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.

A variable range compensating device, including at least some of a housing having an optical cavity defined at least partially within the housing, wherein the optical cavity extends from an incoming image aperture to an outgoing image aperture; and two or more reflective optical elements, wherein each reflective optical element is adjustably positioned within at least a portion of the optical cavity, and wherein adjustment of at least one of the reflective optical elements adjusts the reflective optical elements such that a target image entering the incoming image aperture is reflected by the reflective optical elements, so as to exit the outgoing image aperture at a determined offset.

A method of digitally boresighting includes finding a laser spot in a field of view of an imaging device that has an optical center, wherein the laser spot is generated by a laser, determining an offset vector between the laser spot in the field of view and the optical center, and correcting for boresight misalignment of the laser and imaging device in the image on a display using the offset vector.

A targeting system operable to be used with a bow to assist an operator with striking a target with an arrow. The targeting system may comprise a processor, a target sighting window, a ranging module and a projector. The processor may be configured to control the projector to project a first sighting element onto the target sighting window to select the target, determine a range to the selected target based on the reflected beam, determine an orientation of the bow based at least partially on the determined range to the selected target, determine a location on the target sighting window to present a compensated sighting mark corresponding to the determined orientation, and control the projector to present the variable compensated sighting mark on the target sighting window.

A universal marksmanship training system is disclosed herein configured to utilize a display device comprising a graphic display. A software application may also be provided. The software application is often configured to display a virtual target on the graphic display. A chamber insert may be utilized, the chamber insert configured to be positioned with the firing chamber of a firearm to be zeroed, wherein the chamber insert interacts with the software application to determine alignment of a bore of the firearm to a bore alignment point on the graphic display. In one form, the display device displays a sight target on the graphic display wherein the sight target is visually perceived by a marksman and is offset from the bore alignment point by an offset distance. In one form, the software application calculates the sight target relative to the bore alignment point of the firearm given a set of condition variables.

A device can include one or more sensors configured to output sensor data, and a trigger detection module configured to receive the sensor data from the one or more sensors and to determine whether a trigger event has occurred. The trigger detection module can be configured to output a trigger detection signal when the trigger event is detected. The trigger detection signal can be configured to be used by an augmented reality or virtual reality system to cause an augmented reality or virtual reality event.

A device can include one or more sensors configured to output sensor data, and a trigger detection module configured to receive the sensor data from the one or more sensors and to determine whether a trigger event has occurred. The trigger detection module can be configured to output a trigger detection signal when the trigger event is detected. The trigger detection signal can be configured to be used by an augmented reality or virtual reality system to cause an augmented reality or virtual reality event.

A targeting system operable to be used with a bow to assist an operator with striking a target with an arrow. The targeting system may comprise a processor, a target sighting window, a ranging module and a projector. The processor may be configured to control the projector to project a first sighting element onto the target sighting window to select the target, determine a range to the selected target based on the reflected beam, determine an orientation of the bow based at least partially on the determined range to the selected target, determine a location on the target sighting window to present a compensated sighting mark corresponding to the determined orientation, and control the projector to present the variable compensated sighting mark on the target sighting window.

A variable range visual targeting adjustment apparatus, including at least some of a housing having an optical cavity defined at least partially within the housing, wherein the optical cavity extends from an incoming image aperture to an outgoing image aperture; and two or more reflective surfaces, wherein each reflective surface is adjustably positioned within at least a portion of the optical cavity, and wherein adjustment of at least one of the reflective surfaces adjusts the reflective surfaces such that a target image entering the incoming image aperture is reflected by the reflective surfaces, so as to exit the outgoing image aperture at a determined offset.

The invention concerns a device (1) for locating a target, comprising: a camera (2) that can be oriented in an orientation in view of the target so that the camera acquires an image of the target, and an orientation in view of a star so that the camera acquires at least one image of the star, an inertial unit (4) configured to calculate position and orientation data of the camera (2), a resetting module (6) configured to a apply stellar resetting to the data on the basis of the image of the star, in order to produce reset data, a location module (8) configured to estimate a position of the target (T) from the image of the target (T) and the reset data, a communication interface for communicating with an operator station, the camera (2) passing from one orientation to the other in response to the reception, by the interface, of a command sent by the operator station.