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.

A remote weapon system structured to be interfaced with aerial, ground and sea vehicles or platforms for operation in mission critical conditions, allows for mounting and control of single or multi-shot anti-armor rocket launcher systems and provides optical sighting, laser range finding and fire control to adjust vertical elevation, sight of target and trigger of the ignition system. A tactical gimbal controlled by a high torque motor with dual shafts allows for high positional accuracy and target hold that is stable. A frame shrouds and secures rocket launcher tubes causing them to move in unison with the tactical gimbal as a single or multi-shot system. Ignition of the rocket(s) is achieved by a remote-controlled ignitor.

A remote weapon system structured to be interfaced with aerial, ground and sea vehicles or platforms for operation in mission critical conditions, allows for mounting and control of single or multi-shot anti-armor rocket launcher systems and provides optical sighting, laser range finding and fire control to adjust vertical elevation, sight of target and trigger of the ignition system. A tactical gimbal controlled by a high torque motor with dual shafts allows for high positional accuracy and target hold that is stable. A frame shrouds and secures rocket launcher tubes causing them to move in unison with the tactical gimbal as a single or multi-shot system. Ignition of the rocket(s) is achieved by a remote-controlled ignitor.

Disclosed herein is a target display device for assisting to aim at a target beyond a vision obstructing object, the device comprising: a forward-facing camera; a target marker projector; and an orientation marker projector, wherein: the forward-facing camera is adapted to capture an image beyond the vision obstructing object; the target marker projector is adapted to project a target marker; the orientation marker projector is adapted to project an orientation marker; and the forward-facing camera is adapted to capture an image in alignment with the target marker and the orientation marker along a longitudinal axial plane through the target display device.

Disclosed herein is a target display device for assisting to aim at a target beyond a vision obstructing object, the device comprising: a forward-facing camera; a target marker projector; and an orientation marker projector, wherein: the forward-facing camera is adapted to capture an image beyond the vision obstructing object; the target marker projector is adapted to project a target marker; the orientation marker projector is adapted to project an orientation marker; and the forward-facing camera is adapted to capture an image in alignment with the target marker and the orientation marker along a longitudinal axial plane through the target display device.

The present disclosure is directed to scanning radar reflector systems, methods, and apparatuses; even more particularly to a system, method, and apparatus for scanning and reflecting a radar beam transmitted by a radar transmitter onboard an aerial vehicle with radar reflectors equipped on unmanned aerial vehicles. The radar reflection system may include one or more unmanned aerial vehicles equipped with a one or more axis gimbal upon which a radar reflector is mounted. A user may position the unmanned aerial vehicle and the radar reflector to target a specific region for radar scanning.

A system for interoperating and communicating data from a device having a communications gateway and at least one tactical device connected to an electrified rail providing electrical power. The system includes at least one processor, and at least one non-transitory computer-readable data storage device storing data instructions that, when executed by the at least one processor, cause the system to receive an event from the device, determine whether the event triggers a workflow, and execute an action on the device in response to the workflow being triggered.

The present disclosure is directed to scanning radar reflector systems, methods, and apparatuses; even more particularly to a system, method, and apparatus for scanning and reflecting a radar beam transmitted by a radar transmitter onboard an aerial vehicle with radar reflectors equipped on unmanned aerial vehicles. The radar reflection system may include one or more unmanned aerial vehicles equipped with a one or more axis gimbal upon which a radar reflector is mounted. A user may position the unmanned aerial vehicle and the radar reflector to target a specific region for radar scanning.

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.