The disclosure relates to a viewing optic. In one embodiment, the disclosure relates to a viewing optic having an integrated display system. In one embodiment, the disclosure relates to a viewing optic having an integrated display system for generating images that are projected into the first focal plane of an optical system.

The disclosure relates to a viewing optic. In one embodiment, the disclosure relates to a viewing optic having an integrated display system. In one embodiment, the disclosure relates to a viewing optic having an integrated display system for generating images that are projected into the first focal plane of an optical system.

The invention relates to a digital long-range optical apparatus (1) for imaging an object (2), having an optical axis (OA), having a lens (3) for imaging the object (2), the lens (3) being arranged along the optical axis (OA), having a processor unit (4), and having a display unit (5) for displaying an image of the object (2), the processor unit (4) being line-connected to the display unit (5). The digital long-range optical apparatus (1) comprises a beam splitter unit (7), with the lens (3) being arranged first along the optical axis (OA) in a direction of light incidence (LE), followed by the beam splitter unit (7). Further, a first detector (8A) and a second detector (8B) are provided. The first detector (8A) is designed to detect first light (L1) generated by the beam splitter unit (7) and the second detector (8B) is designed to detect second light (L2) generated by the beam splitter unit (7).

The invention relates to a digital long-range optical apparatus (1) for imaging an object (2), having an optical axis (OA), having a lens (3) for imaging the object (2), the lens (3) being arranged along the optical axis (OA), having a processor unit (4), and having a display unit (5) for displaying an image of the object (2), the processor unit (4) being line-connected to the display unit (5). The digital long-range optical apparatus (1) comprises a beam splitter unit (7), with the lens (3) being arranged first along the optical axis (OA) in a direction of light incidence (LE), followed by the beam splitter unit (7). Further, a first detector (8A) and a second detector (8B) are provided. The first detector (8A) is designed to detect first light (L1) generated by the beam splitter unit (7) and the second detector (8B) is designed to detect second light (L2) generated by the beam splitter unit (7).

An Off Axis Guider specifically designed with internal mechanically controlled placement of one or more prisms which allow the user to select stars in the telescope's field of view without obscuring the primary cameras' image capturing ability.

An Off Axis Guider specifically designed with internal mechanically controlled placement of one or more prisms which allow the user to select stars in the telescope's field of view without obscuring the primary cameras' image capturing ability.

An IT-based astronomical telescope system comprises a rotatable lens barrel having an eyepiece installed thereon; a detection device for detecting a current orientation of the lens barrel; and an image generator comprising a micro display provided in the lens barrel. The image generator is used to obtain a picture and display the picture on the micro display. The IT-based astronomical telescope system is configured to work in a virtual reality mode, in which: the image generator is turned on, and based on the current orientation of the lens barrel detected by the detection device, obtains a picture corresponding to an optical image of stars supposed to be imaged by the telescope system with the current orientation of the lens barrel; and the micro display displays the picture, which is presented through the eyepiece.

A wireless vision equipment for weapons including an image capturing device configured to be mounted on a weapon using standard weapon attachment systems, a camera slot, an integrated transmitter using at least one wireless communication protocol, a beam splitter mirror aligned with an aim line, wherein the splitter mirror multiplies an incoming image by two conjugate images, a camera, a transmitter using the at least one wireless communication protocols, a receiver, an antenna, a cable, a shooting glass and a viewing device configured to be lifted upwards to avoid limiting a user's field of vision.

A wireless vision equipment for weapons including an image capturing device configured to be mounted on a weapon using standard weapon attachment systems, a camera slot, an integrated transmitter using at least one wireless communication protocol, a beam splitter mirror aligned with an aim line, wherein the splitter mirror multiplies an incoming image by two conjugate images, a camera, a transmitter using the at least one wireless communication protocols, a receiver, an antenna, a cable, a shooting glass and a viewing device configured to be lifted upwards to avoid limiting a user's field of vision.

A diffractive optic reflex sight (DORS) is provided for aiming devices in which a virtual image, such as a reticle, is produced and appears in the distance of a user's view when looking through the reflex sight. A light source illuminates a diffractive optical element (DOE) that includes a modulation pattern that generates a patterned illuminations corresponding with the virtual image. A reflective image combiner then reflects the patterned illumination so that the virtual image appears in the distance of the viewer's view. The DORS optical design system is mechanically and optically stable for precision aiming across a range of environmental conditions and in different use scenarios or applications including use in rapidly changing temperatures, varying light conditions, and a wide range of user proficiencies. The DORS optical design system is a readily manufacturable aiming and sighting device for a wide range of applications from handguns to astronomical telescopes.