A dry firearm training system and method utilizing dry laser cartridge technology and a software application is provided. The software application enabling a user to: create, edit, or delete training templates providing the ability to perform training sessions quickly and efficiently. The system utilizes an auto calibration process to calibrate single or multi-targets in various shapes. The software application enables the user to perform a training session using the training template in a number of challenging game modes. All data from each session may be saved and uploaded to a social feed enabling other users to view the data. Personal records can be gained from the sessions, and users can compete for badges and rankings via multi-player matches and tournaments.

The present invention relates to a system comprising threat evaluation and sensor/weapon assignment algorithm operating units which are adapted such that they will operate any threat evaluation and sensor/weapon assignment algorithm, a simulation and analysis unit which is adapted such that it will form the area, in which threat evaluation and sensor/weapon assignment algorithms will be operated, as a virtual scenario by forming an air picture in accordance with the data it receives, an external communication unit which is in communication with the simulation and analysis unit; which can communicate correspondingly with a threat evaluation and sensor/weapon assignment algorithm operating unit; which is adapted such that it will transfer the current scenario information to the threat evaluation and sensor/weapon assignment algorithm when it is necessary and transfer the engagement results to the simulation and analysis unit by taking them back, and a communication unit which is adapted such that it will transfer the scenario, which is formed by communicating with a client, to the client and will receive data through the client; and a method comprising the steps of sending and arranging the data to the simulation and analysis unit through at least one client, transferring the virtual scenario to the TESWA algorithm operating units and receiving the engagement data, combining the engagement data with each other and the data received from the clients and updating the scenario status, approving and disapproving the engagement, analyzing the engagement data and transferring the results to a client partially or completely.

The present invention relates to a system comprising threat evaluation and sensor/weapon assignment algorithm operating units which are adapted such that they will operate any threat evaluation and sensor/weapon assignment algorithm, a simulation and analysis unit which is adapted such that it will form the area, in which threat evaluation and sensor/weapon assignment algorithms will be operated, as a virtual scenario by forming an air picture in accordance with the data it receives, an external communication unit which is in communication with the simulation and analysis unit; which can communicate correspondingly with a threat evaluation and sensor/weapon assignment algorithm operating unit; which is adapted such that it will transfer the current scenario information to the threat evaluation and sensor/weapon assignment algorithm when it is necessary and transfer the engagement results to the simulation and analysis unit by taking them back, and a communication unit which is adapted such that it will transfer the scenario, which is formed by communicating with a client, to the client and will receive data through the client; and a method comprising the steps of sending and arranging the data to the simulation and analysis unit through at least one client, transferring the virtual scenario to the TESWA algorithm operating units and receiving the engagement data, combining the engagement data with each other and the data received from the clients and updating the scenario status, approving and disapproving the engagement, analyzing the engagement data and transferring the results to a client partially or completely.

Methods and systems for aligning a point of aim with a point of impact for a projectile device are disclosed. Using a superposition device coupled to the projectile device, at least one optical reference point is superposed within a first target area. The point of impact is created on a second target area using a projectile expelled from the projectile device towards the second target area. The point of aim for the projectile device is aligned with the point of impact while the position of the at least one optical reference point is maintained. Parallax is eliminated (or minimized) by aligning a primary and a secondary sight alignment indicator with each other and with a common optical axis extending through a scope configured to be coupled with the projectile device.

Disclosed is a repair unit (10) for a pod (11), especially a laser designation pod, including: a transportable casing (14); a bubble (18) attached to the casing (14), having a retracted state and a deployed state, the bubble (18) including an opening (46) for inserting part of a pod (11) and at least two projections forming tubes (50) for the hands of an operator, each tube (50) opening up in the bubble (18); and a gas supply device (22) for switching the bubble (18) front the retracted state to the deployed state. The casing (14) and the bubble (18) define an inner space sealed from outside pollutants in both the retracted state and in the deployed state.

A system and method for analyzing quality criteria of a radiation spot are provided herein. The system may include: at least one controllable electromagnetic radiation source configured to generate and transmit a radiation beam onto an object, resulting in a radiation spot on said object; at least one radiation sensor configured to sense and obtain radiation reflections coming back from said object, wherein the radiation beam is generated in a way that reflections from different ranges are distinguishable of each other; and an analyzer configured to analyze said radiation reflections, and determine a remedy to the radiation beam, in a case that said radiation spot does not meet predefined spot validity criteria. The method may implement the aforementioned logic in a different architecture.

A boresighting device to equip a turret provided with a barrel and one or several sight system(s) each with an optical system includes: a deflection target intended to be positioned outside the barrel, at a muzzle brake of the barrel; a housing intended to be positioned outside the barrel, at a shaft of the barrel. The housing includes: a first optics system provided with a deflection camera, the first optics system being used to determine a parallelism error between a firing line from the shaft and that from the muzzle brake; and a second optics system provided with a boresighting camera, the second optics system being used to determine a parallelism error between the firing line from the shaft and an optics line from the sight system(s). The deflection target integrates a geometric figure serving as a reference point for the first optics system.

An area denial system may be operationally placed with communication latency compensation. The area denial system may include a plurality of munitions, one or more sensor devices, and a command and control unit, networked together and having a command and control latency for communication between the command and control unit and the remainder of the area denial system. Latency compensation may include determining a first target position, determining a first predicted position area for the target using the command and control latency and the first target position, receiving an authorization to arm one or more of the munitions, determining a second target position, and determining that the second target position is outside a threshold distance from a first authorized munition of the one or more authorized munitions, and in response, de-authorizing the first authorized munition.

An area denial system may be operationally placed with communication latency compensation. The area denial system may include a plurality of munitions, one or more sensor devices, and a command and control unit, networked together and having a command and control latency for communication between the command and control unit and the remainder of the area denial system. Latency compensation may include determining a first target position, determining a first predicted position area for the target using the command and control latency and the first target position, receiving an authorization to arm one or more of the munitions, determining a second target position, and determining that the second target position is outside a threshold distance from a first authorized munition of the one or more authorized munitions, and in response, de-authorizing the first authorized munition.

Systems and methods for calibrating, operating, and setting the magnitude of the power of light provided by a laser diode in a conducted electrical weapon (“CEW”). The light of the laser diode assists in targeting by providing a visible indication of the projected point of impact of the tethered electrode of the CEW. The calibration process enables laser diode of a CEW to operate within regional guidelines of the maximum output power of light permitted by a laser. The method further permits the magnitude of the power of the light provided by a laser diode to be set and operated in changing environmental conditions in the field.