An optical sight includes a housing, a relay assembly, and a biasing element. The relay assembly has at least one optical element, a main tube, a track tube with at least one track, and a reticle assembly. The track tube is selectively rotatable relative to and about the main tube to adjust an axial position of the at least one optical element within the main tube along an axis that is substantially parallel to a longitudinal axis of the main tube. The reticle assembly further includes at least one optical element. The biasing element includes a mounting strap that is fixed to an inner surface of the housing and a spring having an engagement surface that contacts the relay assembly and exerts a force on the relay assembly. The engagement surface is on a radially inner side of the spring opposite a radially outer side facing the mounting strap.

A telescopic sight for firearms including: magnifying elements disposed along a user optical path between an objective lens assembly and an ocular lens; an imaging system including an imaging sensor and an image processor; a digital optical augmentation (DOA) system disposed outside of the user optical path; at least one optical element adapted to: redirect a spectrum of incoming light from the objective lens assembly to the imaging sensor along a video optical path, redirect/reflect digital markings projected from the DOA system into the user optical path and disallow the projected digital markings from reaching the imaging sensor, and wherein the imaging system is adapted to capture and process imagery from the incoming light to provide image processing data.

The technology relates to a long-range optical device for a firearm with an objective and an eyepiece, through which an observation beam path is formed for aiming at a target, the long-range optical device further comprising an opto-electronic display device, wherein the display device comprises an LCoS display for displaying variable data or a target mark, wherein a display beam path of the display device runs at least partly in the observation beam path for displaying the remote object.

The disclosure relates to a viewing optic. In one embodiment, the disclosure relates to a a viewing optic with an integrated display system. In one embodiment, the disclosure relates to a solar powered viewing optic with an integrated display system.

Systems of the present disclosure may include one or more of an optical overlay device, which may include one or more of an imaging optic to receive incoming light from a scene, and project at least a portion of the incoming light onto an imaging sensor; an imaging sensor to transduce into image data the light projected onto it by the imaging optic; a processing engine electrically coupled with a non-transitory computer readable medium having machine readable instructions stored thereon, which, when executed by the processing engine, cause the system to: generate a scaled overlay image based on the image data and a magnification parameter; a display device configured to project the scaled overlay image through a display optic toward a portion of a beam-combiner; a coupling mechanism to enable releasable attachment of the optical overlay device with a primary viewing device.

A telescoping sight having a sight housing, a moveable lens within the sight housing, a course focus adjustment control being operable to move the moveable lens via a spiral track, and a fine focus adjustment control, the fine focus adjustment control being interoperable with the spiral track.

A holographic, single-unit, augmented sight has a housing containing a see-through holographic eyepiece; at least one of a visible light digital camera and an LWIR digital camera; a display to display an image from the camera(s); a shutter presenting the display; a red dot fiber-coupled LED reticle assembly using a spherical ball configuration sandwiched between two matching seats which are compressed together to contain the spherical ball configuration optical position; and a lever attached to the spherical ball configuration to rotate the ball by moving the lever up/down, left/right to adjust windage and elevation; a lower coupling prism presenting the reticle of the reticle assembly.

A scope magnification adjustment apparatus for use with an optical scope. A scope mount is mounted to a optical scope by means of scope rings. A series of gears is used to rotate a twist ring on the scope to increase or decrease magnification of the optical scope. A mount gear positioned on the mount may be rotated using a lever, power drive, or worm drive mechanism. The rotation of the mount gear rotates a scope gear positioned around the scope and connected to the twist ring on the scope. As the gears rotate, the twist ring rotates and manipulates the magnification.

An optical instrument, such as a riflescope, is disclosed having variable magnification. The reticle can include a stationary display element, such as a magnification scale displayed on a perimeter of the field of view. A moving display element, such as a scale indicator, may be coupled to an actuator that is used to change the magnification power. Both the moving display element and stationary display element may be visible in a field of view through the ocular and together can be used to indicate the magnification power, or a related parameter, such as the range or distance to a target. As the actuator is used to change the magnification power, the user can see the magnification adjustment in the field of view. Thus, the user does not need to look away from the field of view of the instrument to know the magnification setting.

Provided herein is technology relating to telescopic optics and particularly, but not exclusively, to devices and methods for moving a lens in a variable power optical device zoom system.