for displaying a monitoring image of the camera; and the remote controller is also connected with the angle adjustment device and configured for controlling the gun body to rotate with respect to the gun base until the front sight is aligned with the shooting target within a monitoring area; and the remote controller is also connected with the gun body, and configured for controlling the shooting of the gun body. Compared with the prior arts, this remote-controlled gun makes the user's shooting behavior be changed from operation at site to remote operation, which greatly increases the safety of use; the flexibility of operation be greatly increased, the user can concentrate on a screen of the remote controller to find a target; the aiming be improved, without the need to aim by a naked eye and manual firing, reducing effects due to human factors.

The present application provides a remote-controlled gun, comprising a gun base, a gun body, an angle adjustment device, a camera, and a remote controller, wherein the angle adjustment device is connected with the gun body and the gun base, and configured for adjusting a pitch shooting angle of the gun body with respect to the gun base in a vertical plane and a left and right swing angle of the gun body with respect to the gun base in a horizontal plane; the camera is configured for monitoring a shooting target and a front sight of the gun body; the remote controller is connected with the camera and configured for displaying a monitoring image of the camera; and the remote controller is also connected with the angle adjustment device and configured for controlling the gun body to rotate with respect to the gun base until the front sight is aligned with the shooting target within a monitoring area; and the remote controller is also connected with the gun body, and configured for controlling the shooting of the gun body. Compared with the prior arts, this remote-controlled gun makes the user's shooting behavior be changed from operation at site to remote operation, which greatly increases the safety of use; the flexibility of operation be greatly increased, the user can concentrate on a screen of the remote controller to find a target; the aiming be improved, without the need to aim by a naked eye and manual firing, reducing effects due to human factors.

A human transported weapon is comprised of a barrel, computational logic, selection logic, targeting location logic, positioning logic, and, trigger activation logic. The barrel fires munitions therefrom. The computational logic, identifies targets within range of an area of sighting of the human transported weapon as available target. The selection logic determines a selected target from the available targets, responsive to computational logic. The targeting location logic determines a target location of the selected target at a firing time. The positioning logic, positions the aim of the human transported weapon, responsive to computational logic, so that the munitions will strike the selected target when fired at the firing time. The trigger activation logic provides a trigger signal to activate firing of the munitions at the firing time. In one embodiment, the trigger signal is responsive to a user input. In one embodiment, there are a plurality of types of said targets, such as comprised of human, non-human, animal, friend, and foe. The selection logic identifies one said type of target as a selected type, and, one of the available targets of the selected type is chosen to be the selected target.

A human transported weapon is comprised of a barrel, computational logic, selection logic, targeting location logic, positioning logic, and, trigger activation logic. The barrel fires munitions therefrom. The computational logic, identifies targets within range of an area of sighting of the human transported weapon as available target. The selection logic determines a selected target from the available targets, responsive to computational logic. The targeting location logic determines a target location of the selected target at a firing time. The positioning logic, positions the aim of the human transported weapon, responsive to computational logic, so that the munitions will strike the selected target when fired at the firing time. The trigger activation logic provides a trigger signal to activate firing of the munitions at the firing time. In one embodiment, the trigger signal is responsive to a user input. In one embodiment, there are a plurality of types of said targets, such as comprised of human, non-human, animal, friend, and foe. The selection logic identifies one said type of target as a selected type, and, one of the available targets of the selected type is chosen to be the selected target.

A weapons system is comprised of a human transported weapon for firing a munition through a barrel aimed towards an identified target, a targeting subsystem, a decision subsystem, a weapons aim adjustment controller, and, a targeting subsystem for choosing, from up to a plurality of targets, one said target as a selected target in a field of view of the human transported weapon. The targeting subsystem chooses, from up to a plurality of targets, one said target as a selected target in a field of view of the human transported weapon. The decision subsystem compares where the selected target is located versus where the barrel is aimed. The weapons aim adjustment controller, adjusts aim of the barrel so that when fired, the munition will hit the selected target, responsive to the decision subsystem. The firing subsystem fires the munitions at the selected target at a first firing time responsive to the weapons aim adjustment controller. The munition is tracked after it is fired, to generate tracked munitions data. The selected target is tracked after the munitions is fired, to generate tracked target data.

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.

A system and method for determining the wind force along the planned trajectory of a projectile are disclosed herein. A drone is flown along the expected path of the trajectory along a set heading. The drone is programmed to maintain the heading. As wind forces act upon the drone during its flight, the drone's electronic stability system provides automatic power and directional control to one or more motors that control the rotors and propellers that keep the drone aloft. By monitoring the changes in motor or drone state information over time in response to wind forces, the wind can be determined at various locations along the flight path. This information can be provided to a ballistics calculator to determine the launch heading of the projectile.