The present invention discloses a miniaturized wide-range laser range finder which belongs to the technical field of laser range finding, and comprises a monocular telescopic system, a laser emitting system and a laser receiving system, wherein the monocular telescopic system comprises an objective lens system, a focus adjusting system, a beam splitting prism group, a transparent liquid crystal display unit and an eyepiece system through which visible light passes in sequence; the laser emitting system comprises a laser light source and an emitting lens; the laser receiving system comprises an objective lens system, a focus adjusting system, a beam splitting prism group, a receiving lens, a light filter and a laser receiver through which a laser reflection light signal passes in sequence.

The present invention discloses a miniaturized monocular telescopic laser range finder which comprises a receiving and emitting lens group, a focusing negative lens, a beam splitting prism group, an eyepiece group and a laser ranging unit. The receiving and emitting lens group, the focusing negative lens, the beam splitting prism group and the eyepiece group are arranged in sequence from left to right. The receiving and emitting lens group comprises an objective lens and an emitting lens; one side of the objective lens is provided with a groove, and the emitting lens is embedded in the groove. The laser ranging unit is used for emitting laser, receiving the return laser of the laser emitted by the emitting lens, and calculating a distance. The present invention can simultaneously satisfy laser emission and reception through the receiving and emitting lens group, and realizes monocular design and miniaturization.

The present invention discloses a miniaturized monocular telescopic laser range finder which comprises a receiving and emitting lens group, a focusing negative lens, a beam splitting prism group, an eyepiece group and a laser ranging unit. The receiving and emitting lens group, the focusing negative lens, the beam splitting prism group and the eyepiece group are arranged in sequence from left to right. The receiving and emitting lens group comprises an objective lens and an emitting lens; one side of the objective lens is provided with a groove, and the emitting lens is embedded in the groove. The laser ranging unit is used for emitting laser, receiving the return laser of the laser emitted by the emitting lens, and calculating a distance. The present invention can simultaneously satisfy laser emission and reception through the receiving and emitting lens group, and realizes monocular design and miniaturization.

Certain aspects of a novel weapon sight system combine a direct view, a visible light video view, and an infrared (IR) video view mode. Each of the view modes may be viewed individually or simultaneously with one or more of the other view modes through a single viewing aperture. Further, the one or more view-modes may be provided while providing a bore-sighted reticle superimposed on the selected view. Further, the reticle may be powered separately from the video view electronics enabling use of the reticle regardless of the power status video view electronics.

The invention relates to a long range optical device with at least a first visual optical path and a focusing device for focusing the at least first visual optical path. The long range optical device may also include a laser distance meter with a laser transmitter and a laser receiver, wherein a part of an optical path of the laser receiver extends in the at least first visual optical path to the objective lens. A region of the deflection of the optical path of the laser receiver out of the at least first visual optical path may be disposed on at least one optical component. The focusing device may be disposed between the at least one optical component for deflecting of the optical path of the laser receiver and the objective lens.

The invention relates to a long range optical device with at least a first visual optical path and a focusing device for focusing the at least first visual optical path. The long range optical device may also include a laser distance meter with a laser transmitter and a laser receiver, wherein a part of an optical path of the laser receiver extends in the at least first visual optical path to the objective lens. A region of the deflection of the optical path of the laser receiver out of the at least first visual optical path may be disposed on at least one optical component. The focusing device may be disposed between the at least one optical component for deflecting of the optical path of the laser receiver and the objective lens.

Methods, devices and systems for up to three-dimensional scanning of target regions at high magnification are disclosed.

Methods, devices and systems for up to three-dimensional scanning of target regions at high magnification are disclosed.

A device to capture data and video through a weapon's iron sight during live fire, wherein the iron sight has a rear aperture assembly and is able to adjust iron sight elevation. The device includes a beam splitter assembly, a camera, and camera body with a printed circuit board assembly with sensors and a controller, image sensor, device controller and an adjustment arm. The adjustment arm is mountable on the side of the iron sight assembly such that the camera body can be adjusted to the weapon line of sight in a horizontal/windage direction. The beamsplitter assembly splits the light and images to the image sensor and to the shooter's eye without disrupting the shooter's view of a target. The image sensor captures video of the image sent from the beamsplitter assembly. The device controller collects data from all the sensors and sends the data and video to a computer.

A device to capture data and video through a weapon's iron sight during live fire, wherein the iron sight has a rear aperture assembly and is able to adjust iron sight elevation. The device includes a beam splitter assembly, a camera, and camera body with a printed circuit board assembly with sensors and a controller, image sensor, device controller and an adjustment arm. The adjustment arm is mountable on the side of the iron sight assembly such that the camera body can be adjusted to the weapon line of sight in a horizontal/windage direction. The beamsplitter assembly splits the light and images to the image sensor and to the shooter's eye without disrupting the shooter's view of a target. The image sensor captures video of the image sent from the beamsplitter assembly. The device controller collects data from all the sensors and sends the data and video to a computer.