An embodiment of the present invention relates to a driving device comprising: a second guide part; a first guide part disposed in the second guide part; an optical unit disposed in the first guide part; a first driving part disposed in the optical unit; and a second driving part disposed opposite to the first driving part, wherein the first guide part comprises: a first fixing part coupled to the second guide part; a first moving part connected to the optical unit; and a first connection part for connecting the first fixing part to the first moving part, and the optical unit is tilted about the first connection part by the first moving part.

An optical apparatus capable of adjusting a position of a lens with a simple configuration that enables miniaturization without deteriorating optical performance. Lens groups are arranged on an optical axis to be movable along the optical axis. A first shaft is arranged in parallel to the optical axis and has a fitting part fit in a predetermined lens group and a first fixing part. A support member rotatably supports the first shaft by holding the first fixing part. A center axis of the first fixing part and a center axis of the fitting part are eccentric. The first shaft is supported by the support member to be rotatable around the center axis of the first fixing part. The predetermined lens group is movable between an image pickup position on the optical axis and a retreat position that is separated from the optical axis by rotating around the first shaft.

An optical system is provided. The optical system includes a first optical module with a first light-entering hole, a second optical module with a second light-entering hole, and a third optical module with a third light-entering hole. The second light-entering hole is close to the first light-entering hole and the third light-entering hole. The focal length of the second optical module is different from the focal length of the first optical module and the focal length of the third optical module.

A reflective element driving module includes a first reflective element, a second reflective element, and a driving assembly. The first reflective element has a first reflective surface, disposed to correspond to the incident light, wherein the light has an optical axis. The second reflective element has a second reflective surface, disposed to correspond to the light reflected by the first reflective element, and is movable relative to the first reflective element. The driving assembly is configured to drive the second reflective element to move relative to the first reflective element, wherein the first reflective surface and the second reflective surface face different directions.

A lens module includes a carrier having an internal space; a lens unit including a plurality of lens groups, and installed in the carrier to move at least one of the lens groups in a length direction of the carrier; a lens guide unit including a plurality of guide members arranged on first and second surfaces of the plurality of lens groups, to guide movement of at least two lens groups of the plurality of lens groups; and a plurality of driving wires connected to each of the plurality of guide members. The carrier includes an auxiliary guide member having an auxiliary guide hole, and disposed on at least one of the first and second surfaces of the plurality of lens group, the auxiliary guide hole being disposed parallel to a movement direction of the at least two lens groups to guide movement of the at least two lens groups.

A lens device includes a first lens module, an image sensor and a first light path turning module. The first lens module includes plurality of lenses. The first light path turning module is configured to transmit a light beam passing through the first lens module to the image sensor by exactly three or four reflections. The first light path turning module includes three or four reflecting surfaces on which the reflections occur. All the reflecting surfaces are plane surfaces. The first light path turning module includes no free form surface. All the surfaces on which the light beam is reflected are plane surfaces, wherein the plane surfaces are flat and are different from freeform surfaces.

The disclosure relates to an optical system and to a method for operating an optical system, wherein the optical system includes at least one carrier having at least one optical element, a movement bearing element for supporting the carrier during a movement, at least one first bearing element and at least one further bearing element for statically supporting the carrier, wherein the carrier includes corresponding bearing elements for providing static support, wherein the optical system includes a first and a further end stop element, wherein the carrier is supported movably between the end stop elements, wherein the first end stop element has or forms the first bearing element for providing static support and the further end stop element has or forms the further bearing element for providing static support, wherein the bearing elements define the stop poses of the carrier with repetition accuracy.

Methods for reducing wavefront errors, manifesting during the process of refocusing of an accommodating (re-focusable) lens system that includes an elastically-deformable lenslet disposed along an optical axis and that has an optical power that is varied by changing the degree of applanation of an area of contact of such elastically-deformable lenslet with a neighboring lenslet in response to variation of force applied to the lenslet axially (in one case—by an external element connected with or forming a part of the lens system housing and/or lenslet support element). Associated accommodating lens systems.

An optical system is provided. The optical system includes a first assembly and a second assembly. The first assembly includes a first welding portion. The second assembly is affixed on the first assembly and includes a second welding portion. The first welding portion is affixed on the second welding portion by welding.

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.