The present disclosure relates to a controller (10) for a counter measure system against unmanned aerial vehicles (UAVs), the controller (10) comprising a display device (18) and a processor configured to: receive target position data indicative of a position of a target UAV; receive effector position data indicative of a position of at least one counter measure effectors (12, 14); receive effector orientation data indicative of an orientation of the at least one counter measure effector (12, 14) relative to geographic cardinal directions; determine a field of effect (30, 32) of the at least one counter measure effector on the basis of the effector position data and the effector orientation data, said field (30, 32) of effect being indicative of an area covered by electromagnetic radiation emitted, in use, by the at least one counter measure effector; and, generate a display signal for displaying, on the display device, the position of the target UAV with respect to the field of effect (30, 32) of the at least one counter measure effector (12, 14).

A remote-controlled weapon system, mounted in a moving platform, includes at least one processor that implements: a first posture calculator that calculates a first pixel movement amount corresponding to a posture change amount of a camera during a time interval between a first image and a second image, received after the first image; a second posture calculator that calculates a second pixel movement amount corresponding to a control command for changing a posture of the camera to match a moving target, detected from the second image, with an aiming point; and a region of interest (ROI) controller that calculates a third pixel movement amount corresponding to vibration of the camera based on the first pixel movement amount and the second pixel movement amount, and estimate a location of an ROI that is to be set on the moving target of the second image, based on the third pixel movement amount.

A network of scopes, including one or more lead scopes and one or more follower scopes, is provided to allow scope operators of the respective scopes to track the same presumed target. A lead scope locates a target and communicates target position data of the presumed target to the follower scope. The follower scope uses the target position data and its own position data to electronically generate indicators for use to prompt the operator of the follower scope to make position movements so as to re-position the follower scope from its current target position to move towards the target position defined by the target position data received from the lead scope.

A network of scopes, including one or more lead scopes and one or more follower scopes, is provided to allow scope operators of the respective scopes to track the same presumed target. A lead scope locates a target and communicates target position data of the presumed target to the follower scope. The follower scope uses the target position data and its own position data to electronically generate indicators for use to prompt the operator of the follower scope to make position movements so as to re-position the follower scope from its current target position to move towards the target position defined by the target position data received from the lead scope.

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 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.

According to embodiments of the present disclosure, a multi-armament control system is provided. The multi-armament control system includes: platforms including an armament; and an operating vehicle configured to operate the platforms based on a single controller of the operating vehicle. The operating vehicle is further configured to acquire information about a target according to presence or absence of the target, generate a position of a directing point of the target, and share the position of the directing point of the target with the platforms. At least one from among the operating vehicle and the platforms is configured to construct fixed fire nets or variable fire nets of the platforms according to whether the target moves, and by, in part, assigning priority, to each of the platforms based on the target and the firing range of the armament of the platforms.

According to embodiments of the present disclosure, a multi-armament control system is provided. The multi-armament control system includes: platforms including an armament; and an operating vehicle configured to operate the platforms based on a single controller of the operating vehicle. The operating vehicle is further configured to acquire information about a target according to presence or absence of the target, generate a position of a directing point of the target, and share the position of the directing point of the target with the platforms. At least one from among the operating vehicle and the platforms is configured to construct fixed fire nets or variable fire nets of the platforms according to whether the target moves, and by, in part, assigning priority, to each of the platforms based on the target and the firing range of the armament of the platforms.

A system and method for determining an orientation of a firearm includes a first position sensor, a second position sensor and a transmitter. The first position sensor can be disposed at a first location on the firearm. The second position sensor can be disposed at a second location on the firearm. The first and second locations can be distinct and define a line parallel to an axis of a barrel of the firearm. The transmitter can be configured to communicate a signal. The first and second position sensors receive the signal from the transmitter and determine one of an orientation and a heading of the firearm based on the signal.

A system and method for determining an operational status of a firearm based on a discharge event is provided. A first acceleration is measured on the firearm at a first time. A second acceleration is measured on the firearm at a second time. A measured shot separation of first and second accelerations between the first and second times is calculated. The measured shot separation is compared to at least one shot separation threshold. A speed of a movement member in the firearm is assigned based on the comparing. The operational status of the firearm is determined based on the assigned speed. The operational status is communicated to a first user of the firearm in real-time.