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.

Provided is a tool for providing long distance shooters with the ability to receive information from others in the field to adjust their weapon system for the best advantage based on distance, location, and range. The tool may implemented as an application on a mobile device such as a smart phone, for example, making the tool light weight, space efficient, and portable for use in the field. The communication ability allows for tracking shooting partners as well as on-the-spot coordination. The tool further provides range markings, yard lines, and topographic data that allow the shooter to make decisions based on real time data. Shooters are therefore afforded a tool that is portable, easy to use, and flexible enough to use in high-pressure environments.

Systems and methods of calculating a ballistic solution for a projectile are provided. A ballistic system may include an airborne device, a ballistic computer, a data interface, and a flight module, or any combination thereof. The airborne device (e.g., a drone) may be operable to gather wind data along or adjacent to a flight path of a projectile to a target. The ballistic computer may be in data communication with the airborne device to receive the wind data. The ballistic computer may be configured to calculate a ballistic solution for the projectile based on the wind data. The data interface may be in data communication with the ballistic computer to output the ballistic solution to a user. The flight module may be configured to calibrate a flight path of the airborne device.

The application relates to a target acquisition system according to one embodiment for an indirect-fire weapon. The system includes a terminal device, a sensor unit for the terminal device, an unmanned aircraft and a control device for the aircraft. The terminal device is adapted to receive, from the control device-controlled aircraft, location data (LD, PW, DT, LT) related to a target's location (LT). The sensor unit is adapted to monitor the weapon's position. The terminal device is adapted to present, with a user interface unit, the target's location on the basis of the received location data and a calculated hit point (LH) for the weapon's projectile on the basis of the weapon's position. The terminal device is adapted to indicate, with the user interface unit, when the weapon has been aimed in such a way that, on the basis of its position, the projectile's calculated hit point is in alignment with the target's location, whereby, when the weapon is discharged, its projectile strikes the designated target

The application relates to a target acquisition system according to one embodiment for an indirect-fire weapon. The system includes a terminal device, a sensor unit for the terminal device, an unmanned aircraft and a control device for the aircraft. The terminal device is adapted to receive, from the control device-controlled aircraft, location data (LD, PW, DT, LT) related to a target's location (LT). The sensor unit is adapted to monitor the weapon's position. The terminal device is adapted to present, with a user interface unit, the target's location on the basis of the received location data and a calculated hit point (LH) for the weapon's projectile on the basis of the weapon's position. The terminal device is adapted to indicate, with the user interface unit, when the weapon has been aimed in such a way that, on the basis of its position, the projectile's calculated hit point is in alignment with the target's location, whereby, when the weapon is discharged, its projectile strikes the designated target

A system and method of locating a target and presenting the location via augmented reality. The inventive subject matter includes a projectile that can transmit information including location information to other computing devices. These computing devices can then use the location information to determine the relative location of the projectile relative to the computing device and generate a visual representation of the location of the projectile on an augmented reality display such that the location of the target is overlaid over a real-world view through the display.

A system and method of locating a target and presenting the location via augmented reality. The inventive subject matter includes a projectile that can transmit information including location information to other computing devices. These computing devices can then use the location information to determine the relative location of the projectile relative to the computing device and generate a visual representation of the location of the projectile on an augmented reality display such that the location of the target is overlaid over a real-world view through the display.

The projectile-launcher operation monitoring device includes at least one displacement-sensor and a processor coupled with the displacement-sensor. The displacement-sensor acquires measurements relating to the displacement of the projectile-launcher and to produce a sampled time signal of values relating to the displacement. The processor receives from the displacement-sensor the sampled time signal to determine projectile-launcher operation parameters therefrom, by employing a deep-learning system. The deep-learning system includes an encoder receiving sample-frames from the sampled time signal producing codes relating to the sample-frames. Each of the codes is a vector of values relating to the probabilities of features in the received sample-frames.

The projectile-launcher operation monitoring device includes at least one displacement-sensor and a processor coupled with the displacement-sensor. The displacement-sensor acquires measurements relating to the displacement of the projectile-launcher and to produce a sampled time signal of values relating to the displacement. The processor receives from the displacement-sensor the sampled time signal to determine projectile-launcher operation parameters therefrom, by employing a deep-learning system. The deep-learning system includes an encoder receiving sample-frames from the sampled time signal producing codes relating to the sample-frames. Each of the codes is a vector of values relating to the probabilities of features in the received sample-frames.

A portable system for facilitating inclined shooting of projectile weapons comprises a ranging system, an inclinometer and a processor. The ranging system measures a line-of sight range distance from a vantage point to a target that is elevated or depressed relative to the vantage point, and the inclinometer measures an inclination angle of a line of sight between the vantage point and the target. Based on information from the rangefinder and inclinometer, the processor determines a predicted altitude-compensated inclined shooting (ACIS) trajectory at the line-of sight range distance for a preselected projectile. The ACIS trajectory is based on a bullet path height correction between a bullet path height at a first altitude and a bullet path height at a second altitude, a range distance of the target from the vantage point, and selected meteorological atmospheric information.