A multi-laser bore-sighting riflescope system can receive a first laser beam having a first wavelength and a second laser beam having a second wavelength smaller than the first wavelength. The system can detect reflected light from the first laser beam. The system can calculate an initial range to a target. The system can determine a ballistics solution. The system can find a ballistics aimpoint. Further, the system can illuminate a display of a riflescope display assembly (RDA). The system can mark the ballistics aimpoint with an electronic reticle on the display. The system can redirect the first laser beam to the ballistics aimpoint. The system can redirect the second laser to the ballistics aimpoint. The system can detect secondary reflected laser light from the first laser beam. The system can calculate a secondary range to the target.

An automatically aligning riflescope display adapter (RDA) system can illuminate toward an eyepiece with a beam from a light emitter. The RDA system can activate a display which includes an electronic reticle visible through the eyepiece. Additionally, the RDA system can track, with a tracking sensor, a location of a scope reticle based on back reflection of the beam from direction of the eyepiece. The RDA system can detect an amount of optical misalignment between the scope reticle and rhe electronic reticle. The RDA systen can align the scope reticle with the electronic reticle.

An automatically aligning riflescope display adapter (RDA) system can illuminate toward an eyepiece with a beam from a light emitter. The RDA system can activate a display which includes an electronic reticle visible through the eyepiece. Additionally, the RDA system can track, with a tracking sensor, a location of a scope reticle based on back reflection of the beam from direction of the eyepiece. The RDA system can detect an amount of optical misalignment between the scope reticle and rhe electronic reticle. The RDA systen can align the scope reticle with the electronic reticle.

A system, method, and device for configuring an optical aiming device for ballistic drop compensation (BDC). The optical aiming device can include a housing with a reticle pane defining a reticle display field viewable by a user and indicating a zero point, the housing further including a plurality of axially spaced lenses and defining an optical path therethrough. In various embodiments the system includes a display device configured to project an image generated from a display, a processor, and a non-transitory computer readable storage medium. The computer readable data storage medium can include instructions executable by the processor to receive a first set of ballistics input data indicating a first type of ammunition, determine a BDC pattern including at least two holdover marks corresponding to at least two ranges for the first type of ammunition, and project the BDC pattern onto the reticle display field.

A system, method, and device for configuring an optical aiming device for ballistic drop compensation (BDC). The optical aiming device can include a housing with a reticle pane defining a reticle display field viewable by a user and indicating a zero point, the housing further including a plurality of axially spaced lenses and defining an optical path therethrough. In various embodiments the system includes a display device configured to project an image generated from a display, a processor, and a non-transitory computer readable storage medium. The computer readable data storage medium can include instructions executable by the processor to receive a first set of ballistics input data indicating a first type of ammunition, determine a BDC pattern including at least two holdover marks corresponding to at least two ranges for the first type of ammunition, and project the BDC pattern onto the reticle display field.

The present invention relates to target acquisition and related devices, and more particularly to telescopic gunsights and associated equipment used to achieve shooting accuracy at, for example, close ranges, medium ranges and extreme ranges at stationary and moving targets.

The present invention relates to target acquisition and related devices, and more particularly to telescopic gunsights and associated equipment used to achieve shooting accuracy at, for example, close ranges, medium ranges and extreme ranges at stationary and moving targets.

A range finder assembly comprising one or more sight pin leads having a light emitting end and a light receiver end, one or more PCBs, a range finder assembly, one or more LEDs, a power supply, a device application and an optical coupling assembly. The one or more PCBs comprises one or more processors and a memory. The one or more processors are configured for executing the device application. The device application is configured for interpreting a range signal from the range finder assembly and generating a range display signal. The one or more LEDs generate light signals. The one or more LEDs are selectively routed into the light receiver end of the one or more sight pin leads using the optical coupling assembly. The light emitting end connect to one or more display pins within bow sight.

The present disclosure relates to a counter measure effector (100) for targeting unmanned aerial vehicles (UAVs), said counter measure effector comprising: at least one antenna (108, 109) for selectively emitting electromagnetic radiation; a telescopic sight (126) comprising an optical system that is transferrable between a first state, in which the optical system has a first appearance, and a second state, in which the optical system has a second appearance that is different from the first appearance, wherein the counter measure effector (100) is configured to set the optical system in its first state, when the at least one antenna is activated, and in its second state, when the at least one antenna is de-activated.

A rifle includes a magazine well, a barrel, an exo-bolt, and a rear magazine support. The barrel is detachably coupled to the magazine well. The barrel includes a forward barrel portion on an end of the barrel opposite the magazine well. The exo-bolt is configured to travel along an exterior of the barrel. The rear magazine support is coupled to the magazine well and opposite the barrel. The rear magazine support is configured to come forward toward the barrel and be secured in a plurality of distances from the barrel to adjust a length of the magazine well.