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.

An equatorial mount for providing a telescope with a balanced weight distribution is described. The equatorial mount includes a base, a declination base, and a device support. The declination base is rotatable about a right ascension axis relative to the base. The device support is rotatable about a declination axis relative to the declination base. The declination axis intersects orthogonally with the right ascension axis and the declination axis intersects a midsection of the declination base. The declination base includes a counterweight assembly extending along a counterweight axis, the counterweight axis being spaced away from the declination axis along the right ascension axis.

An optical sight includes a housing, an optical element supported by the housing, a sensor positioned in the housing, a light source configured to selectively illuminate a reticle on the optical element, and a controller configured to control illumination of the reticle based on an output from the sensor. The sensor is configured to detect ambient light at a target object. The controller is configured to control the light source to constantly illuminate the reticle based on a first output from the sensor and illuminate the reticle in pulses based on a second output from the sensor. The first output is different from the second output.

An optical sight includes a housing, an optical element supported by the housing, a sensor positioned in the housing, a light source configured to selectively illuminate a reticle on the optical element, and a controller configured to control illumination of the reticle based on an output from the sensor. The sensor is configured to detect ambient light at a target object. The controller is configured to control the light source to constantly illuminate the reticle based on a first output from the sensor and illuminate the reticle in pulses based on a second output from the sensor. The first output is different from the second output.

The present invention relates to a tracking device for tracking and observing or communicating with moving objects in space or in the atmosphere, wherein the present invention is devised to satisfy the aforementioned needs and an object of the present invention is to provide a tracking device of enabling a single mount to change a posture by one of an altitude-azimuth (ALT-AZ) control method, an equatorial control method, and an altitude-altitude (ALT-ALT) control method so as to facilitate the best tracking according to the operation characteristics of a moving object on the celestial sphere by variously controlling an installation angle of a main rotation shaft.

The present invention relates to a tracking device for tracking and observing or communicating with moving objects in space or in the atmosphere, wherein the present invention is devised to satisfy the aforementioned needs and an object of the present invention is to provide a tracking device of enabling a single mount to change a posture by one of an altitude-azimuth (ALT-AZ) control method, an equatorial control method, and an altitude-altitude (ALT-ALT) control method so as to facilitate the best tracking according to the operation characteristics of a moving object on the celestial sphere by variously controlling an installation angle of a main rotation shaft.

Packaging for an optical sighting device and associated components and methods. The optical sighting device has a sighting axis along which a user looks to use the optical sighting device. The packaging comprises a package defining an interior sized and shaped to fit the optical sighting device. The package includes a base comprising an optical sighting device mount to which the optical sighting device is connected. A cover is connected to the base and at least partially bounds the interior. The cover is configured to permit the user to view the optical sighting device through the cover and to look through the sight along the sighting axis.

Packaging for an optical sighting device and associated components and methods. The optical sighting device has a sighting axis along which a user looks to use the optical sighting device. The packaging comprises a package defining an interior sized and shaped to fit the optical sighting device. The package includes a base comprising an optical sighting device mount to which the optical sighting device is connected. A cover is connected to the base and at least partially bounds the interior. The cover is configured to permit the user to view the optical sighting device through the cover and to look through the sight along the sighting axis.

In one embodiment, an optical device includes an afocal magnifying lens train comprising a plurality of optical elements, which can magnify or demagnify an image of an object with zero or close to zero net convergence or divergence of the incoming light. The afocal magnifying lens train may include a catadioptric system. The optical device also includes an alignment adjustment mechanism to tilt, tip, or move one or more of the optical elements of the afocal magnifying lens train. The optical device further includes a clamp mechanism to secure the optical device to a rail or to another optical device.

In one embodiment, an optical device includes an afocal magnifying lens train comprising a plurality of optical elements, which can magnify or demagnify an image of an object with zero or close to zero net convergence or divergence of the incoming light. The afocal magnifying lens train may include a catadioptric system. The optical device also includes an alignment adjustment mechanism to tilt, tip, or move one or more of the optical elements of the afocal magnifying lens train. The optical device further includes a clamp mechanism to secure the optical device to a rail or to another optical device.