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 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 method of targeting, which involves capturing a first video of a scene about a potential targeting coordinate by a first video sensor on a first aircraft; transmitting the first video and associated potential targeting coordinate by the first aircraft; receiving the first video on a first display in communication with a processor, the processor also receiving the potential targeting coordinate; selecting the potential targeting coordinate to be an actual targeting coordinate for a second aircraft in response to viewing the first video on the first display; and guiding a second aircraft toward the actual targeting coordinate; where positive identification of a target corresponding to the actual targeting coordinate is maintained from selection of the actual targeting coordinate.

A target marking system includes a light source configured to emit a beam of thermal radiation and to impinge the beam onto a target. The system also includes a detector configured to collect radiation passing from the target to the detector along a path. The radiation passing from the target in response to impingement of the beam onto the target. The system further includes an optics assembly disposed optically upstream of the detector along the path. The optics assembly includes at least one of an afocal power changer, a camera objective, a catadioptric lens, and a zoom system configured to condition the radiation passing from the target to the detector.

In an exemplary embodiment of the present disclosure, a target marker for a firearm may comprise a module having a first portion, and a second portion electrically connected and coupled to the first portion. A light source may be disposed within and electrically connected to the second portion. An optical component may be coupled to the first portion at a first fixed distance from the light source. A circuit board may be electrically connected to the light source via at least one lead, wherein the lead may permit relative movement between the circuit board and the light source and may maintain a second fixed distance between the circuit board and the light source.

A method for reducing or eliminating “Missile Tip-off Effect” (MTE) of a missile ejected from a canister. The method includes: receiving data of desired canister state in response to a launch command. The method further include perform repeatedly until an MTE control criterion is met: (a) receiving, from a sensor associated with the canister, data of measured canister state, and (b) processing the data of the measured canister state and desired canister state, for outputting data indicative of a command to an actuator associated with the canister for modifying at least the angular position of the canister, thereby reducing or eliminating the (MTE) effect.

A method for reducing or eliminating “Missile Tip-off Effect” (MTE) of a missile ejected from a canister. The method includes: receiving data of desired canister state in response to a launch command. The method further include perform repeatedly until an MTE control criterion is met: (a) receiving, from a sensor associated with the canister, data of measured canister state, and (b) processing the data of the measured canister state and desired canister state, for outputting data indicative of a command to an actuator associated with the canister for modifying at least the angular position of the canister, thereby reducing or eliminating the (MTE) effect.

The target marking device (1) comprises a drone (2) which is provided with at least one transmitter (4), the transmitter (4) comprising an activation element (10) for activating it so that it transmits at a given time a signal (S) which represents a position information item, the transmitter (4) being configured to transmit at least one of the following signals: an infrared signal, a light signal, a sound signal, a signal generated by a chemical substance, the target marking device (1) being part of a target tracking system (6) and/or a target processing system which is provided with movable machinery (7).

Systems, devices, and methods for determining a predicted impact point of a selected weapon and associated round based on stored ballistic information, provided elevation data, provided azimuth data, and provided position data.

There is provided methods and systems for digital image-referenced indirect target aiming. The systems and methods of the invention measures angle of rotation of subsequent stable images from an initial Reference Image and provide an aiming that is colinear to the target's absolute azimuth.