A safety assembly for use with a laser-directed energy weapon is disclosed. The assembly comprises a control system comprising a photodetector and a processing unit; and an optical device configured to attach to a target such that, when attached, the optical device provides a light beam to the photodetector. The processing unit is arranged to compare the received light beam against one or more predetermined attributes, and to permit the laser-directed energy weapon to fire only when the received light beam is determined to have the one or more attributes.

A system for firearm target shooting monitoring, training, and feedback includes a camera directed at the aiming point of a firearm or a firearm training device. Embodiments include a trigger sensor and a laser emitter aimed at the aiming point of the firearm or firearm training device. A computer module can analyze video captured by the camera and determine if the firearm or firearm training device was aimed at a target region at the time of a trigger pull. User performance can be monitored, recorded, tracked, and reported to the user. Training and instruction modules can provide directed instruction and training exercises for a user to work on particular skills for which the user desires to raise proficiency.

A simulated firearm includes a body, a camera, a memory, and a processor. The body has a handle, a trigger, and a barrel portion. The barrel portion defines a shooting axis. The camera is coupled to the body and aligned with the shooting axis. The camera is configured to capture an image in response to actuation of the trigger. The memory is coupled to the body and stores marker data corresponding to at least one target marker. The processor is coupled to the body and configured to determine whether a portion of the image captured by the camera matches any one or more of the at least one target marker.

This invention discloses a method for correcting the point of aim in riflescopes or other optical weapon sights. The point of aim is corrected by attaching one or more corrector wedge prisms in front of the riflescope. Each wedge prism shifts the point of aim by a predetermined amount such as 5 cm at 100 m or 10 cm at 100 m, etc. A shooter can zero-in his rifle by first firing a set of test shots to determine how far off the bullets hit from the desired point of impact. He then selects one or more wedge prisms supplied with the riflescope and attaches them to the front (objective side) of the riflescope. The wedge prisms shift the riflescope's point of aim and bring it in alignment with the rifle's point of impact.

This invention discloses a riflescope wherein the point of aim is adjusted by attaching one or more corrector wedge prisms in front of the objective. Each wedge prism shifts the point of aim by a predetermined amount such as 5 cm at 100 m or 10 cm at 100 m, etc. A shooter can zero-in his rifle by first firing a set of test shots to determine how far off the bullets hit from the desired point of impact. He then selects one or more wedge prisms supplied with the riflescope and attaches them to its front side. The wedge prisms correct the riflescope's point of aim and bring it in alignment with the the rifle's point of impact. The riflescope introduced in this invention has no moving parts, no turrets and no off-axis optical components. There is no possibility of it's point of aim shifting due to rifle's recoil force or other vibrations. Additionally, the riflescope has a streamlined body which is aesthetically pleasing and also suitable for adding auxiliary sights such as a reflector sight.

This invention discloses a riflescope wherein the point of aim is adjusted by attaching one or more corrector wedge prisms in front of the objective. Each wedge prism shifts the point of aim by a predetermined amount such as 5 cm at 100 m or 10 cm at 100 m, etc. A shooter can zero-in his rifle by first firing a set of test shots to determine how far off the bullets hit from the desired point of impact. He then selects one or more wedge prisms supplied with the riflescope and attaches them to its front side. The wedge prisms correct the riflescope's point of aim and bring it in alignment with the the rifle's point of impact.

The riflescope introduced in this invention has no moving parts, no turrets and no off-axis optical components. There is no possibility of it's point of aim shifting due to rifle's recoil force or other vibrations. Additionally, the riflescope has a streamlined body which is aesthetically pleasing and also suitable for adding auxiliary sights such as a reflector sight.

In one aspect, identification and communication systems are described herein. An identification and communication system described herein, in some embodiments, comprises one or more query units and one or more response units, wherein at least one response unit comprises one or more detectors comprising one or more optical fibers operable to direct one or more signals received from at least one query unit to the one or more detectors. In some embodiments, at least one optical fiber is operable to receive a signal from at least one query unit through the side of the optical fiber. In some embodiments, at least one optical fiber comprises a fluorescent plastic fiber (FPF). In some embodiments, at least one optical fiber is disposed in a textile.

A safety assembly for use with a laser-directed energy weapon is disclosed. The assembly comprises a control system comprising a photodetector and a processing unit; and an optical device configured to attach to a target such that, when attached, the optical device provides a light beam to the photodetector. The processing unit is arranged to compare the received light beam against one or more predetermined attributes, and to permit the laser-directed energy weapon to fire only when the received light beam is determined to have the one or more attributes.