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.

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.

The present invention is a remotely controlled weaponized vehicle, comprising: a vehicular base comprising, a mobilized vehicular device, a first computing system, wherein the first computing system controlled the vehicle device, a weapon system attached to the vehicular base, wherein the weapon system comprises, a mounting system connected to the vehicular base, a weapon mount attached to the mounting system, a weapon attached to the weapon mount, an ammunition feeding system connected to the weapon, a second computing system, wherein the second computing system controls the mounting system, the weapon mount, the weapon, and the ammunition feeding system; a plurality of sensors collecting data from the vehicular base and the weapon system, wherein data collected from the plurality of sensors is sent to the first or the second computing systems.

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.

An aiming method for a weapon system including a weapon secured to a chassis, as well as an aiming device implementing such a method. The weapon system includes a computer having in an internal memory a nominal firing profile defined by the extreme elevation and relative bearing aiming instructions that are possible for the weapon, in the reference frame associated with the chassis, when the latter is in a firing position on a horizontal ground. The boundaries of the nominal firing profile are converted so as to determine a transformed firing profile which is delimited by the extreme directions of fire that are possible in the reference frame of the chassis when the latter is in the firing position on the field, and finally the operating firing profile is determined for the aiming, which is defined as the geometric intersection of the nominal firing profile and the transformed firing profile.

An adjustable firearm mount apparatus includes a main support. The main support includes a base end and an adjustment end opposite the base end. A longitudinal axis extends along a length from the base end to the adjustment end. At least one first mounting section is configured to interface with a first portion of a firearm. At least one passageway is defined in the main support and extends in a direction parallel to the longitudinal axis. An auxiliary support is slidably connected to the main support nearer the adjustment end than the base end. The auxiliary support includes at least one elongate member received in the passageway and at least one second mounting section configured to interface with a second portion of the firearm.

An adjustable firearm mount apparatus includes a main support. The main support includes a base end and an adjustment end opposite the base end. A longitudinal axis extends along a length from the base end to the adjustment end. At least one first mounting section is configured to interface with a first portion of a firearm. At least one passageway is defined in the main support and extends in a direction parallel to the longitudinal axis. An auxiliary support is slidably connected to the main support nearer the adjustment end than the base end. The auxiliary support includes at least one elongate member received in the passageway and at least one second mounting section configured to interface with a second portion of the firearm.

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 direct fire weapon system training and firing aid comprising a shoulder bar attachment for elevating and/or traversing a direct fire weapon system is disclosed. It may have an elongate arm for attachment to the weapon system and extending in a generally rearward direction from the weapon system. Once coupled to a weapon system, it gives a user a stable method of supporting and moving the weapon system, allowing the user to quickly elevate and traverse the weapon system by giving the user an additional point of contact, for example at the shoulder or under the arm, to support and stabilize the weapon system.